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Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


1

Multifamily Individual Heating and Ventilation Systems, Lawrence, Massachusetts (Fact Sheet), Building America Case Study: Efficient Solutions for New and Existing Homes, Building Technologies Office (BTO)  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Multifamily Individual Heating Multifamily Individual Heating and Ventilation Systems Lawrence, Massachusetts PROJECT INFORMATION Construction: Retrofit Type: Multifamily, affordable Builder: Merrimack Valley Habitat for Humanity (MVHfH) www.merrimackvalleyhabitat.org Size: 840 to 1,170 ft 2 units Price Range: $125,000-$130,000 Date completed: Slated for 2014 Climate Zone: Cold (5A) PERFORMANCE DATA HERS Index Range: 48 to 63 Projected annual energy cost savings: $1,797 Incremental cost of energy efficiency measures: $3,747 Incremental annual mortgage: $346 Annual cash flow: $1,451 Billing data: Not available The conversion of an older Massachusetts building into condominiums illustrates a safe, durable, and cost-effective solution for heating and ventilation systems that can potentially benefit millions of multifamily buildings. Merrimack Valley

2

PIA - Northeast Home Heating Oil Reserve System (Heating Oil...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Northeast Home Heating Oil Reserve System (Heating Oil) PIA - Northeast Home Heating Oil Reserve System (Heating Oil) PIA - Northeast Home Heating Oil Reserve System (Heating Oil)...

3

PIA - Northeast Home Heating Oil Reserve System (Heating Oil...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

PIA - Northeast Home Heating Oil Reserve System (Heating Oil) PIA - Northeast Home Heating Oil Reserve System (Heating Oil) PIA - Northeast Home Heating Oil Reserve System (Heating...

4

Honda Smart Home to Include Berkeley Lab Ventilation Controller  

NLE Websites -- All DOE Office Websites (Extended Search)

Honda Smart Home to Include Berkeley Lab Ventilation Controller Honda Smart Home to Include Berkeley Lab Ventilation Controller Honda smart home October 2013 October-November Special Focus: Energy Efficiency, Buildings, and the Electric Grid Honda Motor Company Inc is proceeding with plans to build a Smart Home in Davis, California, to demonstrate the latest in renewable energy technologies and energy efficiency. The home is expected to produce more energy than is consumed, demonstrating how the goal of "zero net energy" can be met in the near term future. A ventilation controller developed by researchers at Berkeley Lab's Environmental Energy Technologies Division (EETD) will be included in the smart home. EETD is currently working with the developers of the home control system to integrate its control algorithms.

5

Solar home heating in Michigan  

Science Conference Proceedings (OSTI)

This booklet presents the fundamentals of solar heating for both new and existing homes. A variety of systems for space heating and household water heating are explained, and examples are shown of solar homes and installations in Michigan.

Not Available

1984-01-01T23:59:59.000Z

6

Home heating system  

SciTech Connect

A home heating system is disclosed that has a furnace with a combustion chamber for burning fuel and creating heat, and a chimney with a draft therein. An improvement is described that has an exhaust flue connected between the combustion chamber and the chimney for venting heated exhaust products from the furnace, a heat reclaimer connected into the exhaust flue between the combustion chamber and the chimney for reclaiming heat from the heated exhaust product, and an outside air line for supplying air from the outside of the house to the combustion chamber. A first flue portion of the exhaust flue is connected between the combustion chamber and the heat reclaimer, and a second insulated flue portion of the exhaust flue is connected between the heat reclaimer and the chimney. An outside air by-pass or balancing line is connected between the outside air line and the chimney for satisfying the chimney suction at flame-out. A flow sensing and regulating device may be connected into the outside air line for regulating the flow or air so that outside air is supplied to the furnace only when fuel is burned therein.

Bellaff, L.

1980-03-25T23:59:59.000Z

7

Ventilation and Solar Heat Storage System Offers Big Energy Savings  

Ventilation and Solar Heat Storage System Offers Big Energy Savings ... Heat is either reflected away from the building with radiant barriers, or heat is absorbed

8

Northeast Home Heating Oil Reserve System Heating Oil, PIA Office...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Northeast Home Heating Oil Reserve System Heating Oil, PIA Office of Fossil Energy Headquaters Northeast Home Heating Oil Reserve System Heating Oil, PIA Office of Fossil Energy...

9

Northeast Home Heating Oil Reserve  

Gasoline and Diesel Fuel Update (EIA)

Northeast Home Heating Oil Reserve Northeast Home Heating Oil Reserve Information on the Northeast Home Heating Oil Reserve is available from the U.S. Department of Energy (DOE) Office of Petroleum Reserves web site at http://www.fossil.energy.gov/programs/reserves/heatingoil/. Northeast Home Heating Oil Reserve (NEHHOR) inventories now classified as ultra-low sulfur distillate (15 parts per million) are not considered to be in the commercial sector and therefore are excluded from distillate fuel oil supply and disposition statistics in Energy Information Administration publications, such as the Weekly Petroleum Status Report, Petroleum Supply Monthly, and This Week In Petroleum. Northeast Home Heating Oil Reserve Terminal Operator Location (Thousand Barrels) Hess Corp. Groton, CT 500*

10

Heating, Ventilation, and Air Conditioning Renovations | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Heating, Ventilation, and Air Conditioning Renovations Heating, Ventilation, and Air Conditioning Renovations Heating, Ventilation, and Air Conditioning Renovations October 16, 2013 - 4:49pm Addthis Renewable Energy Options for HVAC Renovations Geothermal Heat Pumps (GHP) Solar Water Heating (SWH) Biomass Passive Solar Heating Biomass Heating Solar Ventilation Air Preheating Federal building renovations that encompass the heating, ventilation, and air conditioning (HVAC) systems in a facility provide a range of renewable energy opportunities. The primary technology option for HVAC renovations is geothermal heat pumps (GHP). Other options include leveraging a solar water heating (SWH) system to offset heating load or using passive solar heating or a biomass-capable furnace or boiler. Some facilities may also take

11

PreHeat: controlling home heating using occupancy prediction  

Science Conference Proceedings (OSTI)

Home heating is a major factor in worldwide energy use. Our system, PreHeat, aims to more efficiently heat homes by using occupancy sensing and occupancy prediction to automatically control home heating. We deployed PreHeat in five homes, three in the ... Keywords: energy, environment, home heating, prediction, sensing

James Scott; A.J. Bernheim Brush; John Krumm; Brian Meyers; Michael Hazas; Stephen Hodges; Nicolas Villar

2011-09-01T23:59:59.000Z

12

Heating, Ventilation and Air Conditioning Efficiency  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Presented By: WALTER E. JOHNSTON, PE Presented By: WALTER E. JOHNSTON, PE CEM, CEA, CLEP, CDSM, CPE Heating, Ventilation and Air Conditioning (HVAC) system is to provide and maintain a comfortable environment within a building for the occupants or for the process being conducted Many HVAC systems were not designed with energy efficiency as one of the design factors 3 Air Air is the major conductor of heat. Lack of heat = air conditioning OR 4 Btu - Amount of heat required to raise one pound of water 1 F = 0.252 KgCal 1 Pound of Water = About 1 Pint of Water ~ 1 Large Glass 1 Kitchen Match Basics of Air Conditioning = 1 Btu 5 = 6 Low Cost Cooling Unit 7 8 Typical Design Conditions 75 degrees F temperature 50% relative humidity 30 - 50 FPM air movement

13

Evaluating Ventilation Systems for Existing Homes  

SciTech Connect

During the course of this project, an affordable and high performance ductwork system to directly address the problems of thermal losses, poor efficiency, and air leakage was designed. To save space and enable direct connections between different floors of the building, the ductwork system was designed in such a way that it occupied interior or exterior frame wall cavities. The ductwork system satisfied building regulations for structural support when bridging multiple floors, the spread of fire and smoke, and insulation to reduce the heat flow into or out of the building. Retrofits of urban residential buildings will be the main focus for the application of this ductwork system. Highly reflective foils and insulating materials were used to aid in the increase of the overall R-value of the ductwork itself and the wall assembly. It is expected that the proposed system will increase the efficiency of the HVAC system and the thermal resistance of the building envelope. The performance of the proposed ductwork design was numerically evaluated in a number of different ways. Our results indicate that the aerogel duct method is a very cost attractive alternative to the conventional method.

Aldrich, R.; Arena, L.

2013-02-01T23:59:59.000Z

14

Evaluating Ventilation Systems for Existing Homes  

SciTech Connect

During the course of this project, an affordable and high performance ductwork system to directly address the problems of thermal losses, poor efficiency, and air leakage was designed. To save space and enable direct connections between different floors of the building, the ductwork system was designed in such a way that it occupied interior or exterior frame wall cavities. The ductwork system satisfied building regulations for structural support when bridging multiple floors, the spread of fire and smoke, and insulation to reduce the heat flow into or out of the building. Retrofits of urban residential buildings will be the main focus for the application of this ductwork system. Highly reflective foils and insulating materials were used to aid in the increase of the overall R-value of the ductwork itself and the wall assembly. It is expected that the proposed system will increase the efficiency of the HVAC system and the thermal resistance of the building envelope. The performance of the proposed ductwork design was numerically evaluated in a number of different ways. Our results indicate that the duct method is a very cost attractive alternative to the conventional method.

Aldrich, R.; Arena, L.

2013-02-01T23:59:59.000Z

15

New and Underutilized Heating, Ventilation, and Air Conditioning...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

8, 2013 - 2:56pm Addthis The following heating, ventilation, and air conditioning (HVAC) technologies are underutilized within the Federal sector. These technologies have been...

16

Heating, ventilation and air conditioning systems  

DOE Green Energy (OSTI)

A study is made of several outstanding issues concerning the commercial development of environmental control systems for electric vehicles (EVs). Engineering design constraints such as federal regulations and consumer requirements are first identified. Next, heating and cooling loads in a sample automobile are calculated using a computer model available from the literature. The heating and cooling loads are then used as a basis for estimating the electrical consumption that is to be expected for heat pumps installed in EVs. The heat pump performance is evaluated using an automobile heat pump computer model which has been developed recently at Oak Ridge National Laboratory (ORNL). The heat pump design used as input to the model consists of typical finned-tube heat exchangers and a hermetic compressor driven by a variable-speed brushless dc motor. The simulations suggest that to attain reasonable system efficiencies, the interior heat exchangers that are currently installed as automobile air conditioning will need to be enlarged. Regarding the thermal envelope of the automobile itself, calculations are made which show that considerable energy savings will result if steps are taken to reduce {open_quote}hot soak{close_quote} temperatures and if the outdoor air ventilation rate is well controlled. When these changes are made, heating and cooling should consume less than 10% of the total stored electrical energy for steady driving in most U.S. climates. However, this result depends strongly upon the type of driving: The fraction of total power for heating and cooling ({open_quote}range penalty{close_quote}) increases sharply for driving scenarios having low average propulsion power, such as stop-and-go driving.

Kyle, D.M. [Oak Ridge National Lab., TN (United States); Sullivan, R.A. [Dept. of Energy, Washington, DC (United States)

1993-02-01T23:59:59.000Z

17

Overview: Home Heating Systems | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

- 8:17am Addthis Home heating accounts for about 30 percent of the energy used in the home. | Photo courtesy iStockphoto.com Home heating accounts for about 30 percent of the...

18

Formadehyde in New Homes: Ventilation vs. Source Control  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

at at Building America Residential Energy Efficiency Stakeholder Meeting March 1, 2012 Austin, Texas Formaldehyde in New Homes --- Ventilation vs. Source Control Brett C. Singer and Henry Willem Environmental Energy Technologies Division Lawrence Berkeley National Laboratory Acknowledgments * Funding - U.S. Department of Energy - Building America Program - U.S. EPA - Indoor Environments Division - U.S. HUD - Office of Healthy Homes and Lead Hazard Control - Cal. Energy Commission Public Interest Environmental Research * Technical Contributions - Fraunhofer - Ibacos - IEE-SF * LBNL Team - Sherman, Hotchi, Russell, Stratton, and Others Background 1  Formaldehyde is an irritant and a carcinogen  Odor threshold: about 800 ppb  Widely varying health standards  US HUD (8-h): 400 ppb

19

Intelligent Control of Heating, Ventilating and Air Conditioning Systems  

Science Conference Proceedings (OSTI)

This paper proposed a simulation-optimization energy saving strategy for heating, ventilating and air conditioning (HVAC) systems' condenser water loop through intelligent control of single speed cooling towers' components. An analysis of system components ...

Patrick Low Kie; Lau Bee Theng

2009-07-01T23:59:59.000Z

20

Development of a Dedicated 100 Percent Ventilation Air Heat Pump  

Science Conference Proceedings (OSTI)

The concept of using dedicated 100 percent ventilation makeup air conditioning units to meet indoor air quality standards is attractive because of the inherent advantages. However, it is challenging to design and build direct expansion unitary equipment for this purpose. EPRI teamed with ClimateMaster to develop and test a prototype of a vapor compression heat pump to advance the state of the art in such equipment. The prototype unit provides deep dehumidification and cooling of ventilation air in the su...

2000-12-14T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


21

Northeast Home Heating Oil Reserve - Guidelines for Release ...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Heating Oil Reserve Northeast Home Heating Oil Reserve - Guidelines for Release Northeast Home Heating Oil Reserve - Guidelines for Release Petroleum Reserves Strategic...

22

Energy Saver 101: Home Heating | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Energy Saver 101: Home Heating Energy Saver 101: Home Heating Energy Saver 101: Home Heating Space heating is likely the largest energy expense in your home, accounting for about 45 percent of the average American family's energy bills. That means making smart decisions about your home's heating system can have a big impact on your energy bills. Our Energy Saver 101 infographic lays out everything you need to know about home heating -- from how heating systems work and the different types on the market to what to look for when replacing your system and proper maintenance. Download individual sections of the infographic or a high resolution version now. homeHeating.pdf homeHeating_slide-01.png homeHeating_slide-02.png homeHeating_slide-03.png homeHeating_slide-04.png homeHeating_slide-05.png

23

Energy Saver 101: Home Heating | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Energy Saver 101: Home Heating Energy Saver 101: Home Heating Space heating is likely the largest energy expense in your home, accounting for about 45 percent of the average American family's energy bills. That means making smart decisions about your home's heating system can have a big impact on your energy bills. Our Energy Saver 101 infographic lays out everything you need to know about home heating -- from how heating systems work and the different types on the market to what to look for when replacing your system and proper maintenance. Download individual sections of the infographic or a high resolution version now. homeHeating.pdf homeHeating_slide-01.png homeHeating_slide-02.png homeHeating_slide-03.png homeHeating_slide-04.png homeHeating_slide-05.png

24

Multifamily Individual Heating and Ventilation Systems, Lawrence, Massachusetts (Fact Sheet)  

SciTech Connect

The conversion of an older Massachusetts building into condominiums illustrates a safe, durable, and cost-effective solution for heating and ventilation systems that can potentially benefit millions of multifamily buildings. Merrimack Valley Habitat for Humanity (MVHfH) partnered with U.S. Department of Energy Building America team Building Science Corporation (BSC) to provide high performance affordable housing for 10 families in the retrofit of an existing mass masonry building (a former convent). The original ventilation design for the project was provided by a local engineer and consisted of a single large heat recovery ventilator (HRV) located in a mechanical room in the basement with a centralized duct system providing supply air to the main living space and exhausting stale air from the single bathroom in each apartment. This design was deemed to be far too costly to install and operate for several reasons: the large central HRV was oversized and the specified flows to each apartment were much higher than the ASHRAE 62.2 rate; an extensive system of ductwork, smoke and fire dampers, and duct chases were specified; ductwork required a significant area of dropped ceilings; and the system lacked individual ventilation control in the apartments

Metzger, C.; Ueno, K.; Kerrigan, P.; Wytrykowska, H.; Van Straaten, R.

2013-11-01T23:59:59.000Z

25

Reducing home heating and cooling costs  

SciTech Connect

This report is in response to a request from the House Committee on Energy and Commerce that the Energy Information Administration (EIA) undertake a neutral, unbiased analysis of the cost, safety, and health and environmental effects of the three major heating fuels: heating oil, natural gas, and electricity. The Committee also asked EIA to examine the role of conservation in the choice of heating and cooling fuel. To accommodate a wide audience, EIA decided to respond to the Committee`s request in the context of a report on reducing home heating and cooling costs. Accordingly, this report discusses ways to weatherize the home, compares the features of the three major heating and cooling fuels, and comments on the types of heating and cooling systems on the market. The report also includes a worksheet and supporting tables that will help in the selection of a heating and/or cooling system.

Not Available

1994-07-01T23:59:59.000Z

26

Home Heating | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

by automatically setting back your thermostat when you are asleep or away. Read more Wood and Pellet Heating Wood and pellets are renewable fuel sources, and modern wood and...

27

New York Home Heating Oil Prices  

Gasoline and Diesel Fuel Update (EIA)

5 of 15 5 of 15 Notes: The severity of this spot price increase is causing dramatic changes in residential home heating oil prices, although residential price movements are usually a little slower and spread out over time compared to spot prices. Wholesale prices increased over 50 cents from January 17 to January 24, while retail increased 44 cents in New York. Diesel prices are showing a similar pattern to residential home heating oil prices, and are indicating that home heating oil prices may not have peaked yet, although spot prices are dropping. Diesel prices in New England and the Mid-Atlantic increased 30-40 cents January 24 over the prior week, and another 13-15 cents January 31. Spot prices plummeted January 31, closing at 82 cents per gallon, indicating the worst part of the crisis may be over, but it is still a

28

STEO October 2012 - home heating supplies  

U.S. Energy Information Administration (EIA) Indexed Site

Natural gas, propane, and electricity supplies seen plentiful Natural gas, propane, and electricity supplies seen plentiful this winter for U.S. home heating Supplies of the major heating fuels used by most U.S. households are expected to be plentiful this winter, with the possible exception of heating oil, which is consumed mostly by households in the Northeast. Heating oil stocks are expected to be low in the East Coast and Gulf Coast states. And with New York state requiring heating oil with lower sulfur levels for the first time, the heating oil market is expected to be tighter this winter, according to the U.S. Energy Information Administration's new winter fuels forecast. However, U.S. inventories of natural gas, the most common primary heating fuel used by households and a key fuel for electricity generation, is expected to reach 3.9 trillion cubic feet by

29

Economic Analysis of Home Heating and Cooling  

E-Print Network (OSTI)

Over the last eleven years Houston Lighting & Power has raised utility rates an average of 17% per year. Over the last 3 1/2 years the utility rates have doubled. According to Houston City Magazine, Houstonians can expect future raises of 20-25% annually due to required construction of new utility plants to accommodate Houston's future growth. Utility costs could, and in many cases do, exceed the monthly mortgage payment. This has caused all to become concerned with what can be done to lower the utility bill for homes. In a typical Gulf Coast home approximately 50% of household utility costs are due to the air conditioning system, another 15-20% of utility costs are attributed to hot water heating. The remaining items in the home including lights, toaster, washer, dryer, etc. are relatively minor compared to these two "energy gulpers". Reducing air conditioning and hot water heating costs are therefore the two items on which homeowners should concentrate.

Wagers, H. L.

1984-01-01T23:59:59.000Z

30

Ventilation Systems for Cooling | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Systems for Cooling Ventilation Systems for Cooling Ventilation Systems for Cooling May 30, 2012 - 6:19pm Addthis Proper ventilation helps you save energy and money. | Photo courtesy of JD Hancock. Proper ventilation helps you save energy and money. | Photo courtesy of JD Hancock. Ventilation is the least expensive and most energy-efficient way to cool buildings. Ventilation works best when combined with methods to avoid heat buildup in your home. In some cases, natural ventilation will suffice for cooling, although it usually needs to be supplemented with spot ventilation, ceiling fans, and window fans. For large homes, homeowners might want to investigate whole house fans. Interior ventilation is ineffective in hot, humid climates where

31

Ventilation Systems for Cooling | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Systems for Cooling Ventilation Systems for Cooling Ventilation Systems for Cooling May 30, 2012 - 6:19pm Addthis Proper ventilation helps you save energy and money. | Photo courtesy of JD Hancock. Proper ventilation helps you save energy and money. | Photo courtesy of JD Hancock. Ventilation is the least expensive and most energy-efficient way to cool buildings. Ventilation works best when combined with methods to avoid heat buildup in your home. In some cases, natural ventilation will suffice for cooling, although it usually needs to be supplemented with spot ventilation, ceiling fans, and window fans. For large homes, homeowners might want to investigate whole house fans. Interior ventilation is ineffective in hot, humid climates where

32

DOE Seeks Commercial Storage for Northeast Home Heating Oil Reserve...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

DOE Seeks Commercial Storage for Northeast Home Heating Oil Reserve DOE Seeks Commercial Storage for Northeast Home Heating Oil Reserve March 14, 2011 - 1:00pm Addthis Washington,...

33

Northeast Home Heating Oil Reserve - Guidelines for Release ...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Guidelines for Release Northeast Home Heating Oil Reserve - Guidelines for Release Petroleum Reserves Strategic Petroleum Reserve Heating Oil Reserve Naval Reserves International...

34

Evaluating home heating options in Krakow  

SciTech Connect

The city of Krakow, Poland, has poor air quality due, in part, to widespread use of coal for heating. Engineering analyses have been conducted to determine the technical feasibility and capital costs for a number of options for reducing pollution from home heating sources. Capital costs range from $90 per kilowatt (kW) to connect local boiler-houses to the district heating system to $227/kW to upgrade the electrical system and convert coal stoves to electric heat. Air quality analyses have estimated the reduction in pollutant emissions as well as in pollutant concentrations that would result from implementing the options under consideration. Significant reductions can be obtained at a lower cost by using briquettes instead of coal in home stoves than by converting the stoves to electricity or gas. Finally, incentives analyses are examining the cost-effectiveness of the various alternatives and identifying possible incentives that the city could provide to encourage adoption of less-polluting technologies and practices.

Bleda, J.; Nedoma, J.; Bardel, J.; Pierce, B.

1995-08-01T23:59:59.000Z

35

Development of an Integrated Residential Heating, Ventilation, Cooling, and Dehumidification System for Residences  

Science Conference Proceedings (OSTI)

The Need and the Opportunity Codes such as ASHRAE 90.2 and IECC, and programs such as Energy Star and Builders Challenge, are causing new homes to be built to higher performance standards. As a result sensible cooling loads in new homes are going down, but indoor air quality prerogatives are causing ventilation rates and moisture loads to increase in humid climates. Conventional air conditioners are unable to provide the low sensible heat ratios that are needed to efficiently cool and dehumidify homes since dehumidification potential is strongly correlated with cooling system operating hours. The project team saw an opportunity to develop a system that is at least as effective as a conventional air conditioner plus dehumidifier, removes moisture without increasing the sensible load, reduces equipment cost by integrating components, and simplifies installation. Project Overview Prime contractor Davis Energy Group led a team in developing an Integrated Heating, Ventilation, Cooling, and Dehumidification (I-HVCD) system under the DOE SBIR program. Phase I and II SBIR project activities ran from July 2003 through December 2007. Tasks included: (1) Mechanical Design and Prototyping; (2) Controls Development; (3) Laboratory and Field Testing; and (4) Commercialization Activities Technology Description. Key components of the prototype I-HVCD system include an evaporator coil assembly, return and outdoor air damper, and controls. These are used in conjunction with conventional components that include a variable speed air handler or furnace, and a two-stage condensing unit. I-HVCD controls enable the system to operate in three distinct cooling modes to respond to indoor temperature and relative humidity (RH) levels. When sensible cooling loads are high, the system operates similar to a conventional system but varies supply airflow in response to indoor RH. In the second mode airflow is further reduced, and the reheat coil adds heat to the supply air. In the third mode, the reheat coil adds additional heat to maintain the supply air temperature close to the return air temperature (100% latent cooling). Project Outcomes Key Phase II objectives were to develop a pre-production version of the system and to demonstrate its performance in an actual house. The system was first tested in the laboratory and subsequently underwent field-testing at a new house in Gainesville, Florida. Field testing began in 2006 with monitoring of a 'conventional best practices' system that included a two stage air conditioner and Energy Star dehumidifier. In September 2007, the I-HVCD components were installed for testing. Both systems maintained uniform indoor temperatures, but indoor RH control was considerably better with the I-HVCD system. The daily variation from average indoor humidity conditions was less than 2% for the I-HVCD vs. 5-7% for the base case system. Data showed that the energy use of the two systems was comparable. Preliminary installed cost estimates suggest that production costs for the current I-HVCD integrated design would likely be lower than for competing systems that include a high efficiency air conditioner, dehumidifier, and fresh air ventilation system. Project Benefits This project verified that the I-HVCD refrigeration compacts are compact (for easy installation and retrofit) and can be installed with air conditioning equipment from a variety of manufacturers. Project results confirmed that the system can provide precise indoor temperature and RH control under a variety of climate conditions. The I-HVCD integrated approach offers numerous benefits including integrated control, easier installation, and reduced equipment maintenance needs. Work completed under this project represents a significant step towards product commercialization. Improved indoor RH control and fresh air ventilation are system attributes that will become increasingly important in the years ahead as building envelopes improve and sensible cooling loads continue to fall. Technologies like I-HVCD will be instrumental in meeting goals set by Building America

Hoeschele, M.A.; D.A. Springer

2008-06-18T23:59:59.000Z

36

Development of an Integrated Residential Heating, Ventilation, Cooling, and Dehumidification System for Residences  

SciTech Connect

The Need and the Opportunity Codes such as ASHRAE 90.2 and IECC, and programs such as Energy Star and Builders Challenge, are causing new homes to be built to higher performance standards. As a result sensible cooling loads in new homes are going down, but indoor air quality prerogatives are causing ventilation rates and moisture loads to increase in humid climates. Conventional air conditioners are unable to provide the low sensible heat ratios that are needed to efficiently cool and dehumidify homes since dehumidification potential is strongly correlated with cooling system operating hours. The project team saw an opportunity to develop a system that is at least as effective as a conventional air conditioner plus dehumidifier, removes moisture without increasing the sensible load, reduces equipment cost by integrating components, and simplifies installation. Project Overview Prime contractor Davis Energy Group led a team in developing an Integrated Heating, Ventilation, Cooling, and Dehumidification (I-HVCD) system under the DOE SBIR program. Phase I and II SBIR project activities ran from July 2003 through December 2007. Tasks included: (1) Mechanical Design and Prototyping; (2) Controls Development; (3) Laboratory and Field Testing; and (4) Commercialization Activities Technology Description. Key components of the prototype I-HVCD system include an evaporator coil assembly, return and outdoor air damper, and controls. These are used in conjunction with conventional components that include a variable speed air handler or furnace, and a two-stage condensing unit. I-HVCD controls enable the system to operate in three distinct cooling modes to respond to indoor temperature and relative humidity (RH) levels. When sensible cooling loads are high, the system operates similar to a conventional system but varies supply airflow in response to indoor RH. In the second mode airflow is further reduced, and the reheat coil adds heat to the supply air. In the third mode, the reheat coil adds additional heat to maintain the supply air temperature close to the return air temperature (100% latent cooling). Project Outcomes Key Phase II objectives were to develop a pre-production version of the system and to demonstrate its performance in an actual house. The system was first tested in the laboratory and subsequently underwent field-testing at a new house in Gainesville, Florida. Field testing began in 2006 with monitoring of a 'conventional best practices' system that included a two stage air conditioner and Energy Star dehumidifier. In September 2007, the I-HVCD components were installed for testing. Both systems maintained uniform indoor temperatures, but indoor RH control was considerably better with the I-HVCD system. The daily variation from average indoor humidity conditions was less than 2% for the I-HVCD vs. 5-7% for the base case system. Data showed that the energy use of the two systems was comparable. Preliminary installed cost estimates suggest that production costs for the current I-HVCD integrated design would likely be lower than for competing systems that include a high efficiency air conditioner, dehumidifier, and fresh air ventilation system. Project Benefits This project verified that the I-HVCD refrigeration compacts are compact (for easy installation and retrofit) and can be installed with air conditioning equipment from a variety of manufacturers. Project results confirmed that the system can provide precise indoor temperature and RH control under a variety of climate conditions. The I-HVCD integrated approach offers numerous benefits including integrated control, easier installation, and reduced equipment maintenance needs. Work completed under this project represents a significant step towards product commercialization. Improved indoor RH control and fresh air ventilation are system attributes that will become increasingly important in the years ahead as building envelopes improve and sensible cooling loads continue to fall. Technologies like I-HVCD will be instrumental in meeting goals set by Building America

Hoeschele, M.A.; D.A. Springer

2008-06-18T23:59:59.000Z

37

Transpired Solar Collector at NREL's Waste Handling Facility Uses Solar Energy to Heat Ventilation Air  

Energy.gov (U.S. Department of Energy (DOE))

Revised fact sheet describes the transpired solar collector that was installed on NREL's Waste handling Facility (WHF) in 1990 to preheat ventilation air. The electrically heated WHF was an ideal candidate for this technology - requiring a ventilation rate of 3,000 cubic feet per meter to maintain safe indoor conditions.

38

DOE Seeks Commercial Storage for Northeast Home Heating Oil Reserve |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

for Northeast Home Heating Oil Reserve for Northeast Home Heating Oil Reserve DOE Seeks Commercial Storage for Northeast Home Heating Oil Reserve March 14, 2011 - 1:00pm Addthis Washington, DC - The Department of Energy, through its agent, DLA Energy, has issued a solicitation for new contracts to store two million barrels of ultra low sulfur distillate for the Northeast Home Heating Oil Reserve in New York Harbor and New England. Offers are due no later than 9:00 a.m. EDT on March 29, 2011. Of the U.S. households that use heating oil to heat their homes, 69% reside in the Northeast. The Northeast Home Heating Oil Reserve was established by the Energy Policy Act of 2000 to provide an emergency buffer that can supplement commercial fuel supplies in the event of an actual or imminent severe supply disruption. The Reserve can provide supplemental supplies for

39

Performance Assessment of Photovoltaic Attic Ventilator Fans  

E-Print Network (OSTI)

Controlling summer attic heat gain is important to reducing air conditioning energy use in homes in hot-humid climates. Both heat transfer through ceilings and t attic duct systems can make up a large part of peak cooling demand, Attic ventilation has long been identified as a method to abate such heat gains. We present test results from using the photovoltaic (PV) attic ventilator fans in a test home to assess impact on attic and cooling energy performance.

Parker, D. S.; Sherwin, J. R.

2000-01-01T23:59:59.000Z

40

Radiative Heating Errors in Naturally Ventilated Air Temperature Measurements Made from Buoys*  

Science Conference Proceedings (OSTI)

Solar radiative heating errors in buoy-mounted, naturally ventilated air temperature sensors are examined. Data from sensors with multiplate radiation shields and collocated, fan-aspirated air temperature sensors from three buoy deployments ...

Steven P. Anderson; Mark F. Baumgartner

1998-02-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


41

Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Ventilation Ventilation Controlled ventilation keeps energy-efficient homes healthy and comfortable. Learn more about ventilation. Controlled ventilation keeps energy-efficient homes healthy and comfortable. Learn more about ventilation. When creating an energy-efficient, airtight home through air sealing, it's very important to consider ventilation. Unless properly ventilated, an airtight home can seal in indoor air pollutants. Ventilation also helps control moisture-another important consideration for a healthy, energy-efficient home. Featured Whole-House Ventilation A whole-house ventilation system with dedicated ducting in a new energy-efficient home. | Photo courtesy of ©iStockphoto/brebca. Tight, energy-efficient homes require mechanical -- usually whole-house --

42

HVAC Technology Report: A Review of Heating, Ventilation and Air Conditioning Technology and Markets  

Science Conference Proceedings (OSTI)

For many of us, roughly 95 percent of our time is spent indoors. To enable humans to spend this much time inside, mechanical equipment is necessary to provide space conditioning to control the temperature (heating and cooling), ventilation, humidity, and indoor air quality. This report introduces the heating, ventilation, and air-conditioning (HVAC) industry to EPRI member utility employees. The document describes the most common technologies and applications and provides an overview of industry statisti...

2000-12-14T23:59:59.000Z

43

Heat pumps and manufactured homes: Making the marriage work  

SciTech Connect

Manufactured homes make up over 7% of the US housing stock, including over 15% of the homes in North Carolina. As more of these homes are being equipped with heat pumps, it becomes important to figure out how to make these systems efficient. This article describes a number of ways of increasing the efficiency. The following topics are included: heat pump actual and rated capacity; heat pump sizing; air flow to the coil; indoor thermostat placement; outdoor thermostat; condensate; leaky ducts; pressure boundary breaches; pressure problems; what you should look for in heat pumps; manufactured housing - an evolutionary home.

Conlin, F.; Neal, C.L. [North Carolina Alternative Energy Corp., Raleigh, NC (United States)

1996-11-01T23:59:59.000Z

44

New York Home Heating Oil Prices - Energy Information Administration  

U.S. Energy Information Administration (EIA)

The severity of this spot price increase is causing dramatic changes in residential home heating oil prices, although residential price movements are usually a ...

45

Northeast Home Heating Oil Reserve now focuses on New England ...  

U.S. Energy Information Administration (EIA)

The Northeast Home Heating Oil Reserve (NHHOR) will be reduced to one million barrels, half its original size, as the stockpile's holdings are converted to ultra-low ...

46

Energy Saver 101 Infographic: Home Heating | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Saver 101 Infographic: Home Heating Saver 101 Infographic: Home Heating Energy Saver 101 Infographic: Home Heating December 16, 2013 - 10:48am Addthis Our new Energy Saver 101 infographic lays out everything you need to know about home heating -- from how heating systems work and the different types on the market to what to look for when replacing your system and proper maintenance. | Infographic by Sarah Gerrity, Energy Department. Our new Energy Saver 101 infographic lays out everything you need to know about home heating -- from how heating systems work and the different types on the market to what to look for when replacing your system and proper maintenance. | Infographic by Sarah Gerrity, Energy Department. Rebecca Matulka Rebecca Matulka

47

DOE to Purchase Heating Oil for the Northeast Home Heating Oil Reserve |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Purchase Heating Oil for the Northeast Home Heating Oil Purchase Heating Oil for the Northeast Home Heating Oil Reserve DOE to Purchase Heating Oil for the Northeast Home Heating Oil Reserve June 23, 2008 - 1:29pm Addthis WASHINGTON, DC -The U.S. Department of Energy (DOE) today issued a solicitation seeking to purchase heating oil for the Northeast Home Heating Oil Reserve (NEHHOR) using $3 million in appropriated funds. The Northeast Home Heating Oil Reserve provides an important safety cushion for millions of Americans residing in the Northeast region of the country. Due to the modest volume of heating oil expected to be purchased with the available funds, no impact on market prices is expected. In 2007 a 35,000 barrel sale was conducted to raise funds necessary to award new long-term storage contracts to fill NEHHOR to its authorized

48

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

Choice in Home Heating and Cooling D.J. Wood, H. Ruderman,IN HOME HEATING AND COOLING* David J. Wood, Henry RudermanIN HOME HEATING AND COOLING David J. Wood, Henry Ruderman,

Wood, D.J.

2010-01-01T23:59:59.000Z

49

A STUDY OF AGGREGATION BIAS IN ESTIMATING THE MARKET FOR HOME HEATING AND COOLING EQUIPMENT  

E-Print Network (OSTI)

Home Heating and Cooling Equipment D.J. Wood, H. Ruderman,on home heating appliance choice are referred to Wood,FOR HOME HEATING AND COOLING EQUIPMENT David J. Wood, Henry

Wood, D.J.

2010-01-01T23:59:59.000Z

50

Reducing Home Heating and Cooling Costs  

U.S. Energy Information Administration (EIA) Indexed Site

. . . . . . . . . . . . 19 B1. Annual Cost of Oil Heat in Various Climates for a Range of Heating Oil Prices and System Efficiencies . . . . . 21 B2. Annual Cost of Gas Heat in...

51

Economics of the attached solar greenhouse for home heating  

SciTech Connect

For several years, passive solar heating has been considered to be very attractive (economically and otherwise) for home heating in the U.S. Unfortunately passive systems are not as easily analyzed as active systems from an engineering and economic performance point of view. This problem is addressed, and an economic assessment of the solar greenhouse is given. Using simple heat balance analysis, a greenhouse performance model is developed for assessing heat available for home space conditioning from an add-on solar greenhouse. This forms the basis for an engineering-economic model for assessing the economic viability of the add-on solar greenhouse for home heating. Model variables include climatic factors, local costs, alternate fuels and system size. This model is then used to examine several locations in the U.S. for the economic attractiveness of the add-on solar greenhouse for space heating.

Kolstad, C.D.

1978-01-01T23:59:59.000Z

52

A Feasibility Study: Mining Daily Traces for Home Heating Control  

E-Print Network (OSTI)

home time and dynamically controls the HVAC system [8]. In general, automated home heating control Department of Computer Science University of Virginia {hong, whitehouse}@virginia.edu ABSTRACT HVAC systems nationwide. Recent work has been focused on auto- mated control based on occupancy prediction, where some

Whitehouse, Kamin

53

Hillbrook Nursing Home Space Heating Low Temperature Geothermal Facility |  

Open Energy Info (EERE)

Hillbrook Nursing Home Space Heating Low Temperature Geothermal Facility Hillbrook Nursing Home Space Heating Low Temperature Geothermal Facility Jump to: navigation, search Name Hillbrook Nursing Home Space Heating Low Temperature Geothermal Facility Facility Hillbrook Nursing Home Sector Geothermal energy Type Space Heating Location Clancy, Montana Coordinates 46.4652096°, -111.9863826° Loading map... {"minzoom":false,"mappingservice":"googlemaps3","type":"ROADMAP","zoom":14,"types":["ROADMAP","SATELLITE","HYBRID","TERRAIN"],"geoservice":"google","maxzoom":false,"width":"600px","height":"350px","centre":false,"title":"","label":"","icon":"","visitedicon":"","lines":[],"polygons":[],"circles":[],"rectangles":[],"copycoords":false,"static":false,"wmsoverlay":"","layers":[],"controls":["pan","zoom","type","scale","streetview"],"zoomstyle":"DEFAULT","typestyle":"DEFAULT","autoinfowindows":false,"kml":[],"gkml":[],"fusiontables":[],"resizable":false,"tilt":0,"kmlrezoom":false,"poi":true,"imageoverlays":[],"markercluster":false,"searchmarkers":"","locations":[]}

54

DOE Awards Storage Contracts for Northeast Home Heating Oil Reserve |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Awards Storage Contracts for Northeast Home Heating Oil Reserve Awards Storage Contracts for Northeast Home Heating Oil Reserve DOE Awards Storage Contracts for Northeast Home Heating Oil Reserve August 18, 2011 - 1:00pm Addthis Washington, DC - The U.S. Department of Energy (DOE) today announced that new contracts have been awarded for commercial storage of 650,000 barrels of ultra low sulfur distillate (ULSD) for the Northeast Home Heating Oil Reserve (NEHHOR). Awards were made to two companies for storage in New England--Hess Corporation in Groton, CT for 400,000 barrels, and Global Companies LLC in Revere, MA for 250,000 barrels. The procurement was conducted by the Defense Logistics Agency (DLA Energy), acting as the agent for DOE. Acquisition of storage services for an additional 350,000 barrels is planned to complete the establishment of a

55

Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Additional Storage Contracts Awarded for Northeast Home Heating Oil Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve September 30, 2011 - 1:00pm Addthis Washington, DC - The U.S. Department of Energy (DOE) has completed the acquisition of commercial storage services for the one million barrel Northeast Home Heating Oil Reserve (NEHHOR). Two awards totaling 350,000 barrels have been made to companies that had earlier received storage contracts totaling 650,000 barrels. Hess Corporation in Groton, CT has been awarded a second contract for 100,000 barrels, increasing its storage obligation to 500,000 barrels. Global Companies LLC in Revere, MA was awarded a second contract for 250,000 barrels, increasing its obligation to 500,000 barrels.

56

Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Additional Storage Contracts Awarded for Northeast Home Heating Oil Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve Additional Storage Contracts Awarded for Northeast Home Heating Oil Reserve September 30, 2011 - 1:00pm Addthis Washington, DC - The U.S. Department of Energy (DOE) has completed the acquisition of commercial storage services for the one million barrel Northeast Home Heating Oil Reserve (NEHHOR). Two awards totaling 350,000 barrels have been made to companies that had earlier received storage contracts totaling 650,000 barrels. Hess Corporation in Groton, CT has been awarded a second contract for 100,000 barrels, increasing its storage obligation to 500,000 barrels. Global Companies LLC in Revere, MA was awarded a second contract for 250,000 barrels, increasing its obligation to 500,000 barrels.

57

Northeast Home Heating Oil Reserve- Guidelines for Release  

Energy.gov (U.S. Department of Energy (DOE))

The Energy Policy and Conservation Act, as amended, sets conditions for the release of the Northeast Home Heating Oil Reserve. The Secretary of Energy has the authority to sell, exchange, or...

58

Northeast Home Heating Oil Reserve - Online Bidding System | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Services » Petroleum Reserves » Heating Oil Reserve » Northeast Services » Petroleum Reserves » Heating Oil Reserve » Northeast Home Heating Oil Reserve - Online Bidding System Northeast Home Heating Oil Reserve - Online Bidding System The U.S. Department of Energy has developed an on-line bidding system - an anonymous auction program - for the sale of product from the one million barrel Northeast Home Heating Oil Reserve. We invite prospective bidders and other interested parties to try out this system and give us your views. You must register to use the system to practice or to participate in an actual emergency sale. Registration assures that you will receive e-mail alerts of sales or other pertinent news. You will also have the opportunity to establish a user ID and password to submit bids. If you establish a user ID, you will receive a temporary password by

59

Home Energy Solutions for Existing Homes | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Energy Solutions for Existing Homes Home Energy Solutions for Existing Homes Home Energy Solutions for Existing Homes < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Manufacturing Heat Pumps Appliances & Electronics Water Heating Windows, Doors, & Skylights Program Info Funding Source Public Benefits Fund State Oregon Program Type State Rebate Program Rebate Amount Air Sealing: $150 Duct Insulation: 50% of cost up to $100 Gas Boiler: $200 Direct Vent Gas Fireplace: $200-$250 Direct Vent Gas Unit Heater: $100 Heat Pumps: $250 - $450, depending on efficiency and previous heating system Heat Pump Test: $150 Heat Pump Advanced Controls: $250 Ductless Heat Pump: $800

60

STEO October 2012 - home heating use  

U.S. Energy Information Administration (EIA) Indexed Site

Last year's warm U.S. winter temperatures to give way to Last year's warm U.S. winter temperatures to give way to normal, increasing household heating fuel use U.S. households will likely burn more heating fuels to stay warm this winter compared with last year Average household demand for natural gas, the most common primary heating fuel, is expected to be up 14 percent this winter, according to the U.S. Energy Information Administration's new winter fuels forecast. Demand for electricity will be up 8 percent. And demand for heating oil, used mainly in the Northeast, is expected to be 17 percent higher with propane, used mostly in rural areas, also up 17 percent. The primary reason for the boost in heating fuel demand is weather, which is expected to be 20 to 27 percent colder than last winter's unusually warm temperatures in regions of the country

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


61

Field Measurements of Heating System Efficiency in Nine Electrically-Heated Manufactured Homes.  

Science Conference Proceedings (OSTI)

This report presents the results of field measurements of heating efficiency performed on nine manufactured homes sited in the Pacific Northwest. The testing procedure collects real-time data on heating system energy use and heating zone temperatures, allowing direct calculation of heating system efficiency.

Davis, Bob; Siegel, J.; Palmiter, L.; Baylon, D.

1996-07-01T23:59:59.000Z

62

Non-Space Heating Electrical Consumption in Manufactured Homes: Residential Construction Demonstration Project Cycle II : Final Report.  

SciTech Connect

This report summarizes submeter data of the non-space heating electrical energy use in a sample of manufactured homes. These homes were built to Super Good Cents insulation standards in 1988 and 1989 under the auspices of RCDP Cycle 2 of the Bonneville Power Administration. They were designed to incorporate innovations in insulation and manufacturing techniques developed to encourage energy conservation in this important housing type. Domestic water heating (DWH) and other non-space heat energy consumption, however, were not generally affected by RCDP specifications. The purpose of this study is to establish a baseline for energy conservation in these areas and to present a method for estimating total energy saving benefits associated with these end uses. The information used in this summary was drawn from occupant-read submeters and manufacturersupplied specifications of building shell components, appliances and water heaters. Information was also drawn from a field review of ventilation systems and building characteristics. The occupant survey included a census of appliances and occupant behavior in these manufactured homes. A total of 150 manufactured homes were built under this program by eight manufacturers. An additional 35 homes were recruited as a control group. Of the original 185 houses, approximately 150 had some usable submeter data for domestic hot water and 126 had usable submeter data for all other nonheating consumption. These samples were used as the basis for all consumption analysis. The energy use characteristics of these manufactured homes were compared with that of a similar sample of RCDP site-built homes. In general, the manufactured homes were somewhat smaller and had fewer occupants than the site-built homes. The degree to which seasonal variations were present in non-space heat uses was reviewed.

Onisko, Stephen A.; Roos, Carolyn; Baylon, David

1993-06-01T23:59:59.000Z

63

Nuclear Maintenance Applications Center: Heating, Ventilating, and Air Conditioning Specialist Guide  

Science Conference Proceedings (OSTI)

The people responsible for heating, ventilating, and air conditioning (HVAC) in the nuclear power industry are known by various titles--HVAC specialist, HVAC component engineer, HVAC system manager, and HVAC system engineer, to name a few. Although HVAC duties and responsibilities are often spread across several departments, such as maintenance, operations, engineering, and procurement, it is up to the HVAC specialist to ensure that HVAC system and component health and reliability are maintained. This re...

2011-11-28T23:59:59.000Z

64

Proposed Design for a Coupled Ground-Source Heat Pump/Energy Recovery Ventilator System to Reduce Building Energy Demand.  

E-Print Network (OSTI)

??The work presented in this thesis focuses on reducing the energy demand of a residential building by using a coupled ground-source heat pump/energy recovery ventilation (more)

McDaniel, Matthew Lee

2011-01-01T23:59:59.000Z

65

A genetic rule weighting and selection process for fuzzy control of heating, ventilating and air conditioning systems  

Science Conference Proceedings (OSTI)

In this paper, we propose the use of weighted linguistic fuzzy rules in combination with a rule selection process to develop accurate fuzzy logic controllers dedicated to the intelligent control of heating, ventilating and air conditioning systems concerning ... Keywords: BEMS, building energy management system, FLC, fuzzy logic controller, Fuzzy logic controllers, GA, genetic algorithm, Genetic algorithms, HVAC systems, HVAC, heating, ventilating, and air conditioning, KB, knowledge base, PMV, predicted mean vote index for thermal comfort, Rule selection, Weighted fuzzy rules

Rafael Alcal; Jorge Casillas; Oscar Cordn; Antonio Gonzlez; Francisco Herrera

2005-04-01T23:59:59.000Z

66

Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Ventilation Ventilation May 7, 2012 - 2:49pm Addthis This ventilation system in a tight, energy-efficient home ensures good indoor air quality. | Photo courtesy of ©iStockphoto.com/brebca. This ventilation system in a tight, energy-efficient home ensures good indoor air quality. | Photo courtesy of ©iStockphoto.com/brebca. What does this mean for me? After you've reduced air leakage in your home, adequate ventilation is critical for health and comfort. Depending on your climate, there are a number of strategies to ventilate your home. Ventilation is very important in an energy-efficient home. Air sealing techniques can reduce air leakage to the point that contaminants with known health effects such as formaldehyde, volatile organic compounds, and radon

67

Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Ventilation Ventilation May 7, 2012 - 2:49pm Addthis This ventilation system in a tight, energy-efficient home ensures good indoor air quality. | Photo courtesy of ©iStockphoto.com/brebca. This ventilation system in a tight, energy-efficient home ensures good indoor air quality. | Photo courtesy of ©iStockphoto.com/brebca. What does this mean for me? After you've reduced air leakage in your home, adequate ventilation is critical for health and comfort. Depending on your climate, there are a number of strategies to ventilate your home. Ventilation is very important in an energy-efficient home. Air sealing techniques can reduce air leakage to the point that contaminants with known health effects such as formaldehyde, volatile organic compounds, and radon

68

Home Cooling | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Cooling Cooling Home Cooling Ventilation Systems for Cooling Learn how to avoid heat buildup and keep your home cool with ventilation. Read more Cooling with a Whole House Fan A whole-house fan, in combination with other cooling systems, can meet all or most of your home cooling needs year round. Read more Although your first thought for cooling may be air conditioning, there are many alternatives that provide cooling with less energy use. You might also consider fans, evaporative coolers, or heat pumps as your primary means of cooling. In addition, a combination of proper insulation, energy-efficient windows and doors, daylighting, shading, and ventilation will usually keep homes cool with a low amount of energy use in all but the hottest climates. Although ventilation is not an effective cooling strategy in hot, humid

69

Industrial Uses of Vegetable OilsChapter 5 Biofuels for Home Heating Oils  

Science Conference Proceedings (OSTI)

Industrial Uses of Vegetable Oils Chapter 5 Biofuels for Home Heating Oils Processing eChapters Processing Press Downloadable pdf of Chapter 5 Biofuels for Home Heating Oils from the book ...

70

#tipsEnergy: Saving on Home Heating Costs | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

tipsEnergy: Saving on Home Heating Costs tipsEnergy: Saving on Home Heating Costs November 23, 2012 - 3:37pm Addthis Rebecca Matulka Rebecca Matulka Digital Communications...

71

Energy-saving strategies with personalized ventilation in cold climates  

E-Print Network (OSTI)

designs of personalized ventilation, International Journal of heating, Ventilation and Refrigeration

Schiavon, Stefano; Melikov, Arsen

2009-01-01T23:59:59.000Z

72

Energy conservation and solar heating for mobile homes  

DOE Green Energy (OSTI)

Project activities consisted of retro-fitting six (6) mobile homes with extensive energy-conservation improvements and installing solar-space-heating systems on four (4) of these homes. The intent of the project was to evaluate the potential of mobile homes as a low-cost energy-efficient housing option for low- to moderate income families. Using both hard and soft data, it is estimated that an average fuel reduction in excess of 35% was achieved by the conservation improvements alone. The project lacked the expertise and monitoring instruments to properly evaluate the effectiveness of the four solar installations and had to rely on the personal observations of the four families that received the units.

None

73

How refrigeration, heating, ventilation, and air conditioning service technicians learn from troubleshooting (Dissertation ABstract)  

E-Print Network (OSTI)

The purpose of this study was to understand how refrigeration, heating, ventilation, and air conditioning (RHVAC) service technicians (techs) learned from troubleshooting. This understanding resulted in instructional and curricular strategies designed to help community colleges prepare vocational students to learn more effectively from informal workplace learning. RHVAC techs were studied because they increasingly learn their trade skills through a combination of formal schooling and informal workplace learning, though many still learn their trade almost exclusively in the workplace. Even those with formal training require considerable workplace experience to become fully competent. Troubleshooting is a major job function for RHVAC service techs, and troubleshooting

Denis F. H. Green

2006-01-01T23:59:59.000Z

74

VENTILATION MODEL REPORT  

SciTech Connect

The purpose of the Ventilation Model is to simulate the heat transfer processes in and around waste emplacement drifts during periods of forced ventilation. The model evaluates the effects of emplacement drift ventilation on the thermal conditions in the emplacement drifts and surrounding rock mass, and calculates the heat removal by ventilation as a measure of the viability of ventilation to delay the onset of peak repository temperature and reduce its magnitude. The heat removal by ventilation is temporally and spatially dependent, and is expressed as the fraction of heat carried away by the ventilation air compared to the fraction of heat produced by radionuclide decay. One minus the heat removal is called the wall heat fraction, or the remaining amount of heat that is transferred via conduction to the surrounding rock mass. Downstream models, such as the ''Multiscale Thermohydrologic Model'' (BSC 2001), use the wall heat fractions as outputted from the Ventilation Model to initialize their postclosure analyses.

V. Chipman

2002-10-31T23:59:59.000Z

75

Rocky Mountain Power - New Homes Program for Builders | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Rocky Mountain Power - New Homes Program for Builders Rocky Mountain Power - New Homes Program for Builders Rocky Mountain Power - New Homes Program for Builders < Back Eligibility Construction Installer/Contractor Multi-Family Residential Residential Savings Category Heating & Cooling Cooling Commercial Heating & Cooling Appliances & Electronics Home Weatherization Construction Commercial Weatherization Design & Remodeling Other Sealing Your Home Ventilation Heat Pumps Commercial Lighting Lighting Windows, Doors, & Skylights Program Info State Utah Program Type Utility Rebate Program Rebate Amount '''New Construction Whole Home Options''' Home Performance ENERGY STAR Version 3 Certified Home: $500 (Single Family); $200 (Multifamily) ENERGY STAR Version 3 Certified Home: $250 (Single Family); $150 (Multifamily)

76

Cascade Natural Gas - Conservation Incentives for New Homes | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Cascade Natural Gas - Conservation Incentives for New Homes Cascade Natural Gas - Conservation Incentives for New Homes Cascade Natural Gas - Conservation Incentives for New Homes < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Construction Commercial Heating & Cooling Design & Remodeling Sealing Your Home Ventilation Heating Appliances & Electronics Water Heating Program Info State District of Columbia Program Type Utility Rebate Program Rebate Amount High Efficiency Natural Gas Furnace: $150 High Efficiency Natural Gas Hearth: $70 Conventional Natural Gas Water Heater: $40 Condensing Tankless Water Heater: $200 Combined Domestic Water/Hydronic Space Heating System (usingTankless Water Heater): $800 Energy Star Certified Home: $350 Energy Star Certified Plus Home: $750

77

Business reasons for utilizing renewable energy applications in facilities to assist in extending the life of the heating ventilation and air conditioning systems .  

E-Print Network (OSTI)

??This research is intended to discover business reasons for utilizing renewable energy applications in buildings to help extend the life of the heating, ventilation and (more)

Thompson, Glendon Raymond

2008-01-01T23:59:59.000Z

78

Proposal for the award of a contract for the design, supply, installation and commissioning of Heating, Ventilation and Air-Conditioning (HVAC) systems for the PS accelerator infrastructure  

E-Print Network (OSTI)

Proposal for the award of a contract for the design, supply, installation and commissioning of Heating, Ventilation and Air-Conditioning (HVAC) systems for the PS accelerator infrastructure

2012-01-01T23:59:59.000Z

79

Proposal for the award of a contract for dismantling, removal and packaging of the existing Heating, Ventilation and Air-Conditioning (HVAC) systems in the PS tunnel  

E-Print Network (OSTI)

Proposal for the award of a contract for dismantling, removal and packaging of the existing Heating, Ventilation and Air-Conditioning (HVAC) systems in the PS tunnel

2012-01-01T23:59:59.000Z

80

Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes - Business Case Assessment  

SciTech Connect

The long range strategic goal of the Department of Energy's Building Technologies (DOE/BT) Program is to create, by 2020, technologies and design approaches that enable the construction of net-zero energy homes at low incremental cost (DOE/BT 2005). A net zero energy home (NZEH) is a residential building with greatly reduced needs for energy through efficiency gains, with the balance of energy needs supplied by renewable technologies. While initially focused on new construction, these technologies and design approaches are intended to have application to buildings constructed before 2020 as well resulting in substantial reduction in energy use for all building types and ages. DOE/BT's Emerging Technologies (ET) team is working to support this strategic goal by identifying and developing advanced heating, ventilating, air-conditioning, and water heating (HVAC/WH) technology options applicable to NZEHs. Although the energy efficiency of heating, ventilating, and air-conditioning (HVAC) equipment has increased substantially in recent years, new approaches are needed to continue this trend. Dramatic efficiency improvements are necessary to enable progress toward the NZEH goals, and will require a radical rethinking of opportunities to improve system performance. The large reductions in HVAC energy consumption necessary to support the NZEH goals require a systems-oriented analysis approach that characterizes each element of energy consumption, identifies alternatives, and determines the most cost-effective combination of options. In particular, HVAC equipment must be developed that addresses the range of special needs of NZEH applications in the areas of reduced HVAC and water heating energy use, humidity control, ventilation, uniform comfort, and ease of zoning. In FY05 ORNL conducted an initial Stage 1 (Applied Research) scoping assessment of HVAC/WH systems options for future NZEHs to help DOE/BT identify and prioritize alternative approaches for further development. Eleven system concepts with central air distribution ducting and nine multi-zone systems were selected and their annual and peak demand performance estimated for five locations: Atlanta (mixed-humid), Houston (hot-humid), Phoenix (hot-dry), San Francisco (marine), and Chicago (cold). Performance was estimated by simulating the systems using the TRNSYS simulation engine (Solar Energy Laboratory et al. 2006) in two 1800-ft{sup 2} houses--a Building America (BA) benchmark house and a prototype NZEH taken from BEopt results at the take-off (or crossover) point (i.e., a house incorporating those design features such that further progress towards ZEH is through the addition of photovoltaic power sources, as determined by current BEopt analyses conducted by NREL). Results were summarized in a project report, 'HVAC Equipment Design options for Near-Zero-Energy Homes--A Stage 2 Scoping Assessment', ORNL/TM-2005/194 (Baxter 2005). The 2005 study report describes the HVAC options considered, the ranking criteria used, and the system rankings by priority. Table 1 summarizes the energy savings potential of the highest scoring options from the 2005 study for all five locations. All system options were scored by the ORNL building equipment research team and by William Goetzler of Navigant Consulting. These scores were reviewed by DOE/BT's Residential Integration program leaders and Building America team members. Based on these results, the two centrally ducted integrated heat pump (IHP) systems (air source and ground source versions) were selected for advancement to Stage 2 (Exploratory Development) business case assessments in FY06. This report describes results of these business case assessments. It is a compilation of three separate reports describing the initial business case study (Baxter 2006a), an update to evaluate the impact of an economizer cooling option (Baxter 2006b), and a second update to evaluate the impact of a winter humidification option (Baxter 2007). In addition it reports some corrections made subsequent to release of the first two reports to correct so

Baxter, Van D [ORNL

2007-05-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


81

Measuring Residential Ventilation  

NLE Websites -- All DOE Office Websites (Extended Search)

measured. The local exhaust flows can be measured or can meet prescriptive ducting and fan labeling requirements that use ratings provided by the Home Ventilating Institute (HVI,...

82

Heat Pump Water Heaters and American Homes: A Good Fit?  

SciTech Connect

Heat pump water heaters (HPWHs) are over twice as energy-efficient as conventional electric resistance water heaters, with the potential to save substantial amounts of electricity. Drawing on analysis conducted for the U.S. Department of Energy's recently-concluded rulemaking on amended standards for water heaters, this paper evaluates key issues that will determine how well, and to what extent, this technology will fit in American homes. The key issues include: 1) equipment cost of HPWHs; 2) cooling of the indoor environment by HPWHs; 3) size and air flow requirements of HPWHs; 4) performance of HPWH under different climate conditions and varying hot water use patterns; and 5) operating cost savings under different electricity prices and hot water use. The paper presents the results of a life-cycle cost analysis of the adoption of HPWHs in a representative sample of American homes, as well as national impact analysis for different market share scenarios. Assuming equipment costs that would result from high production volume, the results show that HPWHs can be cost effective in all regions for most single family homes, especially when the water heater is not installed in a conditioned space. HPWHs are not cost effective for most manufactured home and multi-family installations, due to lower average hot water use and the water heater in the majority of cases being installed in conditioned space, where cooling of the indoor environment and size and air flow requirements of HPWHs increase installation costs.

Franco, Victor; Lekov, Alex; Meyers, Steve; Letschert, Virginie

2010-05-14T23:59:59.000Z

83

Numerical Simulation of a Displacement Ventilation System with Multi-heat Sources and Analysis of Influential Factors  

E-Print Network (OSTI)

Displacement ventilation (DV) is a promising ventilation concept due to its high ventilation efficiency. In this paper, the application of the CFD method, the velocity and temperature fields of three-dimensional displacement ventilation systems with double heat sources are numerically simulated. The model is verified by experimental data. The results of the study show that thermal stratification characteristics exist in indoor temperature fields. The paper also analyzes the influence of different influential factors, e.g., the distance between heat sources, temperature of heat source, heat characteristics of the wall and outdoor temperature. It was found that the human requirement for comfort is satisfied easily when the distance between heat sources is long. Under the conditions simulated in this paper, when the distance was more than 0.8m, the temperature distribution tended to be average and steady, and it did not change as the distance changed. Second, the temperature change of the thermal current has a large influence on the indoor temperature. The rise in thermal current temperature makes the vertical temperature gradient in the room increase. The upper temperature of the room becomes higher, as does the height of the high temperature air level that lies in the upper part of the room. Finally, both the heat loss of the surrounding structure and the change in outdoor temperature have a large influence on indoor temperature. However, it does not influence the thermal stratification characteristics of DV. The only thing that has changed is the thermal stratification height.

Wu, X.; Gao, J.; Wu, W.

2006-01-01T23:59:59.000Z

84

Cleco Power - Power Miser New Home Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Cleco Power - Power Miser New Home Program Cleco Power - Power Miser New Home Program Cleco Power - Power Miser New Home Program < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Appliances & Electronics Construction Design & Remodeling Sealing Your Home Windows, Doors, & Skylights Ventilation Heating Heat Pumps Water Heating Program Info State Louisiana Program Type Utility Rate Discount Rebate Amount Discount: 10% discount on energy from November through April for the first five years that the customer lives in participating house. Heat Pump Bonus: Up to $1,000 for eligible heat pump installations Provider Cleco Power Louisiana's Cleco Power offers energy efficiency incentives to eligible

85

Progress Energy Florida - Home Energy Check Audit and Rebate Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Progress Energy Florida - Home Energy Check Audit and Rebate Program Progress Energy Florida - Home Energy Check Audit and Rebate Program < Back Eligibility Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Sealing Your Home Ventilation Heat Pumps Insulation Design & Remodeling Windows, Doors, & Skylights Maximum Rebate Duct Test: $$150 Duct Repair: $100 per unit Reflective Roof: $150 Wall Insulation: $300 Replacement Windows - $250 Window Films/Screens - $100 Program Info State Florida Program Type Utility Rebate Program Rebate Amount Heat Pump (Heat Pump Replacement): $100 - $150 Heat Pump (Strip Heat Replacement): $250 - $350

86

Loveland Water & Power - Home Energy Audit Rebate Program (Colorado) |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Loveland Water & Power - Home Energy Audit Rebate Program Loveland Water & Power - Home Energy Audit Rebate Program (Colorado) Loveland Water & Power - Home Energy Audit Rebate Program (Colorado) < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Heating Heat Pumps Insulation Maximum Rebate $500 Program Info State Colorado Program Type Utility Rebate Program Rebate Amount 50% of the cost up to $500 Loveland Water and Power (LWP) is providing an incentive for customers living in single-family detached homes or attached townhouses that wish to upgrade the energy efficiency of eligible homes. Customers can schedule a

87

Berkeley Electric Cooperative -HomeAdvantage Efficiency Loan Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Berkeley Electric Cooperative -HomeAdvantage Efficiency Loan Berkeley Electric Cooperative -HomeAdvantage Efficiency Loan Program Berkeley Electric Cooperative -HomeAdvantage Efficiency Loan Program < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Construction Design & Remodeling Other Windows, Doors, & Skylights Ventilation Manufacturing Heat Pumps Appliances & Electronics Commercial Lighting Lighting Insulation Water Heating Program Info State South Carolina Program Type Utility Loan Program Rebate Amount HomeAdvantage Loans: $15,000 Provider Berkeley Electric Cooperative Berkeley Electric Cooperative provides HomeAdvantage Loans to qualifying homeowners for energy efficiency upgrades to residences. Measures typically

88

A multi-objective evolutionary algorithm for an effective tuning of fuzzy logic controllers in heating, ventilating and air conditioning systems  

Science Conference Proceedings (OSTI)

This paper focuses on the use of multi-objective evolutionary algorithms to develop smartly tuned fuzzy logic controllers dedicated to the control of heating, ventilating and air conditioning systems, energy performance, stability and indoor comfort ... Keywords: Fuzzy logic controllers, Genetic tuning, HVAC systems, Heating, ventilating, and air conditioning systems, Linguistic 2-tuples representation, Multi-objective evolutionary algorithms, Rule selection

Mara Jos Gacto; Rafael Alcal; Francisco Herrera

2012-03-01T23:59:59.000Z

89

RESIDENTIAL INTEGRATED VENTILATION ENERGY CONTROLLER - Energy ...  

A residential controller is described which is used to manage the mechanical ventilation systems of a home, installed to meet whole-house ventilation requirements, at ...

90

Delmarva Power - Home Performance with Energy Star Incentive Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Delmarva Power - Home Performance with Energy Star Incentive Delmarva Power - Home Performance with Energy Star Incentive Program Delmarva Power - Home Performance with Energy Star Incentive Program < Back Eligibility Installer/Contractor Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Construction Design & Remodeling Other Sealing Your Home Ventilation Manufacturing Heating Heat Pumps Appliances & Electronics Commercial Lighting Lighting Water Heating Maximum Rebate Recommended measures resulting from Energy Audit: $2000 Program Info Funding Source Maryland Energy Administration State Maryland Program Type Utility Rebate Program Rebate Amount Home Energy Audit: Cost discounted to $100 HVAC and Envelope upgrades: up to $2000 Provider

91

Local Energy Alliance Program - Home Performance with ENERGY STAR  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Local Energy Alliance Program - Home Performance with ENERGY STAR Local Energy Alliance Program - Home Performance with ENERGY STAR (Virginia) Local Energy Alliance Program - Home Performance with ENERGY STAR (Virginia) < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Appliances & Electronics Ventilation Heating & Cooling Commercial Heating & Cooling Heat Pumps Water Heating Windows, Doors, & Skylights Maximum Rebate LEAP Program: $500 Rappahannock Electric Cooperative: $600 Program Info Funding Source Local Energy Alliance Program State Virginia Program Type Local Rebate Program Rebate Amount LEAP Program LEAP Home Energy Improvement Program : 20% of cost up to $500 Rappahannock Electric Cooperative Incentives Heat Pump Tune-Up: $75 Duct Sealing: $200

92

Michigan Saves - Home Energy Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Michigan Saves - Home Energy Loan Program Michigan Saves - Home Energy Loan Program Michigan Saves - Home Energy Loan Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Cooling Appliances & Electronics Other Design & Remodeling Windows, Doors, & Skylights Ventilation Heat Pumps Insulation Water Heating Solar Buying & Making Electricity Program Info State Michigan Program Type State Loan Program Rebate Amount $1,000-$20,000 Provider Michigan Saves Michigan Saves is a non-profit that offers financing options for energy efficiency improvements throughout Michigan. The Home Energy Loan Program was started with seed funding from the Michigan Public Service Commission.

93

OpenEI/PageKeyword solar home heating | Open Energy Information  

Open Energy Info (EERE)

to: navigation, search A list of all pages that have property "OpenEIPageKeyword" with value "solar home heating" Gateway:Solar + Property: OpenEIPageKeyword Value: solar home...

94

Genetic lateral and amplitude tuning with rule selection for fuzzy control of heating, ventilating and air conditioning systems  

Science Conference Proceedings (OSTI)

In this work, we propose the use of a new post-processing method for the lateral and amplitude tuning of membership functions combined with a rule selection to develop accurate fuzzy logic controllers dedicated to the control of heating, ventilating ...

R. Alcal; J. Alcal-Fdez; F. J. Berlanga; M. J. Gacto; F. Herrera

2006-06-01T23:59:59.000Z

95

Natural Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Natural Ventilation Natural Ventilation Natural Ventilation May 30, 2012 - 7:56pm Addthis Opening a window is a simple natural ventilation strategy. | Credit: ©iStockphoto/Simotion Opening a window is a simple natural ventilation strategy. | Credit: ©iStockphoto/Simotion What does this mean for me? If you live in a part of the country with cool nights and breezes, you may be able to cool your house with natural ventilation. If you're building a new home, design it to take advantage of natural ventilation. Natural ventilation relies on the wind and the "chimney effect" to keep a home cool. Natural ventilation works best in climates with cool nights and regular breezes. The wind will naturally ventilate your home by entering or leaving windows, depending on their orientation to the wind. When wind blows against your

96

New York Home Heating Oil Prices - U.S. Energy Information ...  

U.S. Energy Information Administration (EIA)

The severity of this spot price increase is causing dramatic changes in residential home heating oil prices, although residential price movements are usually a ...

97

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

No-Regrets Remodeling No-Regrets Remodeling Excerpts from No-Regrets Remodeling by the people at Home Energy magazine. Note: This book was published in 1997. While most of the information is timeless, some items may be out-dated. Your Kitchen Cooking Appliances Electric or Gas Kitchen Ranges? Refrigerators Your Home Office Home Office Equipment Power Ratings of Office Equipment Your Heating Heating: General Home Performance Contractors Oil System Upgrades Combined (Indirect) Hot Water & Heating Systems Combined (Integrated) Space & Water Heating The Thermostat is in Control Time for an Energy Switch? Your Cooling Tips for Buying a New Air Conditioner Cool Roofs for Hot Climates Evaporative Cooler Tips Ventilation, Ducts, Moisture, and Air Leakage Common Air Leakage Sites in the Home

98

Modelica Library for Building Heating, Ventilation and Air-Conditioning Systems  

DOE Green Energy (OSTI)

This paper presents a freely available Modelica library for building heating, ventilation and air conditioning systems. The library is based on the Modelica.Fluid library. It has been developed to support research and development of integrated building energy and control systems. The primary applications are controls design, energy analysis and model-based operation. The library contains dynamic and steady-state component models that are applicable for analyzing fast transients when designing control algorithms and for conducting annual simulations when assessing energy performance. For most models, dimensional analysis is used to compute the performance for operating points that differ from nominal conditions. This allows parameterizing models in the absence of detailed geometrical information which is often impractical to obtain during the conceptual design phase of building systems. In the first part of this paper, the library architecture and the main classes are described. In the second part, an example is presented in which we implemented a model of a hydronic heating system with thermostatic radiator valves and thermal energy storage.

Wetter, Michael

2009-06-17T23:59:59.000Z

99

#tipsEnergy: Saving on Home Heating Costs | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Saving on Home Heating Costs Saving on Home Heating Costs #tipsEnergy: Saving on Home Heating Costs November 23, 2012 - 3:37pm Addthis Rebecca Matulka Rebecca Matulka Digital Communications Specialist, Office of Public Affairs #tipsEnergy: Saving on Home Heating Costs A feature on the Energy Department's Twitter account, #tipsEnergy highlights ways to save energy and money at home. Once a month, we ask you to share your energy-saving tips so the larger energy community can learn from you, and we feature some of the best tips in a Storify. Storified by Energy Department · Fri, Nov 23 2012 12:37:07 As we head into December, the cold weather season is officially upon us, and nowhere is that more evident than on your utility bills. Home heating and cooling uses more energy than any other

100

Energy Efficiency Fund (Electric) - Home Energy Solutions and Performance  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Electric) - Home Energy Solutions and Electric) - Home Energy Solutions and Performance Programs Energy Efficiency Fund (Electric) - Home Energy Solutions and Performance Programs < Back Eligibility Low-Income Residential Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Appliances & Electronics Other Ventilation Heat Pumps Commercial Lighting Lighting Water Heating Windows, Doors, & Skylights Program Info Funding Source Energy Efficiency Fund State Connecticut Program Type Utility Rebate Program Rebate Amount Varies Provider Customer Service The Energy Efficiency Fund, funded by Connecticut's public benefits charge, provides home energy efficiency rebate programs to customers of The

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


101

Monitored energy use of homes with geothermal heat pumps: A compilation and analysis of performance. Final report  

SciTech Connect

The performance of residential geothermal heat pumps (GHPs) was assessed by comparing heating, ventilation, and air conditioning (HVAC) system and whole house energy use of GHP houses and control houses. Actual energy savings were calculated and compared to expected savings (based on ARI ratings and literature) and predicted savings (based on coefficient of performance - COP - measurements). Differences between GHP and control houses were normalized for heating degree days and floor area or total insulation value. Predicted savings were consistently slightly below expected savings but within the range of performance cited by the industry. Average rated COP was 3.4. Average measured COP was 3.1. Actual savings were inconsistent and sometimes significantly below predicted savings. No correlation was found between actual savings and actual energy use. This suggests that factors such as insulation and occupant behavior probably have greater impact on energy use than type of HVAC equipment. There was also no clear correlation between climate and actual savings or between climate and actual energy use. There was a trend between GHP installation date and savings. Newer units appear to have lower savings than some of the older units which is opposite of what one would expect given the increase in rated efficiencies of GHPs. There are a number of explanations for why actual savings are repeatedly below rated savings or predicted savings. Poor ground loop sizing or installation procedures could be an issue. Given that performance is good compared to ASHPs but poor compared to electric resistance homes, the shortfall in savings could be due to duct leakage. The takeback effect could also be a reason for lower than expected savings. Occupants of heat pump homes are likely to heat more rooms and to use more air-conditioning than occupants of electric resistance homes. 10 refs., 17 figs., 10 tabs.

Stein, J.R.; Meier, A.

1997-12-01T23:59:59.000Z

102

Design and Development of an Intelligent Energy Controller for Home Energy Saving in Heating/Cooling System .  

E-Print Network (OSTI)

??Energy is consumed every day at home as we perform simple tasks, such as watching television, washing dishes and heating/cooling home spaces during season of (more)

Abaalkhail, Rana

2012-01-01T23:59:59.000Z

103

Field Measurements of Heating Efficiency of Electric Forced-Air Furnaces in Six Manufactured Homes.  

Science Conference Proceedings (OSTI)

This report presents the results of field measurements of heating efficiency for six manufactured homes in the Pacific Northwest heated with electric forced-air systems. This is the first in a series of regional and national efforts to measure in detail the heating efficiency of manufactured homes. Only six homes were included in this study because of budgetary constraints; therefore this is not a representative sample. These investigations do provide some useful information on the heating efficiency of these homes. Useful comparisons can be drawn between these study homes and site-built heating efficiencies measured with a similar protocol. The protocol used to test these homes is very similar to another Ecotope protocol used in the study conducted in 1992 and 1993 for the Bonneville Power Administration to test the heating efficiency of 24 homes. This protocol combined real-time power measurements of furnace energy usage with energy usage during co-heat periods. Accessory data such as house and duct tightness measurements and tracer gas measurements were used to describe these homes and their heating system efficiency. Ensuring that manufactured housing is constructed in an energy and resource efficient manner is of increasing concern to manufactured home builders and consumers. No comparable work has been done to measure the heating system efficiency of MCS manufactured homes, although some co-heat tests have been performed on manufactured homes heated with natural gas to validate HUD thermal standards. It is expected that later in 1994 more research of this kind will be conducted, and perhaps a less costly and less time-consuming method for testing efficiencies will be develops.

Davis, Bob; Palmiter, Larry S.; Siegel, Jeff

1994-07-26T23:59:59.000Z

104

DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Will Convert Northeast Home Heating Oil Reserve to Ultra Low Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur Distillate DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur Distillate February 1, 2011 - 12:00pm Addthis Washington, DC - The current inventory of the Northeast Home Heating Oil Reserve will be converted to cleaner burning ultra low sulfur distillate to comply with new, more stringent fuel standards by some Northeastern states, the U.S. Department of Energy (DOE) said today. The State of New York and other Northeastern states are implementing more stringent fuel standards that require replacement of high sulfur (2,000 parts per million) heating oil to ultra low sulfur fuel (15 parts per million). As a result, DOE will sell the current inventory of the Northeast Home Heating Oil Reserve, a total of approximately 2 million barrels, and

105

Western Riverside Council of Governments - Home Energy Renovation  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Energy Renovation Home Energy Renovation Opportunity (HERO) Financing Program (California) Western Riverside Council of Governments - Home Energy Renovation Opportunity (HERO) Financing Program (California) < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Sealing Your Home Cooling Other Design & Remodeling Windows, Doors, & Skylights Commercial Weatherization Ventilation Heat Pumps Appliances & Electronics Commercial Lighting Lighting Insulation Solar Buying & Making Electricity Water Heating Wind Program Info State California Program Type PACE Financing Provider WRCOG HERO Financing Program (Residential) Western Riverside Council of Governments (WRCOG) is offering homeowners in WRCOG participating jurisdictions an opportunity to finance energy and

106

DOE Accepts Bids for Northeast Home Heating Oil Stocks | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Accepts Bids for Northeast Home Heating Oil Stocks Accepts Bids for Northeast Home Heating Oil Stocks DOE Accepts Bids for Northeast Home Heating Oil Stocks February 3, 2011 - 12:00pm Addthis Washington, DC - The U.S. Department of Energy (DOE) today has awarded contracts to three companies who successfully bid for the purchase of 984,253 barrels of heating oil from the Northeast Home Heating Oil Reserve. Awardee Amount Morgan Stanley 500,000 barrels Shell Trading U.S. Company 250,000 barrels George E. Warren Corporation 234,253 barrels Today's sale was the first held as part of the Department's initiative to convert the current 1,984,253-barrel heating oil reserve to cleaner burning ultra low sulfur distillate. Contracts for the heating oil will be executed upon final payment to DOE; final payment is required no later than

107

Outdoor Air, Heat Wheels and JCPenney: A New Approach to Retail Ventilation  

E-Print Network (OSTI)

JCPenney Construction Services department is responsible for the construction of new stores, takeover of existing facilities to create a new store, repairs to existing JCPenney facilities and the expansion and modernization of stores across the nation and the world. Each year, JCPenney Construction Services handles approximately 50 projects along these lines. After the implementation of ASHRAE 62- 1989 by JCPenney and many major building codes, including BOCA, mechanical engineers at JCPenney noticed a sharp increase in the percentage of cooling capacity required to cool the outdoor ventilation air. In an effort to limit this impact, both in first cost and in operational costs, JCPenney is beginning to make an effort to use enthalpy heat wheels in the hot and humid climate areas where it is economically feasible. This paper discusses the efforts of JCPenney to implement this option to the treatment of outdoor air in a store in Baton Rouge, LA while maintaining indoor air quality requirements as stated in ASHRAE Standard 62-1989 and maintaining energy efficiency. This paper also discusses the projected energy savings and operations of this alternative to the standard treatment of outdoor air.

Smith, C. S.; Bartlett, T. A.

1998-01-01T23:59:59.000Z

108

DOE to Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

to Sell 35,000 Barrels of Oil from the Northeast Home Heating to Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil Reserve DOE to Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil Reserve May 24, 2007 - 4:16pm Addthis WASHINGTON, DC - The U.S. Department of Energy announced today that it will sell approximately 35,000 barrels of home heating oil from the Northeast Home Heating Oil Reserve (NEHHOR). The Reserve's current 5-year storage contracts expire on September 30, 2007 and market conditions have caused new storage costs to rise to a level that exceeds available funds. Revenue from the sale will be used to supplement funds for the award of new long-term storage contracts that will begin on October 1, 2007. The Department will work with Congress to resolve these funding issues in order

109

DOE to Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Sell 35,000 Barrels of Oil from the Northeast Home Heating Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil Reserve DOE to Sell 35,000 Barrels of Oil from the Northeast Home Heating Oil Reserve May 24, 2007 - 4:16pm Addthis WASHINGTON, DC - The U.S. Department of Energy announced today that it will sell approximately 35,000 barrels of home heating oil from the Northeast Home Heating Oil Reserve (NEHHOR). The Reserve's current 5-year storage contracts expire on September 30, 2007 and market conditions have caused new storage costs to rise to a level that exceeds available funds. Revenue from the sale will be used to supplement funds for the award of new long-term storage contracts that will begin on October 1, 2007. The Department will work with Congress to resolve these funding issues in order to restore the inventory of the Reserve to its full authorized size.

110

DOE Completes Sale of Northeast Home Heating Oil Stocks | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Completes Sale of Northeast Home Heating Oil Stocks Completes Sale of Northeast Home Heating Oil Stocks DOE Completes Sale of Northeast Home Heating Oil Stocks February 10, 2011 - 12:00pm Addthis Washington, DC - The U.S. Department of Energy (DOE) today has awarded contracts to four companies who successfully bid for the purchase of 1,000,000 barrels of heating oil from the Northeast Home Heating Oil Reserve storage sites in Groton and New Haven, CT. Hess Groton Terminal, Groton, CT Shell Trading U.S. Company 150,000 barrels Sprague Energy Corp. 100,000 barrels Magellan New Haven Terminal, New Haven, CT Hess Corporation 300,000 barrels Morgan Stanley 450,000 barrels Today's sale was the second held as part of the Department's initiative to convert the 1,984,253 barrel heating oil reserve to cleaner burning

111

Dominion East Ohio (Gas) - Home Performance Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Dominion East Ohio (Gas) - Home Performance Program Dominion East Ohio (Gas) - Home Performance Program Dominion East Ohio (Gas) - Home Performance Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Appliances & Electronics Water Heating Program Info State Ohio Program Type Utility Rebate Program Rebate Amount Furnace: $300-$400 Boiler: $250-$300 Duct Sealing: $40/hour Air Sealing: $40/hour Programmable Thermostat: $30/thermostat Storage Water Heater: $100 Tankless Water Heater: $150 Condensing Water Heater: $125 Water Heater Tank Insulation: $10 Attic Access Insulation: $30 Wall/Attic/Duct Insulation: $0.30/sq. ft.

112

Columbia Gas of Virginia - Home Savings Rebate Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Columbia Gas of Virginia - Home Savings Rebate Program Columbia Gas of Virginia - Home Savings Rebate Program Columbia Gas of Virginia - Home Savings Rebate Program < Back Eligibility Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Heating & Cooling Commercial Heating & Cooling Heating Appliances & Electronics Water Heating Windows, Doors, & Skylights Program Info State Virginia Program Type Utility Rebate Program Rebate Amount Energy Star Gas Storage Water Heater: $50 Energy Star Gas Tankless Water Heater: $300 High Efficiency Gas Furnace: $300 High Efficiency Windows (Replacement): $1/sq. ft. Attic and Floor Insulation (Replacement): $0.30/sq. ft. Duct Insulation (Replacement): $200 - $250/site Provider Columbia Gas of Virginia

113

Georgia Power - Energy Efficiency Home Improvement Rebates | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Georgia Power - Energy Efficiency Home Improvement Rebates Georgia Power - Energy Efficiency Home Improvement Rebates Georgia Power - Energy Efficiency Home Improvement Rebates < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Construction Design & Remodeling Sealing Your Home Ventilation Manufacturing Heat Pumps Appliances & Electronics Commercial Lighting Lighting Water Heating Maximum Rebate All Incentives: 50% of cost Whole House Improvements: $2,200 Individual Improvements: $700 Program Info Start Date 1/1/2011 Expiration Date 12/31/2012 State Georgia Program Type Utility Rebate Program Rebate Amount Programmable Thermostat: $100 BPI Assessment: $200 Whole House Improvements: 50% Air Sealing: $400 Attic Insulation: $300

114

Whole Building Ventilation Systems  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Whole-Building Whole-Building Ventilation Systems for Existing Homes © 2011 Steven Winter Associates, Inc. All rights reserved. © 2011 Steven Winter Associates, Inc. All rights reserved. Home Performance / Weatherization  Addressing ventilation is the exception  Max tightness, e.g. BPI's "Building Airflow Standard" (BAS)  References ASHRAE 62-89  BAS = Max [0.35 ACH, 15 CFM/person], CFM50 eq.  If BD tests show natural infiltration below BAS...  Ventilation must be recommended or installed.  SO DON'T AIR SEAL TO MUCH! © 2011 Steven Winter Associates, Inc. All rights reserved. © 2011 Steven Winter Associates, Inc. All rights reserved. Ventilation Requirements Ventilation systems for existing homes that are:

115

DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur Distillate DOE Will Convert Northeast Home Heating Oil Reserve to Ultra Low Sulfur Distillate February 1, 2011 - 12:00pm Addthis Washington, DC - The current inventory of the Northeast Home Heating Oil Reserve will be converted to cleaner burning ultra low sulfur distillate to comply with new, more stringent fuel standards by some Northeastern states, the U.S. Department of Energy (DOE) said today. The State of New York and other Northeastern states are implementing more stringent fuel standards that require replacement of high sulfur (2,000 parts per million) heating oil to ultra low sulfur fuel (15 parts per million). As a result, DOE will sell the current inventory of the Northeast

116

Our winters of discontent: Addressing the problem of rising home-heating costs1  

E-Print Network (OSTI)

on fossil fuels by using solar energy, reducing residential energy demand, and promoting district heating. 1ERG/200602 Our winters of discontent: Addressing the problem of rising home-heating costs1 Larry Residential space heating is a necessity in northern countries such as Canada. With over 70 percent

Hughes, Larry

117

Geothermal greenhouse-heating facilities for the Klamath County Nursing Home, Klamath Falls, Oregon  

DOE Green Energy (OSTI)

The Klamath County Nursing Home, located in Klamath Falls, Oregon, was constructed in 1976. The building of 55,654 square feet currently houses care facilities for approximately 120 persons. During the initial planning for the Nursing Home, the present site was selected primarily on the basis of its geothermal resource. This resource (approx. 190/sup 0/F) currently provides space and domestic hot water heating for the Nursing Home, Merle West Medical Center and the Oregon Institute of Technology. The feasibility of installing a geothermal heating system in a planned greenhouse for the Nursing Home is explored. The greenhouse system would be tied directly to the existing hot water heating system for the Nursing Home.

Not Available

1982-02-01T23:59:59.000Z

118

Heat Pump Water Heaters and American Homes: A Good Fit?  

E-Print Network (OSTI)

2001. Residential Heat Pump Water Heater (HPWH) DevelopmentKelso, J. 2003. Incorporating Water Heater Replacement into2005. Residential Heat Pump Water Heaters: Energy Efficiency

Franco, Victor

2011-01-01T23:59:59.000Z

119

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

Home Heating Anderson [21 Oil Price Electric Share Gas ShareBaughman and Joskow [3] Oil Price Gas Price Lin, Hirst,and Cohn [10] Gas Price Oil Price Hartman and Hollyer [8] (

Wood, D.J.

2010-01-01T23:59:59.000Z

120

What is the outlook for home heating fuel prices this winter ...  

U.S. Energy Information Administration (EIA)

What is the outlook for home heating fuel prices this winter? According to EIA's Short Term Energy Outlook released on August 6, 2013, the projections for U.S ...

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


121

DOE Seeks Commercial Storage to Complete Fill of Northeast Home Heating Oil  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

to Complete Fill of Northeast Home to Complete Fill of Northeast Home Heating Oil Reserve DOE Seeks Commercial Storage to Complete Fill of Northeast Home Heating Oil Reserve August 26, 2011 - 1:00pm Addthis Washington, DC - The Department of Energy (DOE), through its agent DLA Energy, has issued a solicitation seeking commercial storage contracts for the remaining 350,000 barrels of ultra low sulfur distillate needed to complete the fill of the Northeast Home Heating Oil Reserve. Offers are due no later than 9:00 a.m., August 31, 2011. Earlier this year, DOE sold its entire inventory of heating oil stocks with plans to replace it with cleaner burning ultra low sulfur distillate. New storage contracts were awarded in August 2011 for 650,000 barrels, and awards from this solicitation will complete the fill of the one million

122

Heat Pump Water Heaters and American Homes: A Good Fit?  

NLE Websites -- All DOE Office Websites (Extended Search)

can be cost effective in all regionsfor most single family homes, especially when the water heater is not installed in a conditioned space. HPWHs are not cost effective for most...

123

Assisted Home Performance Grants | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Assisted Home Performance Grants Assisted Home Performance Grants Assisted Home Performance Grants < Back Eligibility Low-Income Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Appliances & Electronics Sealing Your Home Ventilation Manufacturing Commercial Lighting Lighting Cooling Water Heating Maximum Rebate Single-family: $5,000 Multi-family (2-4 units): $10,000 per building Program Info Funding Source Energy Efficiency Portfolio Standard (EEPS) State New York Program Type State Grant Program Rebate Amount 50% of costs Provider New York State Energy Research and Development Authority The Assisted Home Performance Program provides grants to low-income home owners in 1-4 family buildings for up to 50% of costs for energy efficient

124

Initial Business Case Analysis of Two Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes  

SciTech Connect

The long range strategic goal of the Department of Energy's Building Technologies (DOE/BT) Program is to create, by 2020, technologies and design approaches that enable the construction of net-zero energy homes at low incremental cost (DOE/BT 2005). A net zero energy home (NZEH) is a residential building with greatly reduced needs for energy through efficiency gains, with the balance of energy needs supplied by renewable technologies. While initially focused on new construction, these technologies and design approaches are intended to have application to buildings constructed before 2020 as well resulting in substantial reduction in energy use for all building types and ages. DOE/BT's Emerging Technologies (ET) team is working to support this strategic goal by identifying and developing advanced heating, ventilating, air-conditioning, and water heating (HVAC/WH) technology options applicable to NZEHs. Although the energy efficiency of heating, ventilating, and air-conditioning (HVAC) equipment has increased substantially in recent years, new approaches are needed to continue this trend. Dramatic efficiency improvements are necessary to enable progress toward the NZEH goals, and will require a radical rethinking of opportunities to improve system performance. The large reductions in HVAC energy consumption necessary to support the NZEH goals require a systems-oriented analysis approach that characterizes each element of energy consumption, identifies alternatives, and determines the most cost-effective combination of options. In particular, HVAC equipment must be developed that addresses the range of special needs of NZEH applications in the areas of reduced HVAC and water heating energy use, humidity control, ventilation, uniform comfort, and ease of zoning. In FY05 ORNL conducted an initial Stage 1 (Applied Research) scoping assessment of HVAC/WH systems options for future NZEHs to help DOE/BT identify and prioritize alternative approaches for further development. Eleven system concepts with central air distribution ducting and nine multi-zone systems were selected and their annual and peak demand performance estimated for five locations: Atlanta (mixed-humid), Houston (hot-humid), Phoenix (hot-dry), San Francisco (marine), and Chicago (cold). Performance was estimated by simulating the systems using the TRNSYS simulation engine (Solar Energy Laboratory et al. 2006) in two 1800-ft{sup 2} houses--a Building America (BA) benchmark house and a prototype NZEH taken from BEopt results at the take-off (or crossover) point (i.e., a house incorporating those design features such that further progress towards ZEH is through the addition of photovoltaic power sources, as determined by current BEopt analyses conducted by NREL). Results were summarized in a project report, 'HVAC Equipment Design options for Near-Zero-Energy Homes--A Stage 2 Scoping Assessment,' ORNL/TM-2005/194 (Baxter 2005). The 2005 study report describes the HVAC options considered, the ranking criteria used, and the system rankings by priority. Table 1 summarizes the energy savings potential of the highest scoring options from the 2005 study for all five locations.

Baxter, Van D [ORNL

2006-11-01T23:59:59.000Z

125

Most homes have central thermostats on heating and cooling ...  

U.S. Energy Information Administration (EIA)

... solar, wind , geothermal ... Quarterly Coal Report Monthly Energy Review Residential Energy ... main heating equipment is a portable heater, ...

126

Be SMART Home Efficiency Rebate Program (Maryland) | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Rebate Program (Maryland) Rebate Program (Maryland) Be SMART Home Efficiency Rebate Program (Maryland) < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Appliances & Electronics Sealing Your Home Ventilation Heating Heat Pumps Water Heating Maximum Rebate Total: $4,250 Building Envelope Improvements: $2,000 Program Info State Maryland Program Type State Rebate Program Rebate Amount Energy Audit: $300 (paid to contractor) Building Envelope Improvements: 50% of cost HVAC Equipment: varies by measure, $25 - $500 Water Heating: varies by measure, $25 - $350 Appliances: varies by measure, $75 - $150 Provider Maryland Department of Housing and Community Development '''''Note: This program is expiring. Homeowner rebate applications and

127

Energy Efficiency Fund (Gas) - Home Energy Solutions and Performance  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Gas) - Home Energy Solutions and Gas) - Home Energy Solutions and Performance Programs Energy Efficiency Fund (Gas) - Home Energy Solutions and Performance Programs < Back Eligibility Low-Income Residential Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Other Ventilation Appliances & Electronics Water Heating Program Info State Connecticut Program Type Utility Rebate Program Rebate Amount Varies Provider Customer Service The Energy Efficiency Fund, funded by Connecticut's public benefits charge, provides home energy efficiency rebate programs to customers of The Connecticut Light and Power Company and The United Illuminating Company, Connecticut Natural Gas, Southern Connecticut Gas, and Yankeegas customers. The Home Energy Solutions Program provides weatherization assistance to any

128

Project title: Natural ventilation, solar heating and integrated low-energy building design  

E-Print Network (OSTI)

of integrated low-energy building design. In Cambridge, research was conducted at the BP Institute - which was set up in 1999 with an endowment from BP to research some of the fundamental scientific challenges that the oil industry encounters. In the CMI... in building design. Summary of Intended Outcomes: The objectives of the project will be to develop designs and technologies to: reduce energy costs of maintaining a comfortable environment with buildings through use of solar power, natural ventilation...

2009-07-10T23:59:59.000Z

129

Investigations of novel heat pump systems for low carbon homes.  

E-Print Network (OSTI)

??The European standard EN15450 states that the Coefficient of Performance (COP) target range for a Ground Source Heat Pump (GSHP) installation should lie within the (more)

Mempouo, B.

2011-01-01T23:59:59.000Z

130

Homes  

Energy.gov (U.S. Department of Energy (DOE))

The U.S. Department of Energy (DOE) improves home energy performance by developing and demonstrating advanced energy efficiency technologies and practices that make homes in the United States more...

131

Sealing Your Home | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Sealing Your Home Sealing Your Home Sealing Your Home Caulking can reduce heating and cooling costs and improve comfort in your home. Caulking can reduce heating and cooling costs and improve comfort in your home. Air leakage, or infiltration, occurs when outside air enters a house uncontrollably through cracks and openings. Properly air sealing can significantly reduce heating and cooling costs, improve building durability, and create a healthier indoor environment. In addition to air sealing, you'll also want to consider adding additional insulation and moisture control and ventilation strategies to ensure your home is comfortable and efficient. Featured Detecting Air Leaks For a thorough and accurate measurement of air leakage in your home, hire a qualified technician to conduct an energy assessment, particularly a blower door test.

132

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

3 3 Main Commercial Primary Energy Use of Heating and Cooling Equipment as of 1995 Heating Equipment | Cooling Equipment Packaged Heating Units 25% | Packaged Air Conditioning Units 54% Boilers 21% | Room Air Conditioning 5% Individual Space Heaters 2% | PTAC (2) 3% Furnaces 20% | Centrifugal Chillers 14% Heat Pumps 5% | Reciprocating Chillers 12% District Heat 7% | Rotary Screw Chillers 3% Unit Heater 18% | Absorption Chillers 2% PTHP & WLHP (1) 2% | Heat Pumps 7% 100% | 100% Note(s): Source(s): 1) PTHP = Packaged Terminal Heat Pump, WLHP = Water Loop Heat Pump. 2) PTAC = Packaged Terminal Air Conditioner BTS/A.D. Little, Energy Consumption Characteristics of Commercial Building HVAC Systems, Volume 1: Chillers, Refrigerant Compressors, and Heating Systems, Apr. 2001, Figure 5-5, p. 5-14 for cooling and Figure 5-10, p. 5-18 for heating

133

Why We Ventilate  

NLE Websites -- All DOE Office Websites (Extended Search)

Why We Ventilate Why We Ventilate Title Why We Ventilate Publication Type Conference Paper LBNL Report Number LBNL-5093E Year of Publication 2011 Authors Logue, Jennifer M., Phillip N. Price, Max H. Sherman, and Brett C. Singer Conference Name Proceedings of the 2011 32nd AIVC Conference and 1st Tightvent Conference Date Published October 2011 Conference Location Brussels, Belgium Keywords indoor environment department, resave, ventilation and air cleaning Abstract It is widely accepted that ventilation is critical for providing good indoor air quality (IAQ) in homes. However, the definition of "good" IAQ, and the most effective, energy efficient methods for delivering it are still matters of research and debate. This paper presents the results of work done at the Lawrence Berkeley National Lab to identify the air pollutants that drive the need for ventilation as part of a larger effort to develop a health-based ventilation standard. First, we present results of a hazard analysis that identified the pollutants that most commonly reach concentrations in homes that exceed health-based standards or guidelines for chronic or acute exposures. Second, we present results of an impact assessment that identified the air pollutants that cause the most harm to the U.S. population from chronic inhalation in residences. Lastly, we describe the implications of our findings for developing effective ventilation standards.

134

Optimization of the Fin Heat Pipe for Ventilating and Air Conditioning with a Genetic Algorithm  

E-Print Network (OSTI)

This paper illustrates that use of a heat pipe as a heat-reclaiming device can significantly influence the air-conditioning system. It analyzes the heat transfer model of the uniform annular fin heat pipe under the condition of air conditioning. It establishes functions of the fin structure parameters such as height,spacing and thickness of the fin when the volume of fin is the smallest under unit temperature difference and unit quantity of heat. It uses a genetic algorithm to optimize the model of the uniform annular fin heat pipe. The calculation result shows that the method of genetic algorithm is effective.

Qian, J.; Sun, D.; Li, G.

2006-01-01T23:59:59.000Z

135

Whole-House Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Whole-House Ventilation Whole-House Ventilation Whole-House Ventilation May 30, 2012 - 2:37pm Addthis A whole-house ventilation system with dedicated ducting in a new energy-efficient home. | Photo courtesy of ©iStockphoto/brebca. A whole-house ventilation system with dedicated ducting in a new energy-efficient home. | Photo courtesy of ©iStockphoto/brebca. What does this mean for me? Whole-house ventilation is critical in an energy-efficient home to maintain adequate indoor air quality and comfort. The whole-house ventilation system you choose will depend upon your climate, budget, and the availability of experienced contractors in your area. Energy-efficient homes -- both new and existing -- require mechanical ventilation to maintain indoor air quality. There are four basic mechanical

136

Transpired Solar Collector at NREL's Waste Handling Facility Uses Solar Energy to Heat Ventilation Air (Fact Sheet) (Revised), Federal Energy Management Program (FEMP)  

NLE Websites -- All DOE Office Websites (Extended Search)

Highlights Highlights System Size 300 ft 2 transpired solar collector Energy Production About 125 Btu/hr/ft 2 (400 W/m 2 ) of heat delivery under ideal conditions (full sun) Installation Date 1990 Motivation Provide solar-heated ventilation air to offset some of the heating with conventional electric resistance heaters Annual Savings 14,310 kWh (49 million Btu/yr) or about 26% of the energy required to heat the facility's ventilation air System Details Components Black, 300 ft 2 corrugated aluminum transpired solar collector with a porosity of 2%; bypass damper; two-speed 3000 CFM vane axial supply fan; electric duct heater; thermostat controller Storage None Loads 188 million Btu/year (55,038 kWh/year) winter average to heat 1,300 ft 2 Waste Handling Facility

137

Transpired Solar Collector at NREL's Waste Handling Facility Uses Solar Energy to Heat Ventilation Air (Fact Sheet) (Revised), Federal Energy Management Program (FEMP)  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Highlights Highlights System Size 300 ft 2 transpired solar collector Energy Production About 125 Btu/hr/ft 2 (400 W/m 2 ) of heat delivery under ideal conditions (full sun) Installation Date 1990 Motivation Provide solar-heated ventilation air to offset some of the heating with conventional electric resistance heaters Annual Savings 14,310 kWh (49 million Btu/yr) or about 26% of the energy required to heat the facility's ventilation air System Details Components Black, 300 ft 2 corrugated aluminum transpired solar collector with a porosity of 2%; bypass damper; two-speed 3000 CFM vane axial supply fan; electric duct heater; thermostat controller Storage None Loads 188 million Btu/year (55,038 kWh/year) winter average to heat 1,300 ft 2 Waste Handling Facility

138

Home Energy Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Home Energy Loan Program Home Energy Loan Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Cooling Construction Design & Remodeling Other Ventilation Heat Pumps Appliances & Electronics Water Heating Maximum Rebate $30,000 Program Info Funding Source American Recovery and Reinvestment Act of 2009 Start Date 01/2011 State Maryland Program Type State Loan Program Rebate Amount Loans from $1,500 - $30,000 Provider Maryland Clean Energy Center Note: The eligible technologies listed above are only examples of some improvements that might be supported under this program as detailed on the program web site. Other improvements may be eligible and not all

139

Acoustical prediction methods for heating, ventilating, and air?conditioning (HVAC) systems  

Science Conference Proceedings (OSTI)

The goal of this project is to compare and contrast various aspects of acoustical prediction methods for heating

2005-01-01T23:59:59.000Z

140

How Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? How Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? September 23, 2010 - 7:30am Addthis On Monday, Chris told you about his new ceiling fan and how it's changed the way he cools his home. In warm weather, ceiling fans cool people (not rooms) by producing a wind-chill effect-which is why you should turn off fans when you leave the room. A ceiling fan allows you to raise the thermostat setting about 4°F with no reduction in comfort. Ceiling fans don't just cool in the summer; you can also reverse the direction in the winter to provide an updraft and force warm air down into the room. How has a ceiling fan affected the way you heat and cool your home? Each Thursday, you have the chance to share your thoughts on a question

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


141

How Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? How Has a Ceiling Fan Affected the Way You Heat and Cool Your Home? September 23, 2010 - 7:30am Addthis On Monday, Chris told you about his new ceiling fan and how it's changed the way he cools his home. In warm weather, ceiling fans cool people (not rooms) by producing a wind-chill effect-which is why you should turn off fans when you leave the room. A ceiling fan allows you to raise the thermostat setting about 4°F with no reduction in comfort. Ceiling fans don't just cool in the summer; you can also reverse the direction in the winter to provide an updraft and force warm air down into the room. How has a ceiling fan affected the way you heat and cool your home? Each Thursday, you have the chance to share your thoughts on a question

142

Anaheim Public Utilities - Residential Home Efficiency Rebate Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Residential Home Efficiency Rebate Residential Home Efficiency Rebate Program Anaheim Public Utilities - Residential Home Efficiency Rebate Program < Back Eligibility Low-Income Residential Multi-Family Residential Residential Savings Category Heating & Cooling Cooling Commercial Heating & Cooling Appliances & Electronics Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Manufacturing Commercial Lighting Lighting Windows, Doors, & Skylights Maximum Rebate Air Duct Repair: $300 Ceiling Fan: 3 fans Program Info State California Program Type Utility Rebate Program Rebate Amount Refrigerator: $50 Refrigerator Recycling: $50 Dishwasher: $50 Room A/C: $50 Central A/C: $100/ton High Performance windows: $1/sq ft Air Duct Repair: 50% of repair cost Ceiling Fan: $20 Whole House Fan: $100

143

Home  

NLE Websites -- All DOE Office Websites (Extended Search)

Skip Navigation Links Home Newsroom About INL Careers Research Programs Facilities Education Distinctive Signature: ICIS Environment, Safety & Health Research Library Technology...

144

Solar heating and cooling of mobile homes, Phase II. Final report  

DOE Green Energy (OSTI)

The specific objectives of the Phase II program were: (1) through system testing, confirm the feasibility of a solar heated and cooled mobile home; (2) update system performance analysis and provide solar heating and cooling computer model verification; (3) evaluate the performance of both an absorption and a Rankine air conditioning system; (4) perform a consumer demand analysis through field survey to ascertain the acceptance of solar energy into the mobile home market; and (5) while at field locations to conduct the consumer demand analysis, gather test data from various U.S. climatic zones. Results are presented and discussed. (WHK)

Jacobsen, A.A.

1976-12-01T23:59:59.000Z

145

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

2 2 Main Commercial Heating and Cooling Equipment as of 1995, 1999, and 2003 (Percent of Total Floorspace) (1) Heating Equipment 1995 1999 2003 (2) Cooling Equipment 1995 1999 2003 (2) Packaged Heating Units 29% 38% 28% Packaged Air Conditioning Units 45% 54% 46% Boilers 29% 29% 32% Individual Air Conditioners 21% 21% 19% Individual Space Heaters 29% 26% 19% Central Chillers 19% 19% 18% Furnaces 25% 21% 30% Residential Central Air Conditioners 16% 12% 17% Heat Pumps 10% 13% 14% Heat Pumps 12% 14% 14% District Heat 10% 8% 8% District Chilled Water 4% 4% 4% Other 11% 6% 5% Swamp Coolers 4% 3% 2% Other 2% 2% 2% Note(s): Source(s): 1) Heating and cooling equipment percentages of floorspace total more than 100% since equipment shares floorspace. 2) Malls are no longer included in most CBECs tables; therefore, some data is not directly comparable to past CBECs.

146

Why We Ventilate  

SciTech Connect

It is widely accepted that ventilation is critical for providing good indoor air quality (IAQ) in homes. However, the definition of"good" IAQ, and the most effective, energy efficient methods for delivering it are still matters of research and debate. This paper presents the results of work done at the Lawrence Berkeley National Lab to identify the air pollutants that drive the need for ventilation as part of a larger effort to develop a health-based ventilation standard. First, we present results of a hazard analysis that identified the pollutants that most commonly reach concentrations in homes that exceed health-based standards or guidelines for chronic or acute exposures. Second, we present results of an impact assessment that identified the air pollutants that cause the most harm to the U.S. population from chronic inhalation in residences. Lastly, we describe the implications of our findings for developing effective ventilation standards.

Logue, Jennifer M.; Sherman, Max H.; Price, Phil N.; Singer, Brett C.

2011-09-01T23:59:59.000Z

147

Advanced control strategies for heating, ventilation, air-conditioning, and refrigeration systemsAn overview: Part I: Hard control  

SciTech Connect

A chronological overview of the advanced control strategies for heating, ventilation, air-conditioning, and refrigeration (HVAC&R) is presented in this article. The overview focuses on hard-computing or control techniques, such as proportional-integral-derivative, optimal, nonlinear, adaptive, and robust; soft-computing or control techniques, such as neural networks, fuzzy logic, genetic algorithms; and on the fusion or hybrid of hard- and soft-control techniques. Thus, it is to be noted that the terminology hard and soft computing/control has nothing to do with the hardware and software that is being generally used. Part I of a two-part series focuses on hard-control strategies, and Part II focuses on softand fusion-control in addition to some future directions in HVAC&R research. This overview is not intended to be an exhaustive survey on this topic, and any omission of other works is purely unintentional.

D. Subbaram Naidu; Craig G. Rieger

2011-02-01T23:59:59.000Z

148

Spot Ventilation: Source Control to Improve Indoor Air Quality  

SciTech Connect

Fact sheet for homeowners and contractors on how to employ spot ventilation in the home for comfort and safety.

2002-12-01T23:59:59.000Z

149

Whole-House Ventilation Systems: Improved Control of Air Quality  

SciTech Connect

Fact sheet for homeowners and contractors on how to employ spot ventilation in the home for comfort and safety.

2002-12-01T23:59:59.000Z

150

BETTER DUCT SYSTEMS FOR HOME HEATING AND COOLING.  

SciTech Connect

This is a series of six guides intended to provide a working knowledge of residential heating and cooling duct systems, an understanding of the major issues concerning efficiency, comfort, health, and safety, and practical tips on installation and repair of duct systems. These guides are intended for use by contractors, system designers, advanced technicians, and other HVAC professionals. The first two guides are also intended to be accessible to the general reader.

ANDREWS,J.

2001-01-01T23:59:59.000Z

151

Air-to-Water Heat Pumps With Radiant Delivery in Low-Load Homes  

SciTech Connect

Space conditioning represents nearly 50% of average residential household energy consumption, highlighting the need to identify alternative cost-effective, energy-efficient cooling and heating strategies. As homes are better built, there is an increasing need for strategies that are particularly well suited for high performance, low load homes. ARBI researchers worked with two test homes in hot-dry climates to evaluate the in-situ performance of air-to-water heat pump (AWHP) systems, an energy efficient space conditioning solution designed to cost-effectively provide comfort in homes with efficient, safe, and durable operation. Two monitoring projects of test houses in hot-dry climates were initiated in 2010 to test this system. Both systems were fully instrumented and have been monitored over one year to capture complete performance data over the cooling and heating seasons. Results are used to quantify energy savings, cost-effectiveness, and system performance using different operating modes and strategies. A calibrated TRNSYS model was developed and used to evaluate performance in various climate regions. This strategy is most effective in tight, insulated homes with high levels of thermal mass (i.e. exposed slab floors).

Backman, C.; German, A.; Dakin, B.; Springer, D.

2013-12-01T23:59:59.000Z

152

A database of PFT ventilation measurements  

SciTech Connect

About five years ago, a method for measuring the ventilation flows of a building was developed at Brookhaven National Laboratory (BNL). This method is based on the use of a family of compounds known as perfluorocarbon tracers or PFTs. Since 1982, BNL has measured ventilation in more than 4000 homes, comprising about 100 separate research projects throughout the world. This measurement set is unique in that it is the only set of ventilation measurements that acknowledge and measure the multizone characteristics of residences. Other large measurement sets assume that a home can be treated as a single well-mixed zone. This report describes the creation of a database of approximately half of the PFT ventilation measurements made by BNL over the last five years. The PFT database is currently available for use on any IBM PC or Apple Macintosh based personal computer system. In addition to its utility in modeling indoor pollutant dispersion, this database may also be useful to those people studying energy conservation, thermal comfort and heating system design in residential buildings. 2 refs.

D' Ottavio, T.W.; Goodrich, R.W.; Spandau, D.J.; Dietz, R.N.

1988-08-01T23:59:59.000Z

153

Comparison of actual and predicted energy savings in Minnesota gas-heated single-family homes  

Science Conference Proceedings (OSTI)

Data available from a recent evaluation of a home energy audit program in Minnesota are sufficient to allow analysis of the actual energy savings achieved in audited homes and of the relationship between actual and predicted savings. The program, operated by Northern States Power in much of the southern half of the state, is part of Minnesota's version of the federal Residential Conservation Service. NSP conducted almost 12 thousand RCS audits between April 1981 (when the progam began) and the end of 1982. The data analyzed here, available for 346 homes that obtained an NSP energy audit, include monthly natural gas bills from October 1980 through April 1983; heating degree day data matched to the gas bills; energy audit reports; and information on household demographics, structure characteristics, and recent conservation actions from mail and telephone surveys. The actual reduction in weather-adjusted natural gas use between years 1 and 3 averaged 19 MBtu across these homes (11% of preprogram consumption); the median value of the saving was 16 MBtu/year. The variation in actual saving is quite large: gas consumption increased in almost 20% of the homes, while gas consumption decreased by more than 50 MBtu/year in more than 10% of the homes. These households reported an average expenditure of almost $1600 for the retrofit measures installed in their homes; the variation in retrofit cost, while large, was not as great as the variation in actual natural gas savings.

Hirst, E.; Goeltz, R.

1984-03-01T23:59:59.000Z

154

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

3 3 Residential Boiler Efficiencies (1) Gas-Fired Boilers Oil-Fired Boilers Average shipped in 1985 (2): 74% AFUE Average shipped in 1985 (2): 79% AFUE Best Available in 1981: 81% AFUE Best Available in 1981: 86% AFUE Best Available in 2007: 96% AFUE Best Available in 2007: 89% AFUE Note(s): Source(s): 1) Federal appliance standards effective Jan. 1, 1992, require a minimum of 80% AFUE (except gas-fired steam boiler, which must have a 75% AFUE or higher). 2) Includes furnaces. GAMA, Consumer's Directory of Certified Efficiency Ratings for Residential Heating and Water Heating Equipment, Aug. 2005, p. 88 and 106 for best- available AFUE; and GAMA for 1985 average AFUEs; GAMA Tax Credit Eligible Equipment: Gas- and Oil-Fired Boilers 95% AFUE or Greater, May 2007; and GAMA Consumer's Directory of Certified Efficiency Ratings for Heating and Water Heating Equipment, May 2007

155

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation...  

Buildings Energy Data Book (EERE)

Standard (Trane) 14% York 12% Nordyne 12% Rheem 9% Lennox 9% Others 3% Total 100% Note(s): Source(s): 5,833,354 1) Does not include water-source or ground-source heat pumps....

156

EERE: Homes  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

RENEWABLE ENERGY AND BEING ENERGY EFFICIENT AT HOME Incentives Tax Credits, Rebates, and Savings Save Money and Energy at Home Appliances Energy Assessments Water Heating Using...

157

Home Performance with Energy Star High Efficiency Measure Incentive (HEMI)  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Performance with Energy Star High Efficiency Measure Incentive Home Performance with Energy Star High Efficiency Measure Incentive (HEMI) Home Performance with Energy Star High Efficiency Measure Incentive (HEMI) < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Appliances & Electronics Sealing Your Home Ventilation Manufacturing Commercial Lighting Lighting Water Heating Maximum Rebate $3,000 Program Info State New York Program Type State Rebate Program Rebate Amount 10% of project costs Provider New York State Energy Research and Development Authority The New York State Research and Development Authority (NYSERDA) offers an incentive for homeowners of 1-4 homes that participate in the Home Performance with Energy Star program. The program entitles the participant

158

First Electric Cooperative - Home Improvement Loans | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

First Electric Cooperative - Home Improvement Loans First Electric Cooperative - Home Improvement Loans First Electric Cooperative - Home Improvement Loans < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Heating & Cooling Commercial Heating & Cooling Heat Pumps Appliances & Electronics Water Heating Maximum Rebate $15,000 Program Info State Arkansas Program Type Utility Loan Program Rebate Amount $500 - $15,000 Provider First Electric Cooperative First Electric Cooperative, a Touchstone Energy® Cooperative, serves over 85,000 member accounts throughout parts of seventeen counties in central and southeast Arkansas. The Home Improvement Loan Program allows members to borrow between $500 and $15,000 for energy efficiency home improvements

159

Model of home heating and calculation of rates of return to household energy conservation investment  

Science Conference Proceedings (OSTI)

This study attempts to find out if households' investments on energy conservation yield expected returns. It first builds a home-heating regression model, then uses the results of the model to calculate the rates of return for households' investments on the energy conservation. The home heating model includes housing characteristics, economic and demographic variables, appliance related variables, and regional dummy variables. Housing characteristic variables are modeled according to the specific physical relationship between the house and its heating requirement. Data from the Residential Energy Consumption Survey (RECS) of 1980-1981 is used for the empirical testing of the model. The model is estimated for single-detached family houses separately for three major home-heating fuel types: electricity, natural gas and fuel oil. Four scenarios are used to calculate rates of return for each household. The results show in the Northern areas the rates of return in most of the cases are a lot higher than market interest rates. In the Western and Southern areas, with few exceptions, the rates of return are lower than market interest rates. The variation of heating degree days and energy prices can affect the rates of return up to 20 percentage points.

Hsueh, L.M.

1984-01-01T23:59:59.000Z

160

Alliant Energy Interstate Power and Light - New Home Construction  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Alliant Energy Interstate Power and Light - New Home Construction Alliant Energy Interstate Power and Light - New Home Construction Incentives Alliant Energy Interstate Power and Light - New Home Construction Incentives < Back Eligibility Construction Multi-Family Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Construction Design & Remodeling Windows, Doors, & Skylights Ventilation Heat Pumps Appliances & Electronics Commercial Lighting Lighting Water Heating Program Info State Iowa Program Type Utility Rebate Program Rebate Amount Builder Option Package: Up to $2,000 Advanced Builder Option Package: Up to $2,800 Energy Star Qualified Home: Up to $3,500 Multi-Family Incentives: See program web site Provider

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


161

Energy Efficient Home Improvements Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Energy Efficient Home Improvements Loan Program Energy Efficient Home Improvements Loan Program Energy Efficient Home Improvements Loan Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Cooling Other Ventilation Heat Pumps Appliances & Electronics Water Heating Maximum Rebate Loans: Up to $20,000 for 100% of cost as long as 85% of work is for qualifying home improvements Homeowner Energy Efficient Rebates (in lieu of loans): 20% of qualifying improvements up to $2,000 Program Info State Kentucky Program Type State Loan Program Rebate Amount 100% of costs up to $20,000 '''''Note: This program is currently unavailable. Check the program web site for more information regarding future funding.'''''

162

Baltimore Gas and Electric Company - Home Performance with Energy Star  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Baltimore Gas and Electric Company - Home Performance with Energy Baltimore Gas and Electric Company - Home Performance with Energy Star Rebates Baltimore Gas and Electric Company - Home Performance with Energy Star Rebates < Back Eligibility Installer/Contractor Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Construction Design & Remodeling Sealing Your Home Ventilation Manufacturing Heating Heat Pumps Appliances & Electronics Commercial Lighting Lighting Water Heating Maximum Rebate HVAC (Equipment Installation/Duct Sealing/Tune-up): $1,150 Air Sealing/Insulation/Gas Tankless Water Heater: $2,000 Total: $3,150 Program Info Funding Source Maryland Energy Administration State Maryland Program Type Utility Rebate Program Rebate Amount Comprehensive Home Energy Audit: Reduced cost of $100

163

Energy Efficient Home Improvements Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Energy Efficient Home Improvements Program Energy Efficient Home Improvements Program Energy Efficient Home Improvements Program < Back Eligibility Installer/Contractor Low-Income Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Cooling Other Ventilation Heat Pumps Appliances & Electronics Water Heating Program Info State Kentucky Program Type State Rebate Program Rebate Amount Homeowner energy efficient improvements (in lieu of loans): 20% of qualifying costs up to $2,000 Whole-house evaluation: $150 for the first 1000 customers '''''Note: This program is currently unavailable. Check the program web site for more information regarding future funding.''''' Kentucky offers ENERGY STAR Home Performance rebates and loans for

164

Overall U-values and heating/cooling loads: Manufactured homes  

SciTech Connect

This manual specifies a method for calculating the overall thermal transmittance (also referred to as the overall U-value or U{sub o}), heating load, and cooling load of a manufactured (mobile) home. Rules, examples, and data required by the method are also presented. Compliance with the Department of Housing and Urban Development`s (HUD) U{sub o} and load calculation regulations contained in Sections 3280.506, 3280.510 and 3280.511 of the Manufactured Home Construction and Safety Standards must be demonstrated through the application of the method provided herein.

Conner, C.C.; Taylor, Z.T.

1992-02-01T23:59:59.000Z

165

Overall U-values and heating/cooling loads: Manufactured homes  

SciTech Connect

This manual specifies a method for calculating the overall thermal transmittance (also referred to as the overall U-value or U{sub o}), heating load, and cooling load of a manufactured (mobile) home. Rules, examples, and data required by the method are also presented. Compliance with the Department of Housing and Urban Development's (HUD) U{sub o} and load calculation regulations contained in Sections 3280.506, 3280.510 and 3280.511 of the Manufactured Home Construction and Safety Standards must be demonstrated through the application of the method provided herein.

Conner, C.C.; Taylor, Z.T.

1992-02-01T23:59:59.000Z

166

Overall U-values and heating/cooling loads: Manufactured homes  

SciTech Connect

This manual specifies a method for calculating the overall thermal transmittance (also referred to as the overall U-value or U{sub o}), heating load, and cooling load of a manufactured (mobile) home. Rules, examples, and data required by the method are also presented. Compliance with the Department of Housing and Urban Development's (HUD) U{sub o} and load calculation regulations contained in Sections 3280.506, 3280.510 and 3280.511 of the Manufactured Home Construction and Safety Standards must be demonstrated through the application of the method provided herein.

Conner, C.C.; Taylor, Z.T.

1992-02-01T23:59:59.000Z

167

Preoperational test report, vent building ventilation system  

Science Conference Proceedings (OSTI)

This represents a preoperational test report for Vent Building Ventilation Systems, Project W-030. Project W-030 provides a ventilation upgrade for the four Aging Waste Facility tanks. The system provides Heating, Ventilation, and Air Conditioning (HVAC) for the W-030 Ventilation Building. The tests verify correct system operation and correct indications displayed by the central Monitor and Control System.

Clifton, F.T.

1997-11-04T23:59:59.000Z

168

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

U.S. Heating and Air-Conditioning System Manufacturer Shipments, by Type (Including Exports) 2005 Value of 2000 2005 2007 2009 2010 Shipments Equipment Type (1,000s) (1,000s) (1,000s) (1,000s) (1,000s) ($million) (7) Air-Conditioners (1) 5,346 6,472 4,508 3,516 3419 5,837 Heat Pumps 1,539 2,336 1,899 1,642 1,748 2,226 Air-to-Air Heat Pumps 1,339 2,114 1,899 1,642 1748 1,869 Water-Source Heat Pumps (2) 200 222 N.A. N.A. N.A. 357 Chillers 38 37 37 25 29 1,093 Reciprocating 25 24 30 20 24 462 Centrifugal/Screw 8 6 7 5 5 566 Absorption (3) 5 7 N.A. N.A. N.A. 64 Furnaces 3,681 3,624 2,866 2,231 2,509 2,144 Gas-Fired (4) 3,104 3,512 2,782 2,175 2453 2,081 Electric 455 N.A. N.A. N.A. N.A. N.A. Oil-Fired (5) 121 111 84 56 56 63 Boilers (6) 368 370 N.A. N.A. N.A. N.A. Note(s): Source(s): 1) Includes exports and gas air conditioners (gas units <10,000 units/yr) and rooftop equipment. Excludes heat pumps, packaged terminal air

169

The smart thermostat: using occupancy sensors to save energy in homes  

Science Conference Proceedings (OSTI)

Heating, ventilation and cooling (HVAC) is the largest source of residential energy consumption. In this paper, we demonstrate how to use cheap and simple sensing technology to automatically sense occupancy and sleep patterns in a home, and how to use ... Keywords: building energy, home monitoring, programmable thermostats, wireless sensor networks

Jiakang Lu; Tamim Sookoor; Vijay Srinivasan; Ge Gao; Brian Holben; John Stankovic; Eric Field; Kamin Whitehouse

2010-11-01T23:59:59.000Z

170

Measure Guideline: Ventilation Cooling  

SciTech Connect

The purpose of this measure guideline on ventilation cooling is to provide information on a cost-effective solution for reducing cooling system energy and demand in homes located in hot-dry and cold-dry climates. This guideline provides a prescriptive approach that outlines qualification criteria, selection considerations, and design and installation procedures.

Springer, D.; Dakin, B.; German, A.

2012-04-01T23:59:59.000Z

171

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

2 2 Residential Furnace Efficiencies (Percent of Units Shipped) (1) AFUE Range 1985 AFUE Range 2006 AFUE Range 1985 Below 65% 15% 75% to 88% 64% Below 75% 10% 65% to 71% 44% 88% or More 36% 75% to 80% 56% 71% to 80% 10% Total 100% More Than 80% 35% 80% to 86% 19% Total 100% More than 86% 12% Total 100% Average shipped in 1985 (2): 74% AFUE Average shipped in 1985 (2): 79% AFUE Average shipped in 1995: 84% AFUE Average shipped in 1995: 81% AFUE Best Available in 1981: 85% AFUE Best Available in 1981: 85% AFUE Best Available in 2007: 97% AFUE Best Available in 2007: 95% AFUE Note(s): Source(s): Gas-Fired Oil-Fired 1) Federal appliance standards effective Jan. 1, 1992, require a minimum of 78% AFUE for furnaces. 3) Includes boilers. GAMA's Internet Home Page for 2006 AFUE ranges; GAMA News, Feb. 24, 1987, for 1985 AFUE ranges; LBNL for average shipped AFUE; GAMA,

172

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

5 5 Commercial Equipment Efficiencies Equipment Type Chiller Screw COP(full-load / IPLV) 2.80 / 3.05 2.80 / 3.05 3.02 / 4.45 Scroll COP 2.80 / 3.06 2.96 / 4.40 N.A. Reciprocating COP(full-load / IPLV) 2.80 / 3.05 2.80 / 3.05 3.52 / 4.40 Centrifugal COP(full-load / IPLV) 5.0 / 5.2 6.1 / 6.4 7.3 / 9.0 Gas-Fired Absorption COP 1.0 1.1 N.A. Gas-Fired Engine Driven COP 1.5 1.8 N.A. Rooftop A/C EER 10.1 11.2 13.9 Rooftop Heat Pump EER (cooling) 9.8 11.0 12.0 COP (heating) 3.2 3.3 3.4 Boilers Gas-Fired Combustion Efficiency 77 80 98 Oil-Fired Thermal Efficiency 80 84 98 Electric Thermal Efficiency 98 98 98 Furnace AFUE 77 80 82 Water Heater Gas-Fired Thermal Efficiency 78 80 96 Oil-Fired Thermal Efficiency 79 80 85 Electric Resistance Thermal Efficiency 98 98 98 Gas-Fired Instantaneous Thermal Efficiency 77 84 89 Source(s): Parameter Efficiency

173

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

1 1 Main Residential Heating Equipment as of 1987, 1993, 1997, 2001, and 2005 (Percent of Total Households) Equipment Type 1987 1993 1997 2001 2005 Natural Gas 55% 53% 53% 55% 52% Central Warm-Air Furnace 35% 36% 38% 42% 40% Steam or Hot-Water System 10% 9% 7% 7% 7% Floor/Wall/Pipeless Furnace 6% 4% 4% 3% 2% Room Heater/Other 4% 3% 4% 3% 3% Electricity 20% 26% 29% 29% 30% Central Warm-Air Furnace 8% 10% 11% 12% 14% Heat Pump 5% 8% 10% 10% 8% Built-In Electric Units 6% 7% 7% 6% 5% Other 1% 1% 2% 2% 1% Fuel Oil 12% 11% 9% 7% 7% Steam or Hot-Water System 7% 6% 5% 4% 4% Central Warm-Air Furnace 4% 5% 4% 3% 3% Other 1% 0% 0% 0% 0% Other 13% 11% 9% 8% 10% Total 100% 100% 100% 100% 100% Note(s): Source(s): Other equipment includes wood, LPG, kerosene, other fuels, and none. EIA, A Look at Residential Consumption in 2005, June 2008, Table HC2-4; EIA, A Look at Residential Energy Consumption in 2001, Apr. 2004, 'Table HC3-

174

State Home Oil Weatherization (SHOW) Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Oil Weatherization (SHOW) Program Home Oil Weatherization (SHOW) Program State Home Oil Weatherization (SHOW) Program < Back Eligibility Multi-Family Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Maximum Rebate $500/household Program Info State Oregon Program Type State Rebate Program Rebate Amount Blower-door test - 100% of the cost up to $100. All other technologies are 25% of the total cost, up to $150 or $500, depending on the upgrade. Provider Oregon Department of Energy Oregon homeowners and renters who heat with oil, wood, propane, kerosene, or butane are eligible for home weatherization rebates of up to $500. A

175

Ventilative cooling  

E-Print Network (OSTI)

This thesis evaluates the performance of daytime and nighttime passive ventilation cooling strategies for Beijing, Shanghai and Tokyo. A new simulation method for cross-ventilated wind driven airflow is presented . This ...

Graa, Guilherme Carrilho da, 1972-

1999-01-01T23:59:59.000Z

176

Ventilation Systems  

Energy.gov (U.S. Department of Energy (DOE))

Ventilation is the process of moving air into and out of an interior space by natural or mechanical means. Ventilation is necessary for the health and comfort of occupants of all buildings....

177

Proposal for the award of a contract for the design, supply, installation and commissioning of a Heating, Ventilation and Air-Conditioning (HVAC) system for the computer room of the CERN Control Centre  

E-Print Network (OSTI)

Proposal for the award of a contract for the design, supply, installation and commissioning of a Heating, Ventilation and Air-Conditioning (HVAC) system for the computer room of the CERN Control Centre

2012-01-01T23:59:59.000Z

178

Proposal for the award of a contract for the design, supply, installation and commissioning of a Heating Ventilation and Air Conditioning (HVAC) system for the HIE-ISOLDE infrastructure  

E-Print Network (OSTI)

Proposal for the award of a contract for the design, supply, installation and commissioning of a Heating Ventilation and Air Conditioning (HVAC) system for the HIE-ISOLDE infrastructure

2012-01-01T23:59:59.000Z

179

Meeting Residential Ventilation Standards Through Dynamic Control of Ventilation Systems  

SciTech Connect

Existing ventilation standards, including American Society of Heating, Refrigerating, and Air-conditioning Engineers (ASHRAE) Standard 62.2, specify continuous operation of a defined mechanical ventilation system to provide minimum ventilation, with time-based intermittent operation as an option. This requirement ignores several factors and concerns including: other equipment such as household exhaust fans that might incidentally provide ventilation, negative impacts of ventilation when outdoor pollutant levels are high, the importance of minimizing energy use particularly during times of peak electricity demand, and how the energy used to condition air as part of ventilation system operation changes with outdoor conditions. Dynamic control of ventilation systems can provide ventilation equivalent to or better than what is required by standards while minimizing energy costs and can also add value by shifting load during peak times and reducing intake of outdoor air contaminants. This article describes the logic that enables dynamic control of whole-house ventilation systems to meet the intent of ventilation standards and demonstrates the dynamic ventilation system control concept through simulations and field tests of the Residential Integrated Ventilation-Energy Controller (RIVEC).

Sherman, Max H.; Walker, Iain S.

2011-04-01T23:59:59.000Z

180

Demonstration of Demand Control Ventilation Technology  

Science Conference Proceedings (OSTI)

Demand Control Ventilation (DCV) is one of the control strategies that can be used modulate the amount of ventilation air for space conditioning in commercial buildings. DCV modulates the amount of ventilation air introduced into the heating, ventilation and air conditioning (HVAC) system based on carbon dioxide levels sensed in the areas served. The carbon dioxide level is a proxy for the number of people within the space, from which the required quantity of ventilation air is determined. By using this ...

2011-12-30T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


181

Buildings Energy Data Book: 5.3 Heating, Cooling, and Ventilation Equipment  

Buildings Energy Data Book (EERE)

8 8 Major Residential HVAC Equipment Lifetimes, Ages, and Replacement Picture Equipment Type Central Air Conditioners 8 - 14 11 8 5,354 Heat Pumps 9 - 15 12 8 1,260 Furnaces Electric 10 - 20 15 11 N.A. Gas-Fired 12 - 17 15 11 2,601 Oil-Fired 15 - 19 17 N.A. 149 Gas-Fired Boilers (1) 17 - 24 20 17 204 Note(s): Source(s): Lifetimes based on use by the first owner of the product, and do not necessarily indicate that the product stops working after this period. A replaced unit may be discarded or used elsewhere. 1) 2005 average stock age is for gas- and oil-fired steam and hot water boilers. Appliance Magazine, U.S. Appliance Industry: Market Share, Life Expectancy & Replacement Market, and Saturation Levels, January 2010, p. 10 for service and average lifetimes, and units to be replaced; ASHRAE, 1999 ASHRAE Handbook: HVAC Applications, Table 3, p. 35.3 for boilers service lifetimes; and

182

Home Performance with Energy Star | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Performance with Energy Star Home Performance with Energy Star Home Performance with Energy Star < Back Eligibility Low-Income Residential Multi-Family Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Other Sealing Your Home Ventilation Heat Pumps Appliances & Electronics Water Heating Program Info Funding Source Focus On Energy Program State Wisconsin Program Type State Rebate Program Rebate Amount Air Sealing, Attic Insulation, Exterior Wall Insulation, Sill Box Insulation, Interior Foundation Insulation: 33.3% of improvement costs up to $1,500 Bonus for 15% Energy Savings: $200 Bonus for 25% Energy Savings: $700 Free installation of CFLs, faucet aerators, shower heads, and pipe wraps

183

Cascade Natural Gas - Conservation Incentives for Existing Homes |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Existing Homes Existing Homes Cascade Natural Gas - Conservation Incentives for Existing Homes < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Heating & Cooling Commercial Heating & Cooling Heating Appliances & Electronics Water Heating Program Info State District of Columbia Program Type Utility Rebate Program Rebate Amount Floor Insulation: $0.45 per sq. ft. Wall Insulation: $0.40 per sq. ft. Ceiling or Attic Insulation: $0.25 per sq. ft. High Efficiency Natural Gas Furnace: $150 Duct Sealing: $150 High Efficiency Natural Gas Furnace and Duct Sealing: $400 High Efficiency Natural Gas Hearth: $70 Conventional Natural Gas Water Heater: $40 Combination Domestic Water/Hydronic Space Heating System (using Tankless

184

Home Performance with Energy Star Financing | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Performance with Energy Star Financing Home Performance with Energy Star Financing Home Performance with Energy Star Financing < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Appliances & Electronics Other Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Heat Pumps Commercial Lighting Lighting Water Heating Bioenergy Solar Program Info Funding Source Energy Efficiency Portfolio Standard (EEPS)/Regional Greenhouse Gas Initiative (RGGI) State New York Program Type State Loan Program Rebate Amount Up to 100% of costs; loans from $3,000 - $25,000 (minimum loan of $1,500 for income qualified customers); loan limit is $13,000 for projects with a

185

Fort Collins Utilities - Home Efficiency Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Efficiency Program Home Efficiency Program Fort Collins Utilities - Home Efficiency Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Sealing Your Home Ventilation Heat Pumps Appliances & Electronics Commercial Lighting Lighting Manufacturing Water Heating Windows, Doors, & Skylights Program Info State Colorado Program Type Utility Rebate Program Rebate Amount Lighting: See Program Website Air Sealing: $200 - $500 Conditioned Crawl Space Insulation: $0.30/sq ft. - $0.75/sq ft. Cold Crawl Space: $0.30/sq ft. - $0.45/sq ft. Basement Wall Insulation:$0.50/sq ft. - $1.00/sq ft., Cantilever Floor Insulation: $0.50/sq ft. - $0.75/sq ft. Frame Floor Insulation Over Garage: $0.50/sq ft. - $0.75/sq ft.

186

In-Depth Look at Ground Source Heat Pumps and Other Electric Loads in Two GreenMax Homes  

DOE Green Energy (OSTI)

CARB partnered with WPPI Energy to answer key research questions on in-field performance of ground-source heat pumps and LAMELs through extensive field monitoring at two WPPI GreenMax demonstration homes in Wisconsin. These two test home evaluations provided valuable data on the true in-field performance of various building mechanical systems and lighting, appliances, and miscellaneous loads (LAMELs).

Puttagunta, S.; Shapiro, C.

2012-04-01T23:59:59.000Z

187

International Energy Agency Building Energy Simulation Test and Diagnostic Method for Heating, Ventilating, and Air-Conditioning Equipment Models (HVAC BESTEST); Volume 1: Cases E100-E200  

DOE Green Energy (OSTI)

This report describes the Building Energy Simulation Test for Heating, Ventilating, and Air-Conditioning Equipment Models (HVAC BESTEST) project conducted by the Tool Evaluation and Improvement International Energy Agency (IEA) Experts Group. The group was composed of experts from the Solar Heating and Cooling (SHC) Programme, Task 22, Subtask A. The current test cases, E100-E200, represent the beginning of work on mechanical equipment test cases; additional cases that would expand the current test suite have been proposed for future development.

Neymark, J.; Judkoff, R.

2002-01-01T23:59:59.000Z

188

NREL evaluates energy savings potential of heat pump water heaters in homes throughout all U.S. climate zones.  

E-Print Network (OSTI)

in homes compared to traditional electric resistance water heaters. Researchers at the National Renewable is a function of surrounding air temperature, humidity, hot water usage, and the logic controlling the heat pump

189

Demonstration and Performance Monitoring of Foundation Heat Exchangers in Low Load, High Performance Research Homes  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Demonstration and Performance Monitoring of Foundation Heat Exchangers (FHX) in Low Load, High Performance Research Homes Piljae Im, Ph.D. Oak Ridge National Laboratory Building America Technical Update Meeting April 29 - 30, Denver, Colorado ACKNOWLEDGEMENT * This project was sponsored by the Building Technologies Office of the U.S. Department of Energy's Office of Energy Efficiency and Renewable Energy and the Tennessee Valley Authority (TVA). Managed by UT-Battelle for the U.S. Department of Energy 2 PRESENTATION OVERVIEW * INTRODUCTION * FIELD TEST OF THE FOUNDATION HEAT EXCHANGER (FHX) CONCEPT * FOUNDATION HEAT EXCHANGER PERFORMANCE MEASUREMENTS * ADDITIONAL FINDINGS AND COST COMPARISON * SUMMARY Managed by UT-Battelle for the U.S. Department of Energy

190

System manual for the University of Pennsylvania retrofitted solar heated Philadelphia row home (SolaRow)  

DOE Green Energy (OSTI)

The University of Pennsylvania SolaRow house, an urban row home retrofitted for comfort and domestic hot water heating, was extensively instrumented for performance monitoring and acquisition of weather and solar radiation data. This report describes the heating and instrumentation systems, provides the details for instrumentation, piping and valve identification, and specifies the operation and maintenance of the heating and data acquisition systems. The following are included: (1) system flow diagrams; (2) valve and cable identification tables; (3) wiring diagrams; and (4) start-up, normal operation, shut-down, maintenance and trouble-shooting procedures. It thus provides the necessary technical information to permit system operation and monitoring, overall system performance analysis and optimization, and acquisition of climatological data.

Zinnes, I.; Lior, N.

1980-05-01T23:59:59.000Z

191

Design Approach and Performance Analysis of a Small Integrated Heat Pump (IHP) for Net Zero Energy Homes (ZEH)  

SciTech Connect

This paper describes the design and performance analysis of a variable-capacity heat pump system developed for a small [1800ft2 (167 m2)] prototype net ZEH with an average design cooling load of 1.25 tons (4.4 kW) in five selected US climates. The heat pump integrates space heating and cooling, water heating, ventilation, and humidity control (humidification and dehumidification) functions into a single integrated heat pump (IHP) unit. The design approach uses one small variable-capacity compressor to meet all the above functions in an energy efficient manner. Modal performance comparisons to an earlier IHP product are shown relative to the proposed new design for net ZEH application. The annual performance analysis approach using TRNSYS in conjunction with the ORNL Heat Pump Design Model is discussed. Annual performance projections for a range of locations are compared to those of a base system consisting of separate pieces of equipment to perform the same functions. The ZEH IHP is projected to reduce energy use for space heating & cooling, water heating, dehumidification, and ventilation for a net ZEH by about 50% compared to that of the base system.

Rice, C Keith [ORNL; Murphy, Richard W [ORNL; Baxter, Van D [ORNL

2008-01-01T23:59:59.000Z

192

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Cleanup Project Cleanup Project Search Login Home News News Inside the ICP articles About Us About Us Our Mission Facility Factsheets History of the Site Safety Working with CWI/Property Sales Working with CWI Subcontracting & Small Business Academic Internship Program Property Sales Outreach Community Outreach Stakeholders Education and Research Transfer Program AR-IR Administration Contact Us Industry leader in safe performance CWI's worker-owned safety culture has been the cornerstone for delivering work at the Idaho Cleanup Project. Since contract inception in May 2005, the CWI team has reduced recordable injuries by more than 70 percent. Video Feature: Waste Management Treatment of sodium-contaminated waste using a distillation process (9:47) Terms Of Use Privacy Statement If you have a disability and need an

193

TVA Partner Utilities - In-Home Energy Evaluation Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Program Program TVA Partner Utilities - In-Home Energy Evaluation Program < Back Eligibility Installer/Contractor Residential Utility Savings Category Home Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Commercial Weatherization Ventilation Manufacturing Heat Pumps Windows, Doors, & Skylights Maximum Rebate 50% cost up to $500 Program Info State Virginia Program Type Utility Rebate Program Rebate Amount Windows: $500 Duct Repair, Replacement, and Sealing: $500 Minor Repair Work: $250 Replace HVAC: $250 Insulation: $500 Electric Water Heater and Pipe Insulation: $50 Air Sealing/Weatherstrip/Caulk: $500 Central HVAC Tune-up: $150 Provider Tennessee Valley Authority The Tennessee Valley Authority (TVA) energy right In-Home Energy Evaluation

194

Flexible Residential Test Facility: Impact of Infiltration and Ventilation on Measured Heating Season Energy and Moisture Levels  

SciTech Connect

Two identical laboratory homes designed to model existing Florida building stock were sealed and tested to 2.5 ACH50. Then, one was made leaky with 70% leakage through the attic and 30% through windows, to a tested value of 9 ACH50. Reduced energy use was measured in the tighter home (2.5 ACH50) in the range of 15% to 16.5% relative to the leaky (9 ACH50) home. Internal moisture loads resulted in higher dew points inside the tight home than the leaky home. Window condensation and mold growth occurred inside the tight home. Even cutting internal moisture gains in half to 6.05 lbs/day, the dew point of the tight home was more than 15 degrees F higher than the outside dry bulb temperature. The homes have single pane glass representative of older Central Florida homes.

Vieira, R.; Parker, D.; Fairey, P.; Sherwin, J.; Withers, C.; Hoak, D.

2013-09-01T23:59:59.000Z

195

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or the information, products or services contained therein by the DOE Oak Ridge Office. Home Home Contact Infomation Background Reference Documents Pre-Solicitation Notice Final...

196

Impacts of Mixing on Acceptable Indoor Air Quality in Homes  

NLE Websites -- All DOE Office Websites (Extended Search)

Impacts of Mixing on Acceptable Indoor Air Quality in Homes Impacts of Mixing on Acceptable Indoor Air Quality in Homes Title Impacts of Mixing on Acceptable Indoor Air Quality in Homes Publication Type Journal Article LBNL Report Number LBNL-3048E Year of Publication 2010 Authors Sherman, Max H., and Iain S. Walker Journal HVAC & Research Journal Keywords air distribution, indoor air quality, mechanical ventilation, mixing, other, resave, residential ventilation, ventilation effectiveness Abstract Ventilation reduces occupant exposure to indoor contaminants by diluting or removing them. In a multi-zone environment such as a house, every zone will have different dilution rates and contaminant source strengths. The total ventilation rate is the most important factor in determining occupant exposure to given contaminant sources, but the zone-specific distribution of exhaust and supply air and the mixing of ventilation air can play significant roles. Different types of ventilation systems will provide different amounts of mixing depending on several factors such as air leakage, air distribution system, and contaminant source and occupant locations. Most U.S. and Canadian homes have central heating, ventilation, and air conditioning systems, which tend to mix the air; thus, the indoor air in different zones tends to be well mixed for significant fractions of the year. This article reports recent results of investigations to determine the impact of air mixing on exposures of residential occupants to prototypical contaminants of concern. We summarize existing literature and extend past analyses to determine the parameters than affect air mixing as well as the impacts of mixing on occupant exposure, and to draw conclusions that are relevant for standards development and for practitioners designing and installing home ventilation systems. The primary conclusion is that mixing will not substantially affect the mean indoor air quality across a broad population of occupants, homes, and ventilation systems, but it can reduce the number of occupants who are exposed to extreme pollutant levels. If the policy objective is to minimize the number of people exposed above a given pollutant threshold, some amount of mixing will be of net benefit even though it does not benefit average exposure. If the policy is to minimize exposure on average, then mixing air in homes is detrimental and should not be encouraged. We also conclude that most homes in the US have adequate mixing already, but that new, high-performance homes may require additional mixing. Also our results suggest that some differentiation should be made in policies and standards for systems that provide continuous exhaust, thereby reducing relative dose for occupants overall

197

Columbia Gas of Ohio - Home Performance Solutions Loan Program | Department  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Columbia Gas of Ohio - Home Performance Solutions Loan Program Columbia Gas of Ohio - Home Performance Solutions Loan Program Columbia Gas of Ohio - Home Performance Solutions Loan Program < Back Eligibility Installer/Contractor Low-Income Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Program Info State Ohio Program Type Utility Loan Program Rebate Amount Amount remaining after Home Performance Solution Program Rebates Provider Columbia Gas of Ohio Columbia Gas of Ohio (CGO) partners with Huntington National Bank's Energy Performance Solutions program to offer a loan complementing rebates for energy efficient equipment to residential customers. Rebates may be available if a customer purchases or installs measures recommended by an

198

Ventilation System Basics | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation System Basics Ventilation System Basics Ventilation System Basics August 16, 2013 - 1:33pm Addthis Ventilation is the process of moving air into and out of an interior space by natural or mechanical means. Ventilation is necessary for the health and comfort of occupants of all buildings. Ventilation supplies air for occupants to breathe and removes moisture, odors, and indoor pollutants like carbon dioxide. Too little ventilation may result in poor indoor air quality, while too much may cause unnecessarily higher heating and cooling loads. Natural Ventilation Natural ventilation occurs when outdoor air is drawn inside through open windows or doors. Natural ventilation is created by the differences in the distribution of air pressures around a building. Air moves from areas of

199

Ventilation System Basics | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation System Basics Ventilation System Basics Ventilation System Basics August 16, 2013 - 1:33pm Addthis Ventilation is the process of moving air into and out of an interior space by natural or mechanical means. Ventilation is necessary for the health and comfort of occupants of all buildings. Ventilation supplies air for occupants to breathe and removes moisture, odors, and indoor pollutants like carbon dioxide. Too little ventilation may result in poor indoor air quality, while too much may cause unnecessarily higher heating and cooling loads. Natural Ventilation Natural ventilation occurs when outdoor air is drawn inside through open windows or doors. Natural ventilation is created by the differences in the distribution of air pressures around a building. Air moves from areas of

200

Equivalence in Ventilation and Indoor Air Quality  

SciTech Connect

We ventilate buildings to provide acceptable indoor air quality (IAQ). Ventilation standards (such as American Society of Heating, Refrigerating, and Air-Conditioning Enginners [ASHRAE] Standard 62) specify minimum ventilation rates without taking into account the impact of those rates on IAQ. Innovative ventilation management is often a desirable element of reducing energy consumption or improving IAQ or comfort. Variable ventilation is one innovative strategy. To use variable ventilation in a way that meets standards, it is necessary to have a method for determining equivalence in terms of either ventilation or indoor air quality. This study develops methods to calculate either equivalent ventilation or equivalent IAQ. We demonstrate that equivalent ventilation can be used as the basis for dynamic ventilation control, reducing peak load and infiltration of outdoor contaminants. We also show that equivalent IAQ could allow some contaminants to exceed current standards if other contaminants are more stringently controlled.

Sherman, Max; Walker, Iain; Logue, Jennifer

2011-08-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


201

Alabama Power - Residential Heat Pump and Weatherization Loan Programs |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Alabama Power - Residential Heat Pump and Weatherization Loan Alabama Power - Residential Heat Pump and Weatherization Loan Programs Alabama Power - Residential Heat Pump and Weatherization Loan Programs < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Heating & Cooling Commercial Heating & Cooling Heat Pumps Appliances & Electronics Water Heating Maximum Rebate Windows: $350 Program Info State Alabama Program Type Utility Loan Program Rebate Amount Not specified Provider Alabama Power Alabama Power offers low-interest loans to residential customers to purchase and install new heat pumps and a variety of weatherization measures. The loans require no money down and can be used to finance an air

202

Xcel Energy - Residential and Low Income Home Energy Service | Department  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Xcel Energy - Residential and Low Income Home Energy Service Xcel Energy - Residential and Low Income Home Energy Service Xcel Energy - Residential and Low Income Home Energy Service < Back Eligibility Installer/Contractor Low-Income Residential Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Other Sealing Your Home Ventilation Heat Pumps Appliances & Electronics Commercial Lighting Lighting Water Heating Windows, Doors, & Skylights Program Info Start Date 1/1/2011 Expiration Date 12/31/2012 State New Mexico Program Type Utility Rebate Program Rebate Amount Evaporative Cooling: $200-$1000/unit Saver's Switch A/C Cycling: $20/ton of enrolled air conditioning Refrigerator Recycling: $75 CFLs: $1/bulb LED's: $10/bulb

203

Ventilation Systems | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

is important in understanding cooling strategies for homes and buildings. Principles of Heat Transfer Heat is transferred to and from objects via three processes: conduction,...

204

Infiltration Effects on Residential Pollutant Concentrations for Continuous and Intermittent Mechanical Ventilation Approaches  

SciTech Connect

The prevailing residential ventilation standard in North America, American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) Standard 62.2, specifies volumetric airflow requirements as a function of the overall size of the home and the number of bedrooms, assumes a fixed, minimal amount of infiltration, and requires mechanical ventilation to achieve the remainder. The standard allows for infiltration credits and intermittent ventilation patterns that can be shown to provide comparable performance. Whole-house ventilation methods have a substantial effect on time-varying indoor pollutant concentrations. If alternatives specified by Standard 62.2, such as intermittent ventilation, are used, short-term pollutant concentrations could exceed acute health standards even if chronic health standards are met.The authors present a methodology for comparing ASHRAE- and non-ASHRAE-specified ventilation scenarios on relative indoor pollutant concentrations. We use numerical modeling to compare the maximum time-averaged concentrations for acute exposure relevant (1-hour, 8-hour, 24-hour ) and chronic exposure relevant (1-year) time periods for four different ventilation scenarios in six climates with a range of normalized leakage values. The results suggest that long-term concentrations are the most important metric for assessing the effectiveness of whole-house ventilation systems in meeting exposure standards and that, if chronic health exposure standards are met, acute standards will also be met.

Sherman, Max; Logue, Jennifer; Singer, Brett

2010-06-01T23:59:59.000Z

205

Transpired Air Collectors - Ventilation Preheating  

DOE Green Energy (OSTI)

Many commercial and industrial buildings have high ventilation rates. Although all that fresh air is great for indoor air quality, heating it can be very expensive. This short (2-page) fact sheet describes a technology available to use solar energy to preheat ventilation air and dramatically reduce utility bills.

Christensen, C.

2006-06-22T23:59:59.000Z

206

Initial Business Case Analysis of Two Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes -- Update to Include Analyses of an Economizer Option and Alternative Winter Water Heating Control Option  

Science Conference Proceedings (OSTI)

The long range strategic goal of the Department of Energy's Building Technologies (DOE/BT) Program is to create, by 2020, technologies and design approaches that enable the construction of net-zero energy homes at low incremental cost (DOE/BT 2005). A net zero energy home (NZEH) is a residential building with greatly reduced needs for energy through efficiency gains, with the balance of energy needs supplied by renewable technologies. While initially focused on new construction, these technologies and design approaches are intended to have application to buildings constructed before 2020 as well resulting in substantial reduction in energy use for all building types and ages. DOE/BT's Emerging Technologies (ET) team is working to support this strategic goal by identifying and developing advanced heating, ventilating, air-conditioning, and water heating (HVAC/WH) technology options applicable to NZEHs. Although the energy efficiency of heating, ventilating, and air-conditioning (HVAC) equipment has increased substantially in recent years, new approaches are needed to continue this trend. Dramatic efficiency improvements are necessary to enable progress toward the NZEH goals, and will require a radical rethinking of opportunities to improve system performance. The large reductions in HVAC energy consumption necessary to support the NZEH goals require a systems-oriented analysis approach that characterizes each element of energy consumption, identifies alternatives, and determines the most cost-effective combination of options. In particular, HVAC equipment must be developed that addresses the range of special needs of NZEH applications in the areas of reduced HVAC and water heating energy use, humidity control, ventilation, uniform comfort, and ease of zoning. In FY05 ORNL conducted an initial Stage 1 (Applied Research) scoping assessment of HVAC/WH systems options for future NZEHs to help DOE/BT identify and prioritize alternative approaches for further development. Eleven system concepts with central air distribution ducting and nine multi-zone systems were selected and their annual and peak demand performance estimated for five locations: Atlanta (mixed-humid), Houston (hot-humid), Phoenix (hot-dry), San Francisco (marine), and Chicago (cold). Performance was estimated by simulating the systems using the TRNSYS simulation engine (Solar Energy Laboratory et al. 2006) in two 1800-ft{sup 2} houses--a Building America (BA) benchmark house and a prototype NZEH taken from BEopt results at the take-off (or crossover) point (i.e., a house incorporating those design features such that further progress towards ZEH is through the addition of photovoltaic power sources, as determined by current BEopt analyses conducted by NREL). Results were summarized in a project report, HVAC Equipment Design options for Near-Zero-Energy Homes--A Stage 2 Scoping Assessment, ORNL/TM-2005/194 (Baxter 2005). The 2005 study report describes the HVAC options considered, the ranking criteria used, and the system rankings by priority. In 2006, the two top-ranked options from the 2005 study, air-source and ground-source versions of an integrated heat pump (IHP) system, were subjected to an initial business case study. The IHPs were subjected to a more rigorous hourly-based assessment of their performance potential compared to a baseline suite of equipment of legally minimum efficiency that provided the same heating, cooling, water heating, demand dehumidification, and ventilation services as the IHPs. Results were summarized in a project report, Initial Business Case Analysis of Two Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes, ORNL/TM-2006/130 (Baxter 2006). The present report is an update to that document. Its primary purpose is to summarize results of an analysis of the potential of adding an outdoor air economizer operating mode to the IHPs to take advantage of free cooling (using outdoor air to cool the house) whenever possible. In addition it provides some additional detail for an alternative winter water heating/space heating (WH/S

Baxter, Van D [ORNL

2006-12-01T23:59:59.000Z

207

US Department of Energys Regulatory Negotiations Convening on Commercial Certification for Heating, Ventilating, Air-Conditioning, and Refrigeration Equipment  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

US Department of Energy's Regulatory Negotiations Convening on US Department of Energy's Regulatory Negotiations Convening on Commercial Certification for Heating, Ventilating, Air-Conditioning, and Refrigeration Equipment Public Information for Convening Interviews I. What are the substantive issues DOE seeks to address? Strategies for grouping various basic models for purposes of certification; Identification of non-efficiency attributes, which do not impact the measured consumption of the equipment as tested by DOE's test procedure; The information that is certified to the Department; The timing of when the certification should be made relative to distribution in commerce; and Alterations to a basic model that would impact the certification.

208

ASHRAE and residential ventilation  

SciTech Connect

In the last quarter of a century, the western world has become increasingly aware of environmental threats to health and safety. During this period, people psychologically retreated away from outdoors hazards such as pesticides, smog, lead, oil spills, and dioxin to the seeming security of their homes. However, the indoor environment may not be healthier than the outdoor environment, as has become more apparent over the past few years with issues such as mold, formaldehyde, and sick-building syndrome. While the built human environment has changed substantially over the past 10,000 years, human biology has not; poor indoor air quality creates health risks and can be uncomfortable. The human race has found, over time, that it is essential to manage the indoor environments of their homes. ASHRAE has long been in the business of ventilation, but most of the focus of that effort has been in the area of commercial and institutional buildings. Residential ventilation was traditionally not a major concern because it was felt that, between operable windows and envelope leakage, people were getting enough outside air in their homes. In the quarter of a century since the first oil shock, houses have gotten much more energy efficient. At the same time, the kinds of materials and functions in houses changed in character in response to people's needs. People became more environmentally conscious and aware not only about the resources they were consuming but about the environment in which they lived. All of these factors contributed to an increasing level of public concern about residential indoor air quality and ventilation. Where once there was an easy feeling about the residential indoor environment, there is now a desire to define levels of acceptability and performance. Many institutions--both public and private--have interests in Indoor Air Quality (IAQ), but ASHRAE, as the professional society that has had ventilation as part of its mission for over 100 years, is the logical place to provide leadership. This leadership has been demonstrated most recently by the publication of the first nationally recognized standard on ventilation in homes, ASHRAE Standard 62.2-2003, which builds on work that has been part of ASHRAE for many years and will presumably continue. Homeowners and occupants, which includes virtually all of us, will benefit from the application of Standard 62.2 and use of the top ten list. This activity is exactly the kind of benefit to society that the founders of ASHRAE envisioned and is consistent with ASHRAE's mission and vision. ASHRAE members should be proud of their Society for taking leadership in residential ventilation.

Sherman, Max H.

2003-10-01T23:59:59.000Z

209

AlabamaWISE Home Energy Program (Alabama) | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

AlabamaWISE Home Energy Program (Alabama) AlabamaWISE Home Energy Program (Alabama) AlabamaWISE Home Energy Program (Alabama) < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Construction Commercial Heating & Cooling Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Maximum Rebate $750 Program Info Funding Source The American Reinvestment and Recovery Act (ARRA) of 2009; Alabama Department of Economic and Community Affairs Start Date 01/01/2010 State Alabama Program Type Local Rebate Program The WISE Home Energy Program provides up to $750 in energy efficiency rebates for homeowners in Cullman, Madison, Jefferson, Shelby, Morgan, Limestone and Lawrence counties. A $350 rebate is available to homeowners

210

Measure Guideline: Heat Pump Water Heaters in New and Existing Homes  

Science Conference Proceedings (OSTI)

This Building America Measure Guideline is intended for builders, contractors, homeowners, and policy-makers. This document is intended to explore the issues surrounding heat pump water heaters (HPWHs) to ensure that homeowners and contractors have the tools needed to appropriately and efficiently install HPWHs. Heat pump water heaters (HPWHs) promise to significantly reduce energy consumption for domestic hot water (DHW) over standard electric resistance water heaters (ERWHs). While ERWHs perform with energy factors (EFs) around 0.9, new HPWHs boast EFs upwards of 2.0. High energy factors in HPWHs are achieved by combining a vapor compression system, which extracts heat from the surrounding air at high efficiencies, with electric resistance element(s), which are better suited to meet large hot water demands. Swapping ERWHs with HPWHs could result in roughly 50% reduction in water heating energy consumption for 35.6% of all U.S. households. This Building America Measure Guideline is intended for builders, contractors, homeowners, and policy-makers. While HPWHs promise to significantly reduce energy use for DHW, proper installation, selection, and maintenance of HPWHs is required to ensure high operating efficiency and reliability. This document is intended to explore the issues surrounding HPWHs to ensure that homeowners and contractors have the tools needed to appropriately and efficiently install HPWHs. Section 1 of this guideline provides a brief description of HPWHs and their operation. Section 2 highlights the cost and energy savings of HPWHs as well as the variables that affect HPWH performance, reliability, and efficiency. Section 3 gives guidelines for proper installation and maintenance of HPWHs, selection criteria for locating HPWHs, and highlights of important differences between ERWH and HPWH installations. Throughout this document, CARB has included results from the evaluation of 14 heat pump water heaters (including three recently released HPWH products) installed in existing homes in the northeast region of the United States.

Shapiro, C.; Puttagunta, S.; Owens, D.

2012-02-01T23:59:59.000Z

211

Coal home heating and environmental tobacco smoke in relation to lower respiratory illness in Czech children, from birth to 3 years of age  

E-Print Network (OSTI)

in the Czech setting, where coal is still com- monly used inwe found exposure to coal home heating and ETS increasewell studied, residential coal combustion in economically

2006-01-01T23:59:59.000Z

212

Columbia Gas of Ohio - Home Performance Solutions Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Columbia Gas of Ohio - Home Performance Solutions Program Columbia Gas of Ohio - Home Performance Solutions Program Columbia Gas of Ohio - Home Performance Solutions Program < Back Eligibility Installer/Contractor Low-Income Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Maximum Rebate 70% Program Info State Ohio Program Type Utility Rebate Program Rebate Amount Energy Audit: $50 cost Attic Insulation: $0.30-$0.50/sq. ft. Wall Insulation: $0.40/sq. ft. Air sealing: $40/air sealing hour Furnace: $200 Boiler: $200 Bonus Incentives: Varies by equipment-type Provider Columbia Gas of Ohio Columbia Gas of Ohio (CGO) offers a number of rebates on energy efficient equipment and measures to residential customers. Rebates may be available

213

Air Distribution Effectiveness for Residential Mechanical Ventilation: Simulation and Comparison of Normalized Exposures  

SciTech Connect

The purpose of ventilation is to dilute indoor contaminants that an occupant is exposed to. Even when providing the same nominal rate of outdoor air, different ventilation systems may distribute air in different ways, affecting occupants' exposure to household contaminants. Exposure ultimately depends on the home being considered, on source disposition and strength, on occupants' behavior, on the ventilation strategy, and on operation of forced air heating and cooling systems. In any multi-zone environment dilution rates and source strengths may be different in every zone and change in time, resulting in exposure being tied to occupancy patterns.This paper will report on simulations that compare ventilation systems by assessing their impact on exposure by examining common house geometries, contaminant generation profiles, and occupancy scenarios. These simulations take into account the unsteady, occupancy-tied aspect of ventilation such as bathroom and kitchen exhaust fans. As most US homes have central HVAC systems, the simulation results will be used to make appropriate recommendations and adjustments for distribution and mixing to residential ventilation standards such as ASHRAE Standard 62.2.This paper will report on work being done to model multizone airflow systems that are unsteady and elaborate the concept of distribution matrix. It will examine several metrics for evaluating the effect of air distribution on exposure to pollutants, based on previous work by Sherman et al. (2006).

Petithuguenin, T.D.P.; Sherman, M.H.

2009-05-01T23:59:59.000Z

214

Town of Babylon - Long Island Green Homes Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Town of Babylon - Long Island Green Homes Program Town of Babylon - Long Island Green Homes Program Town of Babylon - Long Island Green Homes Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Other Ventilation Appliances & Electronics Commercial Lighting Lighting Program Info Start Date 2008 State New York Program Type PACE Financing Provider Town of Bablyon The Long Island Green Homes Program is a self-financing residential retrofit program designed to support a goal of upgrading the energy efficiency of existing homes in the Town of Babylon. The program is a "benefit assessment" program, which allows the town to make a specific improvement that serves a public purpose on a parcel of property, and

215

Factors affecting the adoption of home-heating energy-conservation measures: a behavioral approach  

SciTech Connect

The basic aim of this research is to better understand homeowners' adoption of home-heating energy-conservation measures by analyzing a number of factors that are thought to be underlying determinants of adoption behavior. The basic approach is behavioral drawing on the knowledge built up in behavioral geography through studies on natural hazards and innovation diffusion, and borrowing from psychological theories of attitude formation and decision making. In particular, six factors (information, environmental personality, socio-economic and demographic factors, dwelling unit characteristics, psychological variables, and past experience) are shown to directly and indirectly affect adoption behavior. By this means, differences between adopters and nonadopters in the underlying cognitive structures and in the situational factors that affect their decisions are identified. The study focuses on the adoption of three measures: reducing winter night-time thermostat settings, changing or cleaning furnace filters, and installing an automatic setback thermostat. Personal interviews with a random sample of 159 homeowners in Decatur, Illinois serve as the main data base. Results indicate that adoption behavior is determined more by past experience, than by intention. Beliefs, attitudes, and social influences affect behavior indirectly through intention. These psychological variables also act as mediators between information, knowledge, environmental personality, situational variables and behavior. In particular, respondent's age, previous home ownership, and length of residence act indirectly on adoption behavior. Each of these reflects the amount of past experience the respondent is likely to have.

Macey, S.M.

1982-01-01T23:59:59.000Z

216

Market share elasticities for fuel and technology choice in home heating and cooling  

Science Conference Proceedings (OSTI)

A new technique for estimating own- and cross-elasticities of market share for fuel and technology choices in home heating and cooling is presented. We simulate changes in economic conditions and estimate elasticities by calculating predicted changes in fuel and technology market shares. Elasticities are found with respect to household income, equipment capital cost, and equipment capital cost, and equipment operating cost (including fuel price). The method is applied to a revised and extended version of a study by the Electric Power Research Institute (EPRI). Data for that study are drawn primarily from the 1975--1979 Annual Housing Surveys. Results are generally similar to previous studies, although our estimates of elasticities are somewhat lower. We feel the superior formulation of consumer choice and the currency of data in EPRI's work produce reliable estimates of market share elasticities. 18 refs., 1 fig., 6 tabs.

Wood, D.J.; Ruderman, H.; McMahon, J.E.

1989-05-01T23:59:59.000Z

217

Mississippi Power - EarthCents New Home Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Mississippi Power - EarthCents New Home Program Mississippi Power - EarthCents New Home Program Mississippi Power - EarthCents New Home Program < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Appliances & Electronics Construction Design & Remodeling Sealing Your Home Ventilation Heat Pumps Water Heating Windows, Doors, & Skylights Program Info State Mississippi Program Type Utility Rebate Program Rebate Amount Gold Level: $1,000 Silver Level: $500 Bronze Level: certification Provider Efficiency Programs Mississippi Power offers incentives to its residential customers to help offset the cost of installing energy efficient measures in new homes. A three-level program is offered to encourage the adoption of these energy

218

NREL: Learning - Solar Process Heat  

NLE Websites -- All DOE Office Websites (Extended Search)

Process Heat Process Heat Photo of part of one side of a warehouse wall, where a perforated metal exterior skin is spaced about a foot out from the main building wall to form part of the transpired solar collector system. A transpired collector is installed at a FedEx facility in Denver, Colorado. Commercial and industrial buildings may use the same solar technologies-photovoltaics, passive heating, daylighting, and water heating-that are used for residential buildings. These nonresidential buildings can also use solar energy technologies that would be impractical for a home. These technologies include ventilation air preheating, solar process heating, and solar cooling. Space Heating Many large buildings need ventilated air to maintain indoor air quality. In cold climates, heating this air can use large amounts of energy. But a

219

Heating and cooling no longer majority of U.S. home energy use ...  

U.S. Energy Information Administration (EIA)

Consumption & Efficiency. Energy use in homes, commercial buildings, manufacturing, and transportation. Coal.

220

Air-To-Water Heat Pumps with Radiant Delivery in Low Load Homes: Tucson, Arizona and Chico, California (Fact Sheet)  

SciTech Connect

Space conditioning represents nearly 50% of average residential household energy consumption, highlighting the need to identify alternative cost-effective, energy-efficient cooling and heating strategies. As homes are better built, there is an increasing need for strategies that are particularly well suited for high performance, low load homes. ARBI researchers worked with two test homes in hot-dry climates to evaluate the in-situ performance of air-to-water heat pump (AWHP) systems, an energy efficient space conditioning solution designed to cost-effectively provide comfort in homes with efficient, safe, and durable operation. Two monitoring projects of test houses in hot-dry climates were initiated in 2010 to test this system. Both systems were fully instrumented and have been monitored over one year to capture complete performance data over the cooling and heating seasons. Results are used to quantify energy savings, cost-effectiveness, and system performance using different operating modes and strategies. A calibrated TRNSYS model was developed and used to evaluate performance in various climate regions. This strategy is most effective in tight, insulated homes with high levels of thermal mass (i.e. exposed slab floors).

Not Available

2013-11-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


221

Energy Impact of Residential Ventilation Norms in the UnitedStates  

SciTech Connect

The first and only national norm for residential ventilation in the United States is Standard 62.2-2004 published by the American Society of Heating, Refrigerating and Air-conditioning Engineers (ASHRAE). This standard does not by itself have the force of regulation, but is being considered for adoption by various jurisdictions within the U.S. as well as by various voluntary programs. The adoption of 62.2 would require mechanical ventilation systems to be installed in virtually all new homes, but allows for a wide variety of design solutions. These solutions, however, may have a different energy costs and non-energy benefits. This report uses a detailed simulation model to evaluate the energy impacts of currently popular and proposed mechanical ventilation approaches that are 62.2 compliant for a variety of climates. These results separate the energy needed to ventilate from the energy needed to condition the ventilation air, from the energy needed to distribute and/or temper the ventilation air. The results show that exhaust systems are generally the most energy efficient method of meeting the proposed requirements. Balanced and supply systems have more ventilation resulting in greater energy and their associated distribution energy use can be significant.

Sherman, Max H.; Walker, Iain S.

2007-02-01T23:59:59.000Z

222

NREL evaluates energy savings potential of heat pump water heaters in homes throughout all U.S. climate zones.  

E-Print Network (OSTI)

NREL evaluates energy savings potential of heat pump water heaters in homes throughout all U.S in the U.S. market--to evaluate the cost of saved energy as a function of climate. The performance of HPWHs laboratory of the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, operated

223

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

Price Cap Cost Gas Heat Cap Cost Oil Heat Electric Share GasPrice Cap Cost Gas Heat Cap Cost Oil Heat 3. Summary of WorkEPRI [this study] Cap Cost Elec Heat Oil Price Income Gas

Wood, D.J.

2010-01-01T23:59:59.000Z

224

On The Valuation of Infiltration towards Meeting Residential Ventilation Needs  

SciTech Connect

The purpose of ventilation is dilute or remove indoor contaminants that an occupant is exposed to. It can be provided by mechanical or natural means. In most homes, especially existing homes, infiltration provides the dominant fraction of the ventilation. As we seek to provide acceptable indoor air quality at minimum energy cost, it is important to neither over-ventilate nor under-ventilate. Thus, it becomes critically important to correctly evaluate the contribution infiltration makes to both energy consumption and equivalent ventilation. ASHRAE Standards including standards 62, 119, and 136 have all considered the contribution of infiltration in various ways, using methods and data from 20 years ago.

Sherman, Max H.

2008-09-01T23:59:59.000Z

225

Ventilation Model and Analysis Report  

Science Conference Proceedings (OSTI)

This model and analysis report develops, validates, and implements a conceptual model for heat transfer in and around a ventilated emplacement drift. This conceptual model includes thermal radiation between the waste package and the drift wall, convection from the waste package and drift wall surfaces into the flowing air, and conduction in the surrounding host rock. These heat transfer processes are coupled and vary both temporally and spatially, so numerical and analytical methods are used to implement the mathematical equations which describe the conceptual model. These numerical and analytical methods predict the transient response of the system, at the drift scale, in terms of spatially varying temperatures and ventilation efficiencies. The ventilation efficiency describes the effectiveness of the ventilation process in removing radionuclide decay heat from the drift environment. An alternative conceptual model is also developed which evaluates the influence of water and water vapor mass transport on the ventilation efficiency. These effects are described using analytical methods which bound the contribution of latent heat to the system, quantify the effects of varying degrees of host rock saturation (and hence host rock thermal conductivity) on the ventilation efficiency, and evaluate the effects of vapor and enhanced vapor diffusion on the host rock thermal conductivity.

V. Chipman

2003-07-18T23:59:59.000Z

226

Missouri Gas Energy (MGE) - Home Performance with ENERGY STAR | Department  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Missouri Gas Energy (MGE) - Home Performance with ENERGY STAR Missouri Gas Energy (MGE) - Home Performance with ENERGY STAR Missouri Gas Energy (MGE) - Home Performance with ENERGY STAR < Back Eligibility Construction Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Heating & Cooling Commercial Heating & Cooling Maximum Rebate Total Incentives: $600 ($1200 with KCP&L rebate) Wall Insulation: $600 Floor Insulation: $400 Attic Insulation: $500 Air Sealing: $400 Duct Sealing: $200 Window or Door: $400 Program Info Funding Source MGE State Missouri Program Type Utility Rebate Program Rebate Amount Single Family Energy Assessment: $400/unit Multi Family Energy Assessment: $200/unit Attic Insulation: $0.01-$0.02 x R-Value Added x sq. ft.

227

Home Performance with Energy Star (WPS Customers Only) | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Performance with Energy Star (WPS Customers Only) Performance with Energy Star (WPS Customers Only) Home Performance with Energy Star (WPS Customers Only) < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Construction Commercial Heating & Cooling Design & Remodeling Other Sealing Your Home Ventilation Appliances & Electronics Commercial Lighting Lighting Program Info State Wisconsin Program Type State Rebate Program Rebate Amount WPS doubles the existing Air Sealing, Attic Insulation, Exterior Wall Insulation, Sill Box Insulation, Interior Foundation Insulation: 33.3% of improvement costs up to $1,500 through Home Performance with ENERGY STAR Total: 66% of improvement costs of up to $3,000 Assisted Home Performance Bonus: Additional 15% off, for a total of 90% off

228

Solar-assisted electric clothes dryer using a home attic as a heat source  

DOE Green Energy (OSTI)

This study was undertaken to determine the suitability of using a southeastern home attic as a means of reducing the energy consumption of an electric clothes dryer. An inexpensive duct (duplicable for $25) was constructed to collect hot attic air from the peak of a south facing roof and introduce it into the dryer inlet. Instrumentation was added to measure inlet temperatures and operating time/energy consumption of the dryer. Standardized test loads, in addition to normal laundry, were observed over the period of one year. The heat-on time of the dryer tested was shown to be reduced .16 to .35 minutes per /sup 0/C rise in inlet temperature. Inlet temperatures produced by the attic duct peaked at 56/sup 0/C(133/sup 9/F) in May/June and 40/sup 0/C(104/sup 0/F) in February. Based on peak temperatures available between 2 and 4 pm each month, a potential 20% yearly average savings could be realized. Economic viability of the system, dependant primarily on dryer usage, can be computed using a formula derived from the test results and included in the report.

Stana, J.M.

229

A study of aggregation bias in estimating the market for home heating and cooling equipment  

SciTech Connect

Econometricians frequently propose parametric models which are contingent on an underlying assumption of rational economic agents maximizing their utility. Accurate estimation of the parameters of these models depends on using data disaggregated to the level of the actual agents, usually individual consumers or firms. Using data at some other level of aggregation introduces bias into the inferences made from the data. Unfortunately, properly disaggregated data is often unavailable, or at least, much more costly to obtain than aggregate data. Research on consumer choice of home heating equipment has long depended on state-level cross-sectional data. Only recently have investigators been able to build up and successfully use data on consumer attributes and choices at the household level. A study estimated for the Electric Power Research Institute REEPS model is currently one of the best of these. This paper examines the degree of bias that would be introduced in that study if only average data across SMSAs or states were used at several points in the investigation. We examine the market shares and elasticities estimated from that model using only the mean values of the exogenous variables, and find severe errors to be possible. However, if the models were calibrated on only aggregate data originally, we find that proper treatment allows market shares and elasticities to be found with little error relative to the disaggregate models. 22 refs., 4 figs., 10 tabs.

Wood, D.J.; Ruderman, H.; McMahon, J.E.

1989-05-01T23:59:59.000Z

230

Xcel Energy (Electric and Gas) - Home Performance with ENERGY STAR Rebates  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Xcel Energy (Electric and Gas) - Home Performance with ENERGY STAR Xcel Energy (Electric and Gas) - Home Performance with ENERGY STAR Rebates Xcel Energy (Electric and Gas) - Home Performance with ENERGY STAR Rebates < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Appliances & Electronics Construction Design & Remodeling Sealing Your Home Ventilation Commercial Lighting Lighting Water Heating Maximum Rebate $1,200 Program Info State Minnesota Program Type Utility Rebate Program Rebate Amount See Xcel's web site for current levels This program is available only to Minnesota residents who take both electric and natural gas service from Xcel Energy. Customers must undertake a low-cost energy audit ($60) before implementing energy-efficiency

231

Facility HVAC System Conversion to Ground Source Heat Pump Geothermal...  

Open Energy Info (EERE)

ventilators will utilize the hot water to "temper" outdoor air ventilation. Although the heat pump modules can provide both heating and cooling, the space requires heating only....

232

Breathing HRV by the Concept of AC Ventilation  

NLE Websites -- All DOE Office Websites (Extended Search)

Breathing HRV by the Concept of AC Ventilation Breathing HRV by the Concept of AC Ventilation Speaker(s): Hwataik Han Date: July 10, 2007 - 12:00pm Location: 90-3122 Seminar Host/Point of Contact: Thomas McKone Heat recovery ventilators are frequently used to save heating/cooling loads of buildings for ventilation. There are several types of HRV's, including a parallel plate type, a rotary type, a capillary type, and a heat pipe type. The breathing HRV is a heat recovery ventilator of a new kind using the concept of alternating-current ventilation. The AC ventilation is the ventilation with the airflow directions reversed periodically. It has an advantage of using a single duct system, for both supply and exhaust purposes. In order to develop a breathing HRV system, the thermal recovery performance should be investigated depending on many parameters, such as

233

Initial Business Case Analysis of Two Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes - Update to Include Evaluation of Impact of Including a Humidifier Option  

SciTech Connect

The long range strategic goal of the Department of Energy's Building Technologies (DOE/BT) Program is to create, by 2020, technologies and design approaches that enable the construction of net-zero energy homes at low incremental cost (DOE/BT 2005). A net zero energy home (NZEH) is a residential building with greatly reduced needs for energy through efficiency gains, with the balance of energy needs supplied by renewable technologies. While initially focused on new construction, these technologies and design approaches are intended to have application to buildings constructed before 2020 as well resulting in substantial reduction in energy use for all building types and ages. DOE/BT's Emerging Technologies (ET) team is working to support this strategic goal by identifying and developing advanced heating, ventilating, air-conditioning, and water heating (HVAC/WH) technology options applicable to NZEHs. In FY05 ORNL conducted an initial Stage 1 (Applied Research) scoping assessment of HVAC/WH systems options for future NZEHs to help DOE/BT identify and prioritize alternative approaches for further development. Eleven system concepts with central air distribution ducting and nine multi-zone systems were selected and their annual and peak demand performance estimated for five locations: Atlanta (mixed-humid), Houston (hot-humid), Phoenix (hot-dry), San Francisco (marine), and Chicago (cold). Performance was estimated by simulating the systems using the TRNSYS simulation engine (Solar Energy Laboratory et al. 2006) in two 1800-ft{sup 2} houses--a Building America (BA) benchmark house and a prototype NZEH taken from BEopt results at the take-off (or crossover) point (i.e., a house incorporating those design features such that further progress towards ZEH is through the addition of photovoltaic power sources, as determined by current BEopt analyses conducted by NREL). Results were summarized in a project report, HVAC Equipment Design options for Near-Zero-Energy Homes--A Stage 2 Scoping Assessment, ORNL/TM-2005/194 (Baxter 2005). The 2005 study report describes the HVAC options considered, the ranking criteria used, and the system rankings by priority. In 2006, the two top-ranked options from the 2005 study, air-source and ground-source versions of a centrally ducted integrated heat pump (IHP) system, were subjected to an initial business case study. The IHPs were subjected to a more rigorous hourly-based assessment of their performance potential compared to a baseline suite of equipment of legally minimum efficiency that provided the same heating, cooling, water heating, demand dehumidification, and ventilation services as the IHPs. Results were summarized in a project report, Initial Business Case Analysis of Two Integrated Heat Pump HVAC Systems for Near-Zero-Energy Homes, ORNL/TM-2006/130 (Baxter 2006a). The present report is an update to that document which summarizes results of an analysis of the impact of adding a humidifier to the HVAC system to maintain minimum levels of space relative humidity (RH) in winter. The space RH in winter has direct impact on occupant comfort and on control of dust mites, many types of disease bacteria, and 'dry air' electric shocks. Chapter 8 in ASHRAE's 2005 Handbook of Fundamentals (HOF) suggests a 30% lower limit on RH for indoor temperatures in the range of {approx}68-69F based on comfort (ASHRAE 2005). Table 3 in chapter 9 of the same reference suggests a 30-55% RH range for winter as established by a Canadian study of exposure limits for residential indoor environments (EHD 1987). Harriman, et al (2001) note that for RH levels of 35% or higher, electrostatic shocks are minimized and that dust mites cannot live at RH levels below 40%. They also indicate that many disease bacteria life spans are minimized when space RH is held within a 30-60% range. From the foregoing it is reasonable to assume that a winter space RH range of 30-40% would be an acceptable compromise between comfort considerations and limitation of growth rates for dust mites and many bacteria. In addition it reports som

Baxter, Van D [ORNL

2007-02-01T23:59:59.000Z

234

Review of Residential Ventilation Technologies.  

NLE Websites -- All DOE Office Websites (Extended Search)

Review of Residential Ventilation Technologies. Review of Residential Ventilation Technologies. Title Review of Residential Ventilation Technologies. Publication Type Journal Article LBNL Report Number LBNL-57730 Year of Publication 2007 Authors Russell, Marion L., Max H. Sherman, and Armin F. Rudd Journal HVAC&R Research Volume 13 Start Page Chapter Pagination 325-348 Abstract This paper reviews current and potential ventilation technologies for residential buildings in North America and a few in Europe. The major technologies reviewed include a variety of mechanical systems, natural ventilation, and passive ventilation. Key parameters that are related to each system include operating costs, installation costs, ventilation rates, heat recovery potential. It also examines related issues such as infiltration, duct systems, filtration options, noise, and construction issues. This report describes a wide variety of systems currently on the market that can be used to meet ASHRAE Standard 62.2. While these systems generally fall into the categories of supply, exhaust or balanced, the specifics of each system are driven by concerns that extend beyond those in the standard and are discussed. Some of these systems go beyond the current standard by providing additional features (such as air distribution or pressurization control). The market will decide the immediate value of such features, but ASHRAE may wish to consider modifications to the standard in the future.

235

Infiltration in ASHRAE's Residential Ventilation Standards  

Science Conference Proceedings (OSTI)

The purpose of ventilation is to dilute or remove indoor contaminants that an occupant could be exposed to. It can be provided by mechanical or natural means. ASHRAE Standards including standards 62, 119, and 136 have all considered the contribution of infiltration in various ways, using methods and data from 20 years ago. The vast majority of homes in the United States and indeed the world are ventilated through natural means such as infiltration caused by air leakage. Newer homes in the western world are tight and require mechanical ventilation. As we seek to provide acceptable indoor air quality at minimum energy cost, it is important to neither over-ventilate norunder-ventilate. Thus, it becomes critically important to correctly evaluate the contribution infiltration makes to both energy consumption and equivalent ventilation. ASHRAE Standard 62.2 specifies how much mechanical ventilation is considered necessary to provide acceptable indoor air quality, but that standard is weak on how infiltration can contribute towards meeting the total requirement. In the past ASHRAE Standard 136 was used to do this, but new theoretical approaches and expanded weather data have made that standard out of date. This article will describe how to properly treat infiltration as an equivalent ventilation approach and then use new data and these new approaches to demonstrate how these calculations might be done both in general and to update Standard 136.

Sherman, Max

2008-10-01T23:59:59.000Z

236

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

Own-Elasticities for Space Conditioning Equipment Equipmentthe choice of a space heat/air conditioning combination. Theutility from air conditioning and space heating alternative

Wood, D.J.

2010-01-01T23:59:59.000Z

237

Subsurface Ventilation System Description Document  

Science Conference Proceedings (OSTI)

The Subsurface Ventilation System supports the construction and operation of the subsurface repository by providing air for personnel and equipment and temperature control for the underground areas. Although the system is located underground, some equipment and features may be housed or located above ground. The system ventilates the underground by providing ambient air from the surface throughout the subsurface development and emplacement areas. The system provides fresh air for a safe work environment and supports potential retrieval operations by ventilating and cooling emplacement drifts. The system maintains compliance within the limits established for approved air quality standards. The system maintains separate ventilation between the development and waste emplacement areas. The system shall remove a portion of the heat generated by the waste packages during preclosure to support thermal goals. The system provides temperature control by reducing drift temperature to support potential retrieval operations. The ventilation system has the capability to ventilate selected drifts during emplacement and retrieval operations. The Subsurface Facility System is the main interface with the Subsurface Ventilation System. The location of the ducting, seals, filters, fans, emplacement doors, regulators, and electronic controls are within the envelope created by the Ground Control System in the Subsurface Facility System. The Subsurface Ventilation System also interfaces with the Subsurface Electrical System for power, the Monitored Geologic Repository Operations Monitoring and Control System to ensure proper and safe operation, the Safeguards and Security System for access to the emplacement drifts, the Subsurface Fire Protection System for fire safety, the Emplacement Drift System for repository performance, and the Backfill Emplacement and Subsurface Excavation Systems to support ventilation needs.

Eric Loros

2001-07-25T23:59:59.000Z

238

Subsurface Ventilation System Description Document  

Science Conference Proceedings (OSTI)

The Subsurface Ventilation System supports the construction and operation of the subsurface repository by providing air for personnel and equipment and temperature control for the underground areas. Although the system is located underground, some equipment and features may be housed or located above ground. The system ventilates the underground by providing ambient air from the surface throughout the subsurface development and emplacement areas. The system provides fresh air for a safe work environment and supports potential retrieval operations by ventilating and cooling emplacement drifts. The system maintains compliance within the limits established for approved air quality standards. The system maintains separate ventilation between the development and waste emplacement areas. The system shall remove a portion of the heat generated by the waste packages during preclosure to support thermal goals. The system provides temperature control by reducing drift temperature to support potential retrieval operations. The ventilation system has the capability to ventilate selected drifts during emplacement and retrieval operations. The Subsurface Facility System is the main interface with the Subsurface Ventilation System. The location of the ducting, seals, filters, fans, emplacement doors, regulators, and electronic controls are within the envelope created by the Ground Control System in the Subsurface Facility System. The Subsurface Ventilation System also interfaces with the Subsurface Electrical System for power, the Monitored Geologic Repository Operations Monitoring and Control System to ensure proper and safe operation, the Safeguards and Security System for access to the emplacement drifts, the Subsurface Fire Protection System for fire safety, the Emplacement Drift System for repository performance, and the Backfill Emplacement and Subsurface Excavation Systems to support ventilation needs.

NONE

2000-10-12T23:59:59.000Z

239

TVA Partner Utilities - In-Home Energy Evaluation Pilot Program (Georgia) |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

TVA Partner Utilities - In-Home Energy Evaluation Pilot Program TVA Partner Utilities - In-Home Energy Evaluation Pilot Program (Georgia) TVA Partner Utilities - In-Home Energy Evaluation Pilot Program (Georgia) < Back Eligibility Installer/Contractor Residential Utility Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Other Design & Remodeling Windows, Doors, & Skylights Ventilation Manufacturing Heat Pumps Maximum Rebate 50% cost up to $500 Program Info State Georgia Program Type Utility Rebate Program Rebate Amount Windows: $500 Duct Repair, Replacement, and Sealing: $500 Minor Repair Work: $250 Replace HVAC: $250 Insulation: $500 Electric Water Heater and Pipe Insulation: $50 Air Sealing: $500 Caulking, Weatherstripping, and other Self Installed Improvements: $250

240

Advanced Controls and Sustainable Systems for Residential Ventilation  

NLE Websites -- All DOE Office Websites (Extended Search)

Advanced Controls and Sustainable Systems for Residential Ventilation Advanced Controls and Sustainable Systems for Residential Ventilation Title Advanced Controls and Sustainable Systems for Residential Ventilation Publication Type Report LBNL Report Number LBNL-5968E Year of Publication 2012 Authors Turner, William J. N., and Iain S. Walker Date Published 12/2012 Keywords ashrae standard 62,2, california title 24, passive ventilation, residential ventilation, ventilation controller Abstract Whole-house ventilation systems are becoming commonplace in new construction, remodeling/renovation, and weatherization projects, driven by combinations of specific requirements for indoor air quality (IAQ), health, and compliance with standards, such as ASHRAE 62.2. At the same time we wish to reduce the energy use in homes and therefore minimize the energy used to provide ventilation. This study examined several approaches to reducing the energy requirements of providing acceptable IAQ in residential buildings. Two approaches were taken. The first used RIVEC - the Residential Integrated VEntilation Controller - a prototype ventilation controller that aims to deliver whole-house ventilation rates that comply with ventilation standards, for the minimum use of energy. The second used passive and hybrid ventilation systems, rather than mechanical systems, to provide whole-house ventilation.

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


241

MassSAVE - HEAT Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

MassSAVE - HEAT Loan Program MassSAVE - HEAT Loan Program MassSAVE - HEAT Loan Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Heat Pumps Appliances & Electronics Water Heating Windows, Doors, & Skylights Solar Maximum Rebate $25,000 Program Info State Massachusetts Program Type Utility Loan Program Rebate Amount HEAT (Micro Loan): $500 - $2,000 Heat (1-4 Unit, Owner Occupied): $2,000 - $25,000 Heat (1-4 Unit, Non-owner Occupied): $5,000 - $25,000 Provider MassSAVE Residential customers of Cape Light Compact, National Grid, NSTAR, Unitil and Western Massachusetts Electric Company may be eligible for zero-interest financing to help increase the energy efficiency of their

242

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Heater Heat Pumps Replacing Your Electric Furnace and CAC with a Heat Pump Sealing Home Air Leaks LPG Furnaces Efficient LPG-fired Water Heaters Oil Furnaces Efficient...

243

The Pacific Northwest residential consumer: Perceptions and preferences of home heating fuels, major appliances, and appliance fuels  

SciTech Connect

In 1983 the Bonneville Power Administration contracted with the Pacific Northwest Laboratory (PNL) to conduct an analysis of the marketing environment for Bonneville's conservation activities. Since this baseline residential study, PNL has conducted two follow up market research projects: Phase 2 in 1985, and Phase 3, in 1988. In this report the respondents' perceptions, preferences, and fuel switching possibilities of fuels for home heating and major appliances are examined. To aid in effective target marketing, the report identifies market segments according to consumers' demographics, life-cycle, attitudes, and opinions.

Harkreader, S.A.; Hattrup, M.P.

1988-09-01T23:59:59.000Z

244

Floor-supply displacement ventilation system  

E-Print Network (OSTI)

Research on indoor environments has received more attention recently because reports of symptoms and other health complaints related to indoor environments have been increasing. Heating, ventilating, and air-conditioning ...

Kobayashi, Nobukazu, 1967-

2001-01-01T23:59:59.000Z

245

Liquid ventilation  

E-Print Network (OSTI)

For 350 million years, fish have breathed liquid through gills. Mammals evolved lungs to breathe air. Rarely, circumstances can occur when a mammal needs to `turn back the clock' to breathe through a special liquid medium. This is particularly true if surface tension at the air-liquid interface of the lung is increased, as in acute lung injury. In this condition, surface tension increases because the pulmonary surfactant system is damaged, causing alveolar collapse, atelectasis, increased right-to-left shunt and hypoxaemia. 69 The aims of treatment are: (i) to offset increased forces causing lung collapse by applying mechanical ventilation with PEEP; (ii) to decrease alveolar surface tension with exogenous surfactant; (iii) to eliminate the air-liquid interface by filling the lung with a fluid in

U. Kaisers; K. P. Kelly; T. Busch

2003-01-01T23:59:59.000Z

246

PERFORMANCE OF RESIDENTIAL AIR-TO-AIR HEAT EXCHANGERS: TEST METHODS AND RESULTS  

E-Print Network (OSTI)

Presenting Test Results Heat Exchanger Descriptions and Testof Residential Heat Exchangers Conclusions . . . . . . . .ventilation testing heat exchangers. system, a heat

Fisk, William J.

2013-01-01T23:59:59.000Z

247

Meeting Residential Ventilation Standards Through Dynamic Control...  

NLE Websites -- All DOE Office Websites (Extended Search)

Meeting Residential Ventilation Standards Through Dynamic Control of Ventilation Systems Title Meeting Residential Ventilation Standards Through Dynamic Control of Ventilation...

248

Assessment of National Benefits from Retrofitting Existing Single-Family Homes with Ground Source Heat Pump Systems  

Science Conference Proceedings (OSTI)

This report assesses the potential national benefits of retrofitting U.S. single-family homes with state-of-the-art GSHP systems at various penetration rates. The benefits considered include energy savings, reduced summer electrical peak demand, consumer utility bill savings, and reduced carbon dioxide (CO2) emissions. The assessment relies heavily on energy consumption and other data obtained from the Residential Energy Consumption Survey conducted by the U.S. Department of Energy s Energy Information Administration. It also considers relative differences in energy consumption between a state-of-the-art GSHP system and existing residential space-heating, space-cooling, and water-heating (SH SC WH) systems, which were determined with a well-established energy analysis program for residential SH SC WH systems. The impacts of various climate and geological conditions, as well as the efficiency and market share of existing residential SH SC WH systems, have been taken into account in the assessment.

Liu, Xiaobing [ORNL

2011-01-01T23:59:59.000Z

249

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

of space heating to air conditioning choice; 3) explicitthe presence of central air conditioning, it seems unwise tonot to have central air conditioning. Statistical evidence

Wood, D.J.

2010-01-01T23:59:59.000Z

250

Heating and cooling no longer majority of U.S. home energy use ...  

U.S. Energy Information Administration (EIA)

For decades, space heating and cooling (space conditioning) accounted for more than half of all residential energy consumption. Estimates from the ...

251

What is the outlook for home heating fuel prices this winter ...  

U.S. Energy Information Administration (EIA)

Petroleum & Other Liquids. Crude oil, gasoline, heating oil, diesel, propane, and other liquids including biofuels and natural gas liquids. Natural Gas

252

Heating and cooling no longer majority of U.S. home energy use ...  

U.S. Energy Information Administration (EIA)

Tools; Glossary All Reports ... Non-weather related energy use for appliances, electronics, water heating, and lighting now accounts for 52% of total consumption, ...

253

Demand Controlled Ventilation and Classroom Ventilation  

NLE Websites -- All DOE Office Websites (Extended Search)

3 3 Authors Fisk, William J., Mark J. Mendell, Molly Davies, Ekaterina Eliseeva, David Faulkner, Tienzen Hong, and Douglas P. Sullivan Publisher Lawrence Berkeley National Laboratory City Berkeley Keywords absence, building s, carbon dioxide, demand - controlled ventilation, energy, indoor air quality, schools, ventilation Abstract This document summarizes a research effort on demand controlled ventilation and classroom ventilation. The research on demand controlled ventilation included field studies and building energy modeling. Major findings included:  The single-location carbon dioxide sensors widely used for demand controlled ventilation frequently have large errors and will fail to effectively control ventilation rates (VRs).  Multi-location carbon dioxide measurement systems with more expensive sensors connected to multi-location sampling systems may measure carbon dioxide more accurately.

254

DOE Challenge Home Case Study: Preferred Builders ? Old Greenwich...  

NLE Websites -- All DOE Office Websites (Extended Search)

air handlers have variable-speed fans and are equipped with 16.5-SEER air conditioning units for cooling. For ventilation, the home has an energy recovery ventilator (ERV) that...

255

Home systems research house: Gas heat pump cooling characterization test results. Topical report, July-September 1991  

Science Conference Proceedings (OSTI)

Cooling performance characterization tests were performed at the GRI Home Systems Research House located in the NAHB Research Home Park in Prince George's County, Maryland. Test protocols followed guidelines set forth in GRI's Research House Utilization Plan (RHUP). A combination of minute-by-minute and hourly average data consisting of weather, comfort, and energy parameters was collected by using an automated data acquisition system. The tests were performed from July 1991 through September 1991. The gas heat pump (GHP) had an average daily gas coefficient of performance (COP) value of 1.49 at an outdoor temperature of 72.8 F and 0.84 at an outdoor temperature of 83.9 F. The average test period gas COP was 1.13. The GHP peak cooling capacity achieved was approximately 34,000 Btuh. The GHP provided good overall thermal comfort control on the first-floor and moderate thermal comfort control on the second floor. Reduced second floor performance was primarily due to thermostat location and the stack effect. Good latent heat removal existed throughout the test period. Unit modulation kept room air stratification to a minimum. Thermostat setback saved energy at high average daily outdoor temperatures and used more energy at lower average daily outdoor temperatures, compared to a constant thermostat setpoint control, due to changes in unit gas COP values from low-speed to high-speed operation.

Reigel, H.D.; Kenney, T.M.; Liller, T.C.

1993-01-01T23:59:59.000Z

256

Kansas City Power and Light - ENERGY STAR New Homes Rebate Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Kansas City Power and Light - ENERGY STAR New Homes Rebate Program Kansas City Power and Light - ENERGY STAR New Homes Rebate Program Kansas City Power and Light - ENERGY STAR New Homes Rebate Program < Back Eligibility Construction Installer/Contractor Multi-Family Residential Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Construction Commercial Heating & Cooling Design & Remodeling Sealing Your Home Windows, Doors, & Skylights Ventilation Maximum Rebate KCP&L ENERGY STAR New Construction: $600 MGE ENERGY STAR New Construction: $600 Insulation: $400-$600 Air Sealing: $400 Duct Sealing: $200 Program Info Funding Source KCP&L and MGE State Missouri Program Type Utility Rebate Program Rebate Amount Upgrade to a High-Efficiency Cooling System: $850 Single Family Energy Assessment: $400/unit

257

Israeli manufacturer introduces solar heating for home use in Greece and Turkey  

SciTech Connect

Miromit Ltd. of Tel Aviv, Israel's principal developer and producer of solar heating equipment, said to be the world's large manufacturer in the field, recently announced the completion of a marketing agreement with major heating companies in Greece and Turkey which are introducing solar energy for hot water heating in their countries. Both of these countries will benefit from continuous Miromit research and development in new Sun heating applications, including central hot water installations for apartment buildings and solar-heating systems for swimming pools, sport halls, and agricultural and industrial buildings. Israeli solar equipment has been installed in a research model apartment building at the Goddard Space Flight Center of NASA in Green Belt, Md. (MCW)

1976-05-01T23:59:59.000Z

258

VENTILATION NEEDS DURING CONSTRUCTION  

Science Conference Proceedings (OSTI)

The purpose of this analysis is to determine ventilation needs during construction and development of the subsurface repository and develop systems to satisfy those needs. For this analysis, construction is defined as pre-emplacement excavation and development is excavation that takes place simultaneously with emplacement. The three options presented in the ''Overall Development and Emplacement Ventilation Systems'' analysis (Reference 5.5) for development ventilation will be applied to construction ventilation in this analysis as well as adding new and updated ventilation factors to each option for both construction and development. The objective of this analysis is to develop a preferred ventilation system to support License Application Design. The scope of this analysis includes: (1) Description of ventilation conditions; (2) Ventilation factors (fire hazards, dust control, construction logistics, and monitoring and control systems); (3) Local ventilation alternatives; (4) Global ventilation options; and (5) Evaluation of options.

C.R. Gorrell

1998-07-23T23:59:59.000Z

259

Hysteresis effects in hybrid building ventilation  

E-Print Network (OSTI)

radiation, external wind forcing and internal heat gains e.g. due to electrical equipment or building chloride, etc. Developing world: By-products of cooking or heating fires Ghiaus & Allard (2005) · Exposure-breeze, displacement ventilation dissipate internal heat gains e.g. from kitchen stove · Wintertime: Spaces filled

Flynn, Morris R.

260

Home and Building Technologies | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home and Building Technologies Home and Building Technologies Homes and other buildings use energy every day for space heating and cooling, for lighting and hot water, and for...

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


261

The evaluation of a 4000-home geothermal heat pump retrofit at Fort Polk, Louisiana: Final Report  

SciTech Connect

This report documents an independent evaluation of an energy retrofit of 4,003 family housing units at Fort Polk, Louisiana, under an energy savings performance contract (ESPC). Replacement of the heating, cooling, and water heating systems in these housing units with geothermal heat pumps (GHPs) anchored the retrofit; low-flow shower heads and compact fluorescent lighting were also installed, as well as attic insulation where needed. Statistically valid findings indicate that the project will save 25.8 million kWh, or 32.5% of the pre-retrofit whole-community electrical consumption, and 100% of the whole-community natural gas previously used for space conditioning and water heating (260,000 therms) in a typical meteorological year. At the end-use level, the GHPs were found to save about 42% of the pre-retrofit electrical consumption for heating, cooling, and water heating in housing units that were all-electric in the pre-retrofit period. This report also demonstrates an improved method of predicting energy savings. Using an engineering model calibrated to pre-retrofit energy use data collected in the field, the method predicted actual energy savings on one of the electric feeders at Fort Polk with a very high degree of accuracy. The accuracy of this model was in turn dependent on data-calibrated models of the geothermal heat pump and ground heat exchanger that are described in this report. In addition this report documents the status of vertical borehole ground heat exchanger (BHEx) design methods at the time this project was designed, and demonstrates methods of using data collected from operating GHP systems to benchmark BHEx design methods against a detailed engineering model calibrated to date. The authors also discuss the ESPC`s structure and implementation and how the experience gained here can contribute to the success of future ESPCs.

Hughes, P.J.; Shonder, J.A.

1998-03-01T23:59:59.000Z

262

Market Share Elasticities for Fuel and Technology Choice in Home Heating and Cooling  

E-Print Network (OSTI)

level, the choice alternatives are cooling and no cooling.to zero in central cooling alternative Income ($1000) in airalternatives are conventional air conditioning and heat pump, given the cooling

Wood, D.J.

2010-01-01T23:59:59.000Z

263

Home Heating Systems Design using PHP and MySQL Databases  

E-Print Network (OSTI)

This paper presents the use of a computer application based on a MySQL database, managed by PHP programs, allowing the selection of a heating device using coefficient-based calculus.

Karnyanszky, Tiberiu Marius

2009-01-01T23:59:59.000Z

264

Results of a field test of heating system efficiency and thermal distribution system efficiency in a manufactured home  

SciTech Connect

A two-day test using electric coheating was performed on a manufactured home in Watertown, New York. The main objective of the test was to evaluate planned procedures for measuring thermal distribution system efficiency. (Thermal distribution systems are the ductwork or piping used to transport heat or cooling effect from the equipment that produces it to the building spaces in which it is used.) These procedures are under consideration for a standard method of test now being prepared by a special committee of the American Society of Heating, Refrigerating, and Air-Conditioning Engineers. The ability of a coheating test to give a credible and repeatable value for the overall heating system efficiency was supported by the test data. Distribution efficiency is derived from system efficiency by correcting for energy losses from the equipment. Alternative means for achieving this were tested and assessed. The best value for system efficiency in the Watertown house was 0.53, while the best value for distribution efficiency was 0.72.

Andrews, J.W.; Krajewski, R.F.; Strasser, J.J. [Brookhaven National Lab., Upton, NY (United States); Kinney, L.; Lewis, G. [Synertech Systems Corp., Syracuse, NY (United States)

1995-05-01T23:59:59.000Z

265

Energy Basics: Home and Building Technologies  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

& Cooling Water Heating Home and Building Technologies Homes and other buildings use energy every day for space heating and cooling, for lighting and hot water, and for...

266

Home Energy Yardstick : ENERGY STAR  

NLE Websites -- All DOE Office Websites (Extended Search)

Home > Home Improvement > Home Energy Yardstick Home > Home Improvement > Home Energy Yardstick Home Energy Yardstick Assess the energy efficiency of your home and see how it measures up: EPA's Home Energy Yardstick provides a simple assessment of your home's annual energy use compared to similar homes. By answering a few basic questions about your home, you can get: Your home's Home Energy Yardstick score (on a scale of 1 to 10); Insights into how much of your home's energy use is related to heating and cooling versus other everyday uses like appliances, lighting, and hot water; Links to guidance from ENERGY STAR on how to increase your home's score, improve comfort, and lower utility bills; and An estimate of your home's annual carbon emissions. Learn more about how the Home Energy Yardstick works.

267

Do Households Smooth Small Consumption Shocks? Evidence from Anticipated and Unanticipated Variation in Home Energy Costs  

E-Print Network (OSTI)

natural gas, and home heating oil prices averaged over thein 2000 and 2001. Home heating oil prices show a similarstate. Information on home heating oil prices comes from

Cullen, Julie Berry; Friedberg, Leora; Wolfram, Catherine

2005-01-01T23:59:59.000Z

268

Evaluation of an Incremental Ventilation Energy Model for Estimating  

NLE Websites -- All DOE Office Websites (Extended Search)

Evaluation of an Incremental Ventilation Energy Model for Estimating Evaluation of an Incremental Ventilation Energy Model for Estimating Impacts of Air Sealing and Mechanical Ventilation Title Evaluation of an Incremental Ventilation Energy Model for Estimating Impacts of Air Sealing and Mechanical Ventilation Publication Type Report LBNL Report Number LBNL-5796E Year of Publication 2012 Authors Logue, Jennifer M., William J. N. Turner, Iain S. Walker, and Brett C. Singer Date Published 06/2012 Abstract Changing the rate of airflow through a home affects the annual thermal conditioning energy.Large-scale changes to airflow rates of the housing stock can significantly alter the energy consumption of the residential energy sector. However, the complexity of existing residential energy models hampers the ability to estimate the impact of policy changes on a state or nationwide level. The Incremental Ventilation Energy (IVE) model developed in this study was designed to combine the output of simple airflow models and a limited set of home characteristics to estimate the associated change in energy demand of homes. The IVE model was designed specifically to enable modelers to use existing databases of home characteristics to determine the impact of policy on ventilation at a population scale. In this report, we describe the IVE model and demonstrate that its estimates of energy change are comparable to the estimates of a well-validated, complex residential energy model when applied to homes with limited parameterization. Homes with extensive parameterization would be more accurately characterized by complex residential energy models. The demonstration included a range of home types, climates, and ventilation systems that cover a large fraction of the residential housing sector.

269

Using the sun and waste wood to heat a central Ohio home. Final technical report  

DOE Green Energy (OSTI)

The description of a house in Ohio built on a south facing slope with two levels above ground on the north, east, and west sides and three levels exposed to the southern winter Sun is presented. The floor plan, a general history of the project, the operation of the system, the backup heat source (wood), the collection of data, and the procedure for determining actual heat loss are described. Additionally, the calculation of the solar contribution percentage and the amount of mass to be included in the greenhouse and problems with an indirect gain wall are discussed. The location of the wood stove in the system is noted. The east wall temperature data are given. Soil temperature, air infiltration, thermal comfort, and energy usage are discussed. (MCW).

Not Available

1981-01-01T23:59:59.000Z

270

The Ventilated Ocean  

Science Conference Proceedings (OSTI)

Adiabatic theories of ocean circulation and density structure have a long tradition, from the concept of the ventilated thermocline to the notion that deep ocean ventilation is controlled by westerly winds over the Southern Ocean. This study ...

Patrick Haertel; Alexey Fedorov

2012-01-01T23:59:59.000Z

271

Methodology for the evaluation of a 4000-home geothermal heat pump retrofit at Fort Polk, Louisiana  

Science Conference Proceedings (OSTI)

The US Army and a private energy service company are developing a comprehensive energy efficiency project to upgrade the family housing at Fort Polk, Louisiana. The project includes converting the space conditioning systems of more than 4,000 housing units to geothermal (or ground-source) heat pumps (GHPs). This interim report describes the methodology of the evaluation associated with this project, including the field monitoring that has been conducted at the base.

Hughes, P.J.; Shonder, J.A.; White, D.L.; Huang, H.L.

1998-03-01T23:59:59.000Z

272

Coal, Smoke, and Death: Bituminous Coal and American Home Heating, 1920-1959  

E-Print Network (OSTI)

Air pollution was severe in many parts of the United States in the first half of the twentieth century. Much of the air pollution was attributable to bituminous coal. This paper uses newly digitized state-month mortality data to estimate the effects of bituminous coal consumption for heating on mortality rates in the U.S. between 1920 and 1959. The use of coal for heating was high until the mid-1940s, and then declined sharply. The switch to cleaner fuels was driven by plausibly exogenous changes in the availability of natural gas, the end of war-related supply restrictions, and a series of coal strikes from 1946-1950. The identification strategy leverages the fact that coal consumption for heating increases during cold weather. Specifically, the mortality effects are identified from differences in the temperature-mortality response functions in state-years with greater coal consumption. Cold weather spells in high coal state-years saw greater increases in the mortality rates than cold weather spells in low coal state-years. Our estimates suggest that reductions in the use of bituminous coal for heating between 1945 and 1959 decreased average annual mortality by 2.2-3.5 percent, January mortality by 3.2-5.1 percent, average annual infant mortality by 1.6-2.8 percent, and January infant mortality by 3.1-4.6 percent. Our estimates are likely to be a lower-bound, since they only capture short-run relationships between coal and mortality. We thank Leila Abu-Orf, Paula Levin, and Katherine Rudolph for excellent research assistance. We are grateful to

Alan Barreca

2012-01-01T23:59:59.000Z

273

Incremental cost of electricity used as backup for passive heated homes  

DOE Green Energy (OSTI)

The impact of passive technologies on a north-central US utility has been studied. A method of utility cost and fuel use analysis, developed at Brookhaven National Laboratory, was used to compute the long run incremental costs and incremental fuel use required for supplementary electricity to houses with Trombe walls or with direct gain features. For comparison, a reference house with no passive features and a house with an energy conservation design were also analyzed. The results show that the total long run incremental cost to the utility of providing supplementary power to the passive houses costs no more than the cost to supply electricity to heat the reference house or the conservation house. An analysis of the annual homeowner costs for the various types of heating systems suggests that the Trombe wall technology is not promising for use in this climate. The passive technologies, as modelled in this study reduced the requirements for conventional energy by about 10% (7 to 10 kilojoules/year). For all of the house types studied, the use of electricity for heating, instead of oil or gas, reduced the overall (utility plus residential) use of oil or gas by only about 30 to 40% even out through the 1990's.

Martorella, J; Bright, R; Davitian, H

1980-08-01T23:59:59.000Z

274

Challenge Home Events | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Challenge Home Events Challenge Home Events Challenge Home Events Sorted By Date Sort By Location Sort By Event Description Contact TBA West Chester, Pennsylvania DOE Challenge Home Zero Net-Energy-Ready Home Training DOE Challenge Home is conducting this Zero Net-Energy-Ready Home training with our Training Partner, the Home Ventilating Institute. Coming soon! January 16, 2014 Latham, New York DOE Challenge Home Zero Net-Energy-Ready Home Training DOE Challenge Home is conducting this Zero Net-Energy-Ready Home training with our Training Partner, the New York State Builders Association (NYSBA). Register by emailing Juli Turner at jturner@nysba.com March 24, 2014 Lexington, Kentucky DOE Challenge Home Zero Net-Energy-Ready Home Training This 3.5-hour training provides builders with a comprehensive review of zero net-energy-ready home construction including the business case, detailed specifications, and opportunities to be recognized as an industry leader.

275

Key Factors in Displacement Ventilation Systems for Better IAQ  

E-Print Network (OSTI)

This paper sets up a mathematical model of three-dimensional steady turbulence heat transfer in an air-conditioned room of multi-polluting heat sources. Numerical simulation helps identify key factors in displacement ventilation systems that affect air-quality in rooms of multi-polluting heat sources. Results show that it is very important to determine the suitable air-intemperature , air-inflow, and heat source quantity and dispersion, to obtain better displacement ventilation results.

Wang, X.; Chen, J.; Li, Y.; Wang, Z.

2006-01-01T23:59:59.000Z

276

Dust and Ventilation Effects on Radiant Barriers: Cooling Season Energy Measurements  

Science Conference Proceedings (OSTI)

This study on the effects of attic ventilation area and type and dust buildup on horizontal and truss radiant barriers in insulated homes can help utilities reduce cooling season electric energy requirements. Increasing the ventilation area ratio and changing ventilation types had little effect on radiant barrier performance. Dust did degrade performance, but insulated homes with radiant barriers still had lower energy requirements than those without radiant barriers.

1990-05-15T23:59:59.000Z

277

Federal Energy Management Program: New and Underutilized Heating,  

NLE Websites -- All DOE Office Websites (Extended Search)

Heating, Ventilation, and Air Conditioning Technologies to Heating, Ventilation, and Air Conditioning Technologies to someone by E-mail Share Federal Energy Management Program: New and Underutilized Heating, Ventilation, and Air Conditioning Technologies on Facebook Tweet about Federal Energy Management Program: New and Underutilized Heating, Ventilation, and Air Conditioning Technologies on Twitter Bookmark Federal Energy Management Program: New and Underutilized Heating, Ventilation, and Air Conditioning Technologies on Google Bookmark Federal Energy Management Program: New and Underutilized Heating, Ventilation, and Air Conditioning Technologies on Delicious Rank Federal Energy Management Program: New and Underutilized Heating, Ventilation, and Air Conditioning Technologies on Digg Find More places to share Federal Energy Management Program: New and

278

Water Heating: Energy-efficient strategies for supplying hot water in the home (BTS Technology Fact Sheet)  

SciTech Connect

Fact sheet for homeowners and contractors on how to supply hot water in the home while saving energy.

NAHB Research Center; Southface Energy Institute; U.S. Department of Energy' s Oak Ridge Laboratory; U.S. Department of Energy' s National Renewable Energy Laboratory

2001-08-15T23:59:59.000Z

279

Heating Systems  

Energy.gov (U.S. Department of Energy (DOE))

A variety of heating technologies are available today. In addition to heat pumps, which are discussed separately, many homes and buildings use the following approaches:

280

Building Science - Ventilation  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Ventilation Joseph Lstiburek, Ph.D., P.Eng, ASHRAE Fellow www.buildingscience.com Build Tight - Ventilate Right Building Science Corporation Joseph Lstiburek 2 Build Tight - Ventilate Right How Tight? What's Right? Building Science Corporation Joseph Lstiburek 3 Air Barrier Metrics Material 0.02 l/(s-m2) @ 75 Pa Assembly 0.20 l/(s-m2) @ 75 Pa Enclosure 2.00 l/(s-m2) @ 75 Pa 0.35 cfm/ft2 @ 50 Pa 0.25 cfm/ft2 @ 50 Pa 0.15 cfm/ft2 @ 50 Pa Building Science Corporation Joseph Lstiburek 4 Getting rid of big holes 3 ach@50 Getting rid of smaller holes 1.5 ach@50 Getting German 0.6 ach@50 Building Science Corporation Joseph Lstiburek 5 Best As Tight as Possible - with - Balanced Ventilation Energy Recovery Distribution Source Control - Spot exhaust ventilation Filtration

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


281

ASHRAE and residential ventilation  

E-Print Network (OSTI)

conditioning Engineers. 2001. ASHRAE, Indoor Air QualityABOUT/IAQ_papr01.htm ASHRAE. Standard 62.2-2003:Ventilation Requirements. ASHRAE Journal, pp. 51- 55, June

Sherman, Max H.

2003-01-01T23:59:59.000Z

282

Carbon-dioxide-controlled ventilation study  

Science Conference Proceedings (OSTI)

The In-House Energy Management (IHEM) Program has been established by the U.S. Department of Energy to provide funds to federal laboratories to conduct research on energy-efficient technology. The Energy Sciences Department of Pacific Northwest Laboratory (PNL) was tasked by IHEM to research the energy savings potential associated with reducing outdoor-air ventilation of buildings. By monitoring carbon dioxide (CO{sub 2}) levels in a building, outdoor air provided by the heating, ventilating, and air-conditioning (HVAC) system can be reduced to the percentage required to maintain satisfactory CO{sub 2} levels rather than ventilating with a higher outdoor-air percentage based on an arbitrary minimum outdoor-air setting. During summer months, warm outdoor air brought into a building for ventilation must be cooled to meet the appropriate cooling supply-air temperature, and during winter months, cold outdoor air must be heated. By minimizing the amount of hot or cold outdoor air brought into the HVAC system, the supply air requires less cooling or heating, saving energy and money. Additionally, the CO{sub 2} levels in a building can be monitored to ensure that adequate outdoor air is supplied to a building to maintain air quality levels. The two main considerations prior to implementing CO{sub 2}-based ventilation control are its impact on energy consumption and the adequacy of indoor air quality (IAQ) and occupant comfort. To address these considerations, six portable CO{sub 2} monitors were placed in several Hanford Site buildings to estimate the adequacy of office/workspace ventilation. The monitors assessed the potential for reducing the flow of outdoor-air to the buildings. A candidate building was also identified to monitor various ventilation control strategies for use in developing a plan for implementing and assessing energy savings.

McMordie, K.L.; Carroll, D.M.

1994-05-01T23:59:59.000Z

283

LBNL REPORT NUMBER 53776; OCTOBER 2003 ASHRAE &Residential Ventilation  

E-Print Network (OSTI)

LBNL REPORT NUMBER 53776; OCTOBER 2003 ASHRAE &Residential Ventilation Max Sherman Energy Performance of Buildings Group IED/EETD Lawrence Berkeley Laboratory1 MHSherman@lbl.gov ASHRAE, the American of heating, ventilating, air-conditioning and refrigeration (HVAC&R). ASHRAE has recently released a new

284

The End-Use Technology Assessment Project: A Load-Shape Analysis of Ground Source Heat Pumps and Good Cents Homes  

Science Conference Proceedings (OSTI)

Interest is growing in end-use technology applications that promote overall energy efficiency through increased electricity use. This study will help utilities understand the impacts of such applications by providing load-shape information on ground source heat pumps as well as energy-efficient appliances promoted through Good Cents Homes programs. This report is available only to funders of Program 101A or 101.001. Funders may download this report at http://my.primen.com/Applications/DE/Community/index...

1995-05-27T23:59:59.000Z

285

Meeting Residential Ventilation Standards Through Dynamic Control of Ventilation Systems  

E-Print Network (OSTI)

Rudd. 2007. Review of residential ventilation technologies.2009. EISG Final Report: Residential Integrated VentilationDesign and Operation of Residential Cooling Systems. Proc.

Sherman, Max H.

2011-01-01T23:59:59.000Z

286

Home Weatherization | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Weatherization Weatherization Home Weatherization A home energy audit is the first step to saving energy and money. Our Energy Saver 101 infographic breaks down a home energy audit, explaining what energy auditors look for and the special tools they use to determine where a home is wasting energy. Explore the full infographic now. A home energy audit is the first step to saving energy and money. Our Energy Saver 101 infographic breaks down a home energy audit, explaining what energy auditors look for and the special tools they use to determine where a home is wasting energy. Explore the full infographic now. From air sealing to improving ventilation to adding insulation, home weatherization helps consumers save money by saving energy. Weatherization

287

Electric co-heating in the ASHRAE standard method of test for thermal distribution efficiency: Test results on two New York State homes  

SciTech Connect

Electric co-heating tests on two single-family homes with forced-air heating systems were carried out in March 1995. The goal of these tests was to evaluate procedures being considered for incorporation in a Standard Method of Test for thermal distribution system efficiency now being developed by ASHRAE. Thermal distribution systems are the ductwork, piping, or other means used to transport heat or cooling effect from the building equipment that produces this thermal energy to the spaces in which it is used. Furthering the project goal, the first objective of the tests was to evaluate electric co-heating as a means of measuring system efficiency. The second objective was to investigate procedures for obtaining the distribution efficiency, using system efficiency as a base. Distribution efficiencies of 0.63 and 0.70 were obtained for the two houses.

Andrews, J.W.; Krajewski, R.F.; Strasser, J.J.

1995-10-01T23:59:59.000Z

288

EPA_T1542_SECTOR_ResHomeImprv  

NLE Websites -- All DOE Office Websites (Extended Search)

to improve energy efficiency at home: > ENERGY STAR's Home Energy Yardstick > The DIY Guide to ENERGY STAR Home Sealing > ENERGY STAR's Guide to Energy-Efficient Heating and...

289

Energy-Efficient Home Design | Department of Energy  

NLE Websites -- All DOE Office Websites (Extended Search)

more light and absorb less heat from sunlight, which keeps homes cooler during hot weather. Passive Solar Home Design Passive solar home design takes advantage of climatic...

290

Columbia Water & Light - New Home Energy Star Rebate | Department...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

New Home Energy Star Rebate Columbia Water & Light - New Home Energy Star Rebate Eligibility Construction Residential Savings For Heating & Cooling Home Weatherization Construction...

291

Home and Building Technology Basics | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home and Building Technology Basics Home and Building Technology Basics Homes and other buildings use energy every day for space heating and cooling, for lighting and hot water,...

292

Multifamily Ventilation Retrofit Strategies  

SciTech Connect

In multifamily buildings, central ventilation systems often have poor performance, overventilating some portions of the building (causing excess energy use), while simultaneously underventilating other portions (causing diminished indoor air quality). BSC and Innova Services Corporation performed a series of field tests at a mid-rise test building undergoing a major energy audit and retrofit, which included ventilation system upgrades.

Ueno, K.; Lstiburek, J.; Bergey, D.

2012-12-01T23:59:59.000Z

293

Multifamily Ventilation - Best Practice?  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Multifamily Ventilation - Best Practice? Multifamily Ventilation - Best Practice? Dianne Griffiths April 29, 2013 Presentation Outline * Basic Objectives * Exhaust Systems * Make-up Air Systems Two Primary Ventilation Objectives 1) Providing Fresh Air - Whole-House 2) Removing Pollutants - Local Exhaust Our goal is to find the simplest solution that satisfies both objectives while minimizing cost and energy impacts. Common Solution: Align local exhaust with fresh air requirements (Ex: 25 Bath + 25 Kitchen) Exhaust-Driven Fresh Air Design * Exhaust slightly depressurizes the units * Outside air enters through leaks, cracks, or planned inlets * Widely used in the North Multifamily Ventilation Best Practice * Step 1: Understand ventilation requirements * Step 2: Select the simplest design that can

294

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Glossary Glossary Heating, Ventilation and Cooling Terminology System Capacity System capacity is a measurement of the total amount of heat or cooling the furnace, heat pump or air conditioner can produce in one hour. This amount is reported in Btu/hr on the nameplate of the equipment. Btu Btu, short for British Thermal Unit is a unit of heat energy. One Btu is the amount of heat needed to raise the temperature of one pound of water 1°F. To get a rough idea of how much heat energy this is, the heat given off by burning one wooden kitchen match is approximately one Btu. AFUE The AFUE, or Annualized Fuel Utilization Efficiency, is the ratio of the total useful heat the gas furnace delivers to the house to the heat value of the fuel it consumes. Heat Pump A heat pump is basically an air conditioner with a reversible valve

295

Kitchen Ventilation Should be High Performance (Not Optional)  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Kitchen Ventilation Kitchen Ventilation Should be High Performance (not Optional) Brett C. Singer Residential Building Systems & Indoor Environment Groups Lawrence Berkeley National Laboratory Building America Technical Update Denver, CO April 30, 2013 Acknowledgements PROGRAM SUPPORT *U.S. Department of Energy - Building America Program *U.S. Environmental Protection Agency - Indoor Environments Division *U.S. Department of Housing and Urban Development - Office of Healthy Homes & Lead Hazard Control *California Energy Commission - Public Interest Energy Research Program TECHNICAL CONTRIBUTIONS *Woody Delp, Tosh Hotchi, Melissa Lunden, Nasim Mullen, Chris Stratton, Doug Sullivan, Iain Walker Kitchen Ventilation Simplified PROBLEM: * Cooking burners & cooking produce odors, moisture

296

Sensor-based demand controlled ventilation  

SciTech Connect

In most buildings, occupancy and indoor pollutant emission rates vary with time. With sensor-based demand-controlled ventilation (SBDCV), the rate of ventilation (i.e., rate of outside air supply) also varies with time to compensate for the changes in pollutant generation. In other words, SBDCV involves the application of sensing, feedback and control to modulate ventilation. Compared to ventilation without feedback, SBDCV offers two potential advantages: (1) better control of indoor pollutant concentrations; and (2) lower energy use and peak energy demand. SBDCV has the potential to improve indoor air quality by increasing the rate of ventilation when indoor pollutant generation rates are high and occupants are present. SBDCV can also save energy by decreasing the rate of ventilation when indoor pollutant generation rates are low or occupants are absent. After providing background information on indoor air quality and ventilation, this report provides a relatively comprehensive discussion of SBDCV. Topics covered in the report include basic principles of SBDCV, sensor technologies, technologies for controlling air flow rates, case studies of SBDCV, application of SBDCV to laboratory buildings, and research needs. SBDCV appears to be an increasingly attractive technology option. Based on the review of literature and theoretical considerations, the application of SBDCV has the potential to be cost-effective in applications with the following characteristics: (a) a single or small number of dominant pollutants, so that ventilation sufficient to control the concentration of the dominant pollutants provides effective control of all other pollutants; (b) large buildings or rooms with unpredictable temporally variable occupancy or pollutant emission; and (c) climates with high heating or cooling loads or locations with expensive energy.

De Almeida, A.T. [Universidade de Coimbra (Portugal). Dep. Eng. Electrotecnica; Fisk, W.J. [Lawrence Berkeley National Lab., CA (United States)

1997-07-01T23:59:59.000Z

297

Solar ventilation preheating: FEMP fact sheet  

DOE Green Energy (OSTI)

Installing a ''solar wall'' to heat air before it enters a building, called solar ventilation preheating, is one of the most efficient ways of reducing energy costs using clean and renewable energy. A solar wall can be designed as an integral part of a new building or it can be added in a retrofit project.

Clyne, R.

1999-09-30T23:59:59.000Z

298

Energy Basics: Home and Building Technologies  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

Home and Building Technologies Homes and other buildings use energy every day for space heating and cooling, for lighting and hot water, and for appliances and electronics. Today's...

299

DOE Seeks Commercial Storage to Complete Fill of Northeast Home...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

DOE Seeks Commercial Storage to Complete Fill of Northeast Home Heating Oil Reserve DOE Seeks Commercial Storage to Complete Fill of Northeast Home Heating Oil Reserve August 26,...

300

Experimental Evaluation of a Downsized Residential Air Distribution System: Comfort and Ventilation Effectiveness  

SciTech Connect

Good air mixing not only improves thermal comfort Human thermal comfort is the state of mind that expresses satisfaction with the surrounding environment, according to ASHRAE Standard 55. Achieving thermal comfort for most occupants of buildings or other enclosures is a goal of HVAC design engineers. but also enhances ventilation effectiveness by inducing uniform supply-air diffusion. In general, the performance of an air distribution system in terms of comfort and ventilation effectiveness is influenced by the supply air temperature, velocity, and flow rate, all of which are in part dictated by the HVAC (Heating Ventilation Air Conditioning) In the home or small office with a handful of computers, HVAC is more for human comfort than the machines. In large datacenters, a humidity-free room with a steady, cool temperature is essential for the trouble-free system as well as the thermal load attributes. Any potential deficiencies associated with these design variables can be further exacerbated by an improper proximity of the supply and return outlets with respect to the thermal and geometrical characteristics of the indoor space. For high-performance houses, the factors influencing air distribution performance take on an even greater significance because of a reduced supply-air design flow rate resulting from downsized HVAC systems.

Jalalzadeh-Azar, A. A.

2007-01-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


301

Particle deposition in ventilation ducts  

SciTech Connect

Exposure to airborne particles is detrimental to human health and indoor exposures dominate total exposures for most people. The accidental or intentional release of aerosolized chemical and biological agents within or near a building can lead to exposures of building occupants to hazardous agents and costly building remediation. Particle deposition in heating, ventilation and air-conditioning (HVAC) systems may significantly influence exposures to particles indoors, diminish HVAC performance and lead to secondary pollutant release within buildings. This dissertation advances the understanding of particle behavior in HVAC systems and the fates of indoor particles by means of experiments and modeling. Laboratory experiments were conducted to quantify particle deposition rates in horizontal ventilation ducts using real HVAC materials. Particle deposition experiments were conducted in steel and internally insulated ducts at air speeds typically found in ventilation ducts, 2-9 m/s. Behaviors of monodisperse particles with diameters in the size range 1-16 {micro}m were investigated. Deposition rates were measured in straight ducts with a fully developed turbulent flow profile, straight ducts with a developing turbulent flow profile, in duct bends and at S-connector pieces located at duct junctions. In straight ducts with fully developed turbulence, experiments showed deposition rates to be highest at duct floors, intermediate at duct walls, and lowest at duct ceilings. Deposition rates to a given surface increased with an increase in particle size or air speed. Deposition was much higher in internally insulated ducts than in uninsulated steel ducts. In most cases, deposition in straight ducts with developing turbulence, in duct bends and at S-connectors at duct junctions was higher than in straight ducts with fully developed turbulence. Measured deposition rates were generally higher than predicted by published models. A model incorporating empirical equations based on the experimental measurements was applied to evaluate particle losses in supply and return duct runs. Model results suggest that duct losses are negligible for particle sizes less than 1 {micro}m and complete for particle sizes greater than 50 {micro}m. Deposition to insulated ducts, horizontal duct floors and bends are predicted to control losses in duct systems. When combined with models for HVAC filtration and deposition to indoor surfaces to predict the ultimate fates of particles within buildings, these results suggest that ventilation ducts play only a small role in determining indoor particle concentrations, especially when HVAC filtration is present. However, the measured and modeled particle deposition rates are expected to be important for ventilation system contamination.

Sippola, Mark R.

2002-09-01T23:59:59.000Z

302

Residential Ventilation & Energy  

NLE Websites -- All DOE Office Websites (Extended Search)

5 5 Residential Ventilation & Energy Figure 1: Annual Average Ventilation Costs of the Current U.S. Single-Family Housing Stock ($/year/house). Infiltration and ventilation in dwellings is conventionally believed to account for one-third to one-half of space conditioning energy. Unfortunately, there is not a great deal of measurement data or analysis to substantiate this assumption. As energy conservation improvements to the thermal envelope continue, the fraction of energy consumed by the conditioning of air may increase. Air-tightening programs, while decreasing energy requirements, have the tendency to decrease ventilation and its associated energy penalty at the possible expense of adequate indoor air quality. Therefore, more energy may be spent on conditioning air.

303

Ventilation | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

(often required by building codes) will help to reduce your use of air conditioning, and attic fans may also help keep cooling costs down. Learn More Whole-House Ventilation...

304

WASTE TREATMENT BUILDING VENTILATION SYSTEM DESCRIPTION DOCUMENT  

SciTech Connect

The Waste Treatment Building Ventilation System provides heating, ventilation, and air conditioning (HVAC) for the contaminated, potentially contaminated, and uncontaminated areas of the Monitored Geologic Repository's (MGR) Waste Treatment Building (WTB). In the uncontaminated areas, the non-confinement area ventilation system maintains the proper environmental conditions for equipment operation and personnel comfort. In the contaminated and potentially contaminated areas, in addition to maintaining the proper environmental conditions for personnel comfort and equipment operation, the contamination confinement area ventilation system directs potentially contaminated air away from personnel in the WTB and confines the contamination within high-efficiency particulate air (HEPA) filtration units. The contamination confinement area ventilation system creates airflow paths and pressure zones to minimize the potential for spreading contamination with the building. The contamination confinement ventilation system also protects the environment and the public by limiting airborne releases of radioactive or other hazardous contaminants from the WTB. The Waste Treatment Building Ventilation System confines the radioactive and hazardous material within the building such that the release rates comply with regulatory limits, The system design, operations, and maintenance activities incorporate ALARA (as low as is reasonably achievable) principles to maintain personnel radiation doses to all occupational workers below regulatory limits and as low as is reasonably achievable. The system provides status of important system parameters and equipment operation, and provides audible and/or visual indication of off-normal conditions and equipment failures. The Waste Treatment Building Ventilation System interfaces with the Waste Treatment Building System by being located in the WTB, and by maintaining specific pressure, temperature, and humidity environments within the building. The system also depends on the WTB for normal electric power supply and the required supply of water for heating, cooling, and humidification. Interface with the Waste Treatment Building System includes the WTB fire protection subsystem for detection of fire and smoke. The Waste Treatment Building Ventilation System interfaces with the Site Radiological Monitoring System for continuous monitoring of the exhaust air and key areas within the WTB, the Monitored Geologic Repository Operations Monitoring and Control System for monitoring and control of system operations, and the Site Generated Radiological Waste Handling System and Site Generated Hazardous, Non-Hazardous & Sanitary Waste Disposal System for routing of pretreated toxic, corrosive, and radiologically contaminated effluent from process equipment to the HEPA filter exhaust ductwork and air-cleaning unit.

P.A. Kumar

2000-06-22T23:59:59.000Z

305

Energy Basics: Radiant Heating  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

low heat capacity and have the quickest response time of any heating technology. More Information Visit the Energy Saver website for more information about radiant heating in homes...

306

Dehumidification and cooling loads from ventilation air  

SciTech Connect

The importance of controlling humidity in buildings is cause for concern, in part, because of indoor air quality problems associated with excess moisture in air-conditioning systems. But more universally, the need for ventilation air has forced HVAC equipment (originally optimized for high efficiency in removing sensible heat loads) to remove high moisture loads. To assist cooling equipment and meet the challenge of larger ventilation loads, several technologies have succeeded in commercial buildings. Newer technologies such as subcool/reheat and heat pipe reheat show promise. These increase latent capacity of cooling-based systems by reducing their sensible capacity. Also, desiccant wheels have traditionally provided deeper-drying capacity by using thermal energy in place of electrical power to remove the latent load. Regardless of what mix of technologies is best for a particular application, there is a need for a more effective way of thinking about the cooling loads created by ventilation air. It is clear from the literature that all-too-frequently, HVAC systems do not perform well unless the ventilation air loads have been effectively addressed at the original design stage. This article proposes an engineering shorthand, an annual load index for ventilation air. This index will aid in the complex process of improving the ability of HVAC systems to deal efficiently with the amount of fresh air the industry has deemed useful for maintaining comfort in buildings. Examination of typical behavior of weather shows that latent loads usually exceed sensible loads in ventilation air by at least 3:1 and often as much as 8:1. A designer can use the engineering shorthand indexes presented to quickly assess the importance of this fact for a given system design. To size those components after they are selected, the designer can refer to Chapter 24 of the 1997 ASHRAE Handbook--Fundamentals, which includes separate values for peak moisture and peak temperature.

Harriman, L.G. III [Mason-Grant, Portsmouth, NH (United States); Plager, D. [Quantitative Decision Support, Portsmouth, NH (United States); Kosar, D. [Gas Research Inst., Chicago, IL (United States)

1997-11-01T23:59:59.000Z

307

Passive Solar Home Design | Department of Energy  

NLE Websites -- All DOE Office Websites (Extended Search)

Passive Solar Home Design Passive Solar Home Design June 24, 2013 - 7:18pm Addthis This North Carolina home gets most of its space heating from the passive solar design, but the...

308

Home Energy Rebate Option (HERO) - Existing Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Home Energy Rebate Option (HERO) - Existing Homes Program Home Energy Rebate Option (HERO) - Existing Homes Program < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Maximum Rebate $3,000 Program Info Funding Source American Recovery and Reinvestment Act Expiration Date 06/11/2013 State Louisiana Program Type State Rebate Program Rebate Amount 20% of improvement costs Provider Louisiana Department of Natural Resources '''''NOTE: All HERO program funding has been allocated as of December 6, 2012. Important dates related to the closure of the program have been announced. Please see summary below for more information. '''''

309

FEMP-FS--Solar Ventilation Preheating  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Installing a "solar wall" to heat air before it enters a Installing a "solar wall" to heat air before it enters a building, called solar ventilation preheating, is one of the most efficient ways of reducing energy costs using clean and renewable energy. The system works by heating outside air with a south-facing solar collector-a dark-colored wall made of sheet metal and perforated with tiny holes. Outdoor air is drawn through the holes and heated as it absorbs the wall's warmth. The warm air rises in the space between the solar wall and the building wall and is moved into the air-duct system, usually by means of a fan, to heat the building. Any additional heating needed at night or on cloudy days is supplied by the build- ing's conventional heating system. During summer months, intake air bypasses the solar collector,

310

Summary of human responses to ventilation  

E-Print Network (OSTI)

low ventilation rates and increase in health problems:rate. As ventilation rates increase, benefits gained fordetermined that increases in ventilation rates above 10 Ls -

Seppanen, Olli A.; Fisk, William J.

2004-01-01T23:59:59.000Z

311

Design methods for displacement ventilation: Critical review.  

E-Print Network (OSTI)

Displacement Ventilation. ASHRAE Research project-RP-949.displacement ventilation. ASHRAE Transaction, 96 (1). Ar ???due to displacement ventilation. ASHRAE Transaction, 96 (1).

Schiavon, Stefano

2006-01-01T23:59:59.000Z

312

Infiltration in ASHRAE's Residential Ventilation Standards  

E-Print Network (OSTI)

Related to Residential Ventilation Requirements. Rudd, A. 2005. Review of Residential Ventilationand Matson N.E. , Residential Ventilation and Energy

Sherman, Max

2008-01-01T23:59:59.000Z

313

Home Energy Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Energy Loan Program Home Energy Loan Program Home Energy Loan Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Cooling Appliances & Electronics Other Heat Pumps Commercial Lighting Lighting Water Heating Windows, Doors, & Skylights Solar Buying & Making Electricity Maximum Rebate $6,000 from LA DNR Program Info State Louisiana Program Type State Loan Program Rebate Amount 50% of loan amount subsidized by LA DNR Provider Louisiana Department of Natural Resources The Home Energy Loan Program (HELP), administered by the Louisiana Department of Natural Resources (DNR), allows homeowners to get a five-year loan to improve the energy efficiency of their existing home. DNR

314

Energy and air quality implications of passive stack ventilation in residential buildings  

SciTech Connect

Ventilation requires energy to transport and condition the incoming air. The energy consumption for ventilation in residential buildings depends on the ventilation rate required to maintain an acceptable indoor air quality. Historically, U.S. residential buildings relied on natural infiltration to provide sufficient ventilation, but as homes get tighter, designed ventilation systems are more frequently required particularly for new energy efficient homes and retrofitted homes. ASHRAE Standard 62.2 is used to specify the minimum ventilation rate required in residential buildings and compliance is normally achieved with fully mechanical whole-house systems; however, alternative methods may be used to provide the required ventilation when their air quality equivalency has been proven. One appealing method is the use of passive stack ventilation systems. They have been used for centuries to ventilate buildings and are often used in ventilation regulations in other countries. Passive stacks are appealing because they require no fans or electrical supply (which could lead to lower cost) and do not require maintenance (thus being more robust and reliable). The downside to passive stacks is that there is little control of ventilation air flow rates because they rely on stack and wind effects that depend on local time-varying weather. In this study we looked at how passive stacks might be used in different California climates and investigated control methods that can be used to optimize indoor air quality and energy use. The results showed that passive stacks can be used to provide acceptable indoor air quality per ASHRAE 62.2 with the potential to save energy provided that they are sized appropriately and flow controllers are used to limit over-ventilation.

Mortensen, Dorthe Kragsig; Walker, Iain S.; Sherman, Max

2011-01-01T23:59:59.000Z

315

WASTE HANDLING BUILDING VENTILATION SYSTEM DESCRIPTION DOCUMENT  

SciTech Connect

The Waste Handling Building Ventilation System provides heating, ventilation, and air conditioning (HVAC) for the contaminated, potentially contaminated, and uncontaminated areas of the Monitored Geologic Repository's (MGR) Waste Handling Building (WHB). In the uncontaminated areas, the non-confinement area ventilation system maintains the proper environmental conditions for equipment operation and personnel comfort. In the contaminated and potentially contaminated areas, in addition to maintaining the proper environmental conditions for equipment operation and personnel comfort, the contamination confinement area ventilation system directs potentially contaminated air away from personnel in the WHB and confines the contamination within high-efficiency particulate air (HEPA) filtration units. The contamination confinement areas ventilation system creates airflow paths and pressure zones to minimize the potential for spreading contamination within the building. The contamination confinement ventilation system also protects the environment and the public by limiting airborne releases of radioactive or other hazardous contaminants from the WHB. The Waste Handling Building Ventilation System is designed to perform its safety functions under accident conditions and other Design Basis Events (DBEs) (such as earthquakes, tornadoes, fires, and loss of the primary electric power). Additional system design features (such as compartmentalization with independent subsystems) limit the potential for cross-contamination within the WHB. The system provides status of important system parameters and equipment operation, and provides audible and/or visual indication of off-normal conditions and equipment failures. The Waste Handling Building Ventilation System confines the radioactive and hazardous material within the building such that the release rates comply with regulatory limits. The system design, operations, and maintenance activities incorporate ALARA (as low as is reasonably achievable) principles to maintain personnel radiation doses to all occupational workers below regulatory limits and as low as is reasonably achievable. The Waste Handling Building Ventilation System interfaces with the Waste Handling Building System by being located within the WHB and by maintaining specific pressures, temperatures, and humidity within the building. The system also depends on the WHB for water supply. The system interfaces with the Site Radiological Monitoring System for continuous monitoring of the exhaust air; the Waste Handling Building Fire Protection System for detection of fire and smoke; the Waste Handling Building Electrical System for normal, emergency, and standby power; and the Monitored Geologic Repository Operations Monitoring and Control System for monitoring and control of the system.

P.A. Kumar

2000-06-21T23:59:59.000Z

316

Redding Electric - Residential and Commercial Energy Efficiency...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Savings For Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Other Ventilation Manufacturing Heat Pumps...

317

Texas-New Mexico Power Company - Residential Energy Efficiency...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Residential Savings For Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Other Sealing Your Home Ventilation Heat...

318

Tax Credits, Rebates & Savings | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Heating & Cooling Commercial Heating & Cooling Heat...

319

Cleco Power - Power Miser New Home Program (Louisiana) | Open...  

Open Energy Info (EERE)

Air sealing, Furnaces, Heat pumps, Water Heaters, Windows, Ventilation, Kitchen and Laundry Equipment Active Incentive Yes Implementing Sector Utility Energy Category Energy...

320

Performance of Home Smoke Alarms  

Science Conference Proceedings (OSTI)

... 72 Figure 86. Heating ignition source with cooking oil . ... Estimated particle size from cooking oil fire scenario . . ... Performance of Home Smoke Alarms ...

2012-10-15T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


321

Solar Hot Water for Your Home  

DOE Green Energy (OSTI)

A brochure describing the cost-saving and energy-saving benefits of using solar heated water in your home.

American Solar Energy Society

2001-06-19T23:59:59.000Z

322

Energy Basics: Ventilation Systems  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

building through the roof, walls, and windows. Heat-reflecting roofs, insulation, and energy efficient windows will help to reduce that heat conduction. Radiation is heat...

323

Measuring Residential Ventilation  

NLE Websites -- All DOE Office Websites (Extended Search)

Measuring Residential Ventilation Measuring Residential Ventilation System Airflows: Part 2 - Field Evaluation of Airflow Meter Devices and System Flow Verification J. Chris Stratton, Iain S. Walker, Craig P. Wray Environmental Energy Technologies Division October 2012 LBNL-5982E 2 Disclaimer This document was prepared as an account of work sponsored by the United States Government. While this document is believed to contain correct information, neither the United States Government nor any agency thereof, nor the Regents of the University of California, nor any of their employees, makes any warranty, express or implied, or assumes any legal responsibility for the accuracy, completeness, or usefulness of any

324

International Energy Agency Building Energy Simulation Test and Diagnostic Method for Heating, Ventilating, and Air-Conditioning Equipment Models (HVAC BESTEST): Volume 2: Cases E300-E545.  

DOE Green Energy (OSTI)

This report documents an additional set of mechanical system test cases that are planned for inclusion in ANSI/ASHRAE STANDARD 140. The cases test a program's modeling capabilities on the working-fluid side of the coil, but in an hourly dynamic context over an expanded range of performance conditions. These cases help to scale the significance of disagreements that are less obvious in the steady-state cases. The report is Vol. 2 of HVAC BESTEST Volume 1. Volume 1 was limited to steady-state test cases that could be solved with analytical solutions. Volume 2 includes hourly dynamic effects, and other cases that cannot be solved analytically. NREL conducted this work in collaboration with the Tool Evaluation and Improvement Experts Group under the International Energy Agency (IEA) Solar Heating and Cooling Programme Task 22.

Neymark J.; Judkoff, R.

2004-12-01T23:59:59.000Z

325

Procedures and Standards for Residential Ventilation System Commissioning:  

NLE Websites -- All DOE Office Websites (Extended Search)

Procedures and Standards for Residential Ventilation System Commissioning: Procedures and Standards for Residential Ventilation System Commissioning: An Annotated Bibliography Title Procedures and Standards for Residential Ventilation System Commissioning: An Annotated Bibliography Publication Type Report LBNL Report Number LBNL-6142E Year of Publication 2013 Authors J. Chris Stratton, and Craig P. Wray Keywords ASHRAE 62.2, commissioning, procedures, residential, standards, ventilation Abstract Beginning with the 2008 version of Title 24, new homes in California must comply with ANSI/ASHRAE Standard 62.2-2007 requirements for residential ventilation. Where installed, the limited data available indicate that mechanical ventilation systems do not always perform optimally or even as many codes and forecasts predict. Commissioning such systems when they are installed or during subsequent building retrofits is a step towards eliminating deficiencies and optimizing the tradeoff between energy use and acceptable IAQ. Work funded by the California Energy Commission about a decade ago at Berkeley Lab documented procedures for residential commissioning, but did not focus on ventilation systems. Since then, standards and approaches for commissioning ventilation systems have been an active area of work in Europe. This report describes our efforts to collect new literature on commissioning procedures and to identify information that can be used to support the future development of residential-ventilation-specific procedures and standards. We recommend that a standardized commissioning process and a commissioning guide for practitioners be developed, along with a combined energy and IAQ benefit assessment standard and tool, and a diagnostic guide for estimating continuous pollutant emission rates of concern in residences (including a database that lists emission test data for commercially-available labeled products).

326

Demonstration and Performance Monitoring of Foundation Heat Exchangers (FHX) in Ultra-High Energy Efficient Research Homes  

DOE Green Energy (OSTI)

The more widespread use of Ground Source Heat Pump (GSHP) systems has been hindered by their high first cost, which is mainly driven by the cost of the drilling and excavation for installation of ground heat exchangers (GHXs). A new foundation heat exchanger (FHX) technology was proposed to reduce first cost by placing the heat exchanger into the excavations made during the course of construction (e.g., the overcut for the basement and/or foundation and run-outs for water supply and the septic field). Since they reduce or eliminate the need for additional drilling or excavation, foundation heat exchangers have the potential to significantly reduce or eliminate the first cost premium associated with GSHPs. Since December 2009, this FHX technology has been demonstrated in two ultra-high energy efficient new research houses in the Tennessee Valley, and the performance data has been closely monitored as well. This paper introduces the FHX technology with the design, construction and demonstration of the FHX and presents performance monitoring results of the FHX after one year of monitoring. The performance monitoring includes hourly maximum and minimum entering water temperature (EWT) in the FHX compared with the typical design range, temperature difference (i.e., T) across the FHX, and hourly heat transfer rate to/from the surrounding soil.

Im, Piljae [ORNL; Hughes, Patrick [ORNL; Liu, Xiaobing [ORNL

2012-01-01T23:59:59.000Z

327

Building America Top Innovations Hall of Fame Profile … Low-Cost Ventilation in Production Housing  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

simple, cost-effective techniques for providing fresh air throughout the home, including exhaust-only and central fan-integrated supply ventilation. Building America has refined simple whole-house ventilation systems that cost less than $350 to install. BUILDING AMERICA TOP INNOVATIONS HALL OF FAME PROFILE INNOVATIONS CATEGORY: 1. Advanced Technologies and Practices 1.3 Assured Health, Safety, and Durability Low-Cost Ventilation in Production Housing As high-performance homes get more air-tight and better insulated, attention to good indoor air quality becomes essential. Building America has effectively guided the nation's home builders to embrace whole-house ventilation by developing low-cost options that adapt well to their production processes. When the U.S. Department of Energy's Building America research teams began

328

Track B - Critical Guidance for Peak Performance Homes | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Track B - Critical Guidance for Peak Performance Homes Track B - Critical Guidance for Peak Performance Homes Track B - Critical Guidance for Peak Performance Homes Presentations from Track B, Critical Guidance for Peak Performance Homes of the U.S. Department of Energy Building America program's 2012 Residential Energy Efficiency Stakeholder Meeting are provided below as Adobe Acrobat PDFs. These presentations for this track covered the following topics: Ventilation Strategies in High Performance Homes; Combustion Safety in Tight Houses; Implementation Program Case Studies; Field Testing from Start to Finish; and Humidity Control and Analysis. why_we_ventilate.pdf formaldehyde_new_homes.pdf whole_bldg_ventilation.pdf combustion_safety_codes.pdf combustion_diagnostics.pdf test_protocols_results.pdf utility_incentive_programs.pdf

329

DOE Responses to DOE Challenge Home (formerly Builders Challenge...  

NLE Websites -- All DOE Office Websites (Extended Search)

- Cold Climate Specs For the colder climate zones (6- 8), commenters felt that the Target Home ventilation spec should be the same as the other climate zones, and also have caps on...

330

Low income home energy assistance  

Science Conference Proceedings (OSTI)

The Low Income Home Energy Assistance Program provides eligible households with assistance for home energy costs. Assistance is available to (1) help families pay heating and cooling costs, (2) prevent energy cutoff in crisis situations, and (3) help families make their homes more energy efficient. This report provides background information on the program in preparation for the program's reauthorization in 1990.

Not Available

1990-10-01T23:59:59.000Z

331

BCP Home  

NLE Websites -- All DOE Office Websites (Extended Search)

Boulder Canyon Project Remarketing Effort HOME Home Page Image WELCOME Boulder Canyon Information Module Federal Register Notices Public Forums Correspondence and Presentations...

332

Meeting Residential Ventilation Standards Through Dynamic Control of Ventilation Systems  

E-Print Network (OSTI)

increased cost per unit of energy at times of peak demandminimizing energy costs and operation during peak timesenergy and cost impacts of ventilation vary with weather and time

Sherman, Max H.

2011-01-01T23:59:59.000Z

333

Cullman Electric Cooperative - Energy Efficient Homes Program | Department  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Cullman Electric Cooperative - Energy Efficient Homes Program Cullman Electric Cooperative - Energy Efficient Homes Program Cullman Electric Cooperative - Energy Efficient Homes Program < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Appliances & Electronics Water Heating Program Info State Alabama Program Type Utility Rebate Program Rebate Amount Energy Efficient Home: $200 Energy Efficient Water Heater: $100 Cullman Electric Cooperative offers rebates to residential customers that make certain energy efficiency improvements to newly constructed, all electric homes. Up to $200 is available per home. Qualifying homes must have electric water heatng, clothes drying, cooking, and a heat pump. A

334

Air Distribution Effectiveness for Different MechanicalVentilation Systems  

SciTech Connect

The purpose of ventilation is to dilute indoor contaminants that an occupant is exposed to. In a multi-zone environment such as a house, there will be different dilution rates and different source strengths in every zone. Most US homes have central HVAC systems, which tend to mix conditions between zones. Different types of ventilation systems will provide different amounts of dilution depending on the effectiveness of their air distribution systems and the location of sources and occupants. This paper will report on work being done to both model the impact of different systems and measurements using a new multi-tracer measurement system that has the capacity to measure not only the flow of outdoor air to each zone, but zone-to-zone transport. The ultimate objective of this project is to determine the effectiveness of different systems so that appropriate adjustments can be made in residential ventilation standards such as ASHRAE Standard 62.2.

Sherman, Max H.; Walker, Iain S.

2007-08-01T23:59:59.000Z

335

Assessment of Indoor Air Quality Benefits and Energy Costs of Mechanical Ventilation  

Science Conference Proceedings (OSTI)

Intake of chemical air pollutants in residences represents an important and substantial health hazard. Sealing homes to reduce air infiltration can save space conditioning energy, but can also increase indoor pollutant concentrations. Mechanical ventilation ensures a minimum amount of outdoor airflow that helps reduce concentrations of indoor emitted pollutants while requiring some energy for fan(s) and thermal conditioning of the added airflow. This work demonstrates a physics based, data driven modeling framework for comparing the costs and benefits of whole-house mechanical ventilation and applied the framework to new California homes. The results indicate that, on a population basis, the health benefits from reduced exposure to indoor pollutants in New California homes are worth the energy costs of adding mechanical ventilation as specified by ASHRAE Standard 62.2.This study determines the health burden for a subset of pollutants in indoor air and the costs and benefits of ASHRAE's mechanical ventilation standard (62.2) for new California homes. Results indicate that, on a population basis, the health benefits of new home mechanical ventilation justify the energy costs.

Logue, J.M.; Price, P.N.; Sherman, M.H.; Singer, B.C.

2011-07-01T23:59:59.000Z

336

Tax Credits, Rebates & Savings | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

& Cooling Heating Home Weatherization Commercial Weatherization Sealing Your Home Cooling Appliances & Electronics Ventilation Commercial Lighting Lighting Water Heating Windows,...

337

Measured Air Distribution Effectiveness for Residential Mechanical Ventilation Systems  

SciTech Connect

The purpose of ventilation is dilute or remove indoor contaminants that an occupant is exposed to. In a multi-zone environment such as a house, there will be different dilution rates and different source strengths in every zone. Most US homes have central HVAC systems, which tend to mix the air thus the indoor conditions between zones. Different types of ventilation systems will provide different amounts of exposure depending on the effectiveness of their air distribution systems and the location of sources and occupants. This paper will report on field measurements using a unique multi-tracer measurement system that has the capacity to measure not only the flow of outdoor air to each zone, but zone-to-zone transport. The paper will derive seven different metrics for the evaluation of air distribution. Measured data from two homes with different levels of natural infiltration will be used to evaluate these metrics for three different ASHRAE Standard 62.2 compliant ventilation systems. Such information can be used to determine the effectiveness of different systems so that appropriate adjustments can be made in residential ventilation standards such as ASHRAE Standard 62.2.

Sherman, Max; Sherman, Max H.; Walker, Iain S.

2008-05-01T23:59:59.000Z

338

Diverse Power - Energy Efficient Existing Homes Rebate Program (Georgia) |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Existing Homes Rebate Program Existing Homes Rebate Program (Georgia) Diverse Power - Energy Efficient Existing Homes Rebate Program (Georgia) < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Heat Pumps Heating Appliances & Electronics Water Heating Program Info State Georgia Program Type Utility Rebate Program Rebate Amount Electric Heat Pump: $100/system Gas to Electric Heat Pump Switch: $300 Dual Fuel Heat Pump: $250/system Geothermal Heat Pump: $250/ton Electric Water Heaters: $75 - $150/unit Gas to Electric Water Heater Switch: $300 - $500 Waste Heat Recovery Unit: $250/house Provider Diverse Power Diverse Power is a member-owned electric cooperative that provides electric

339

Imagine Homes New Construction Occupied Test House  

SciTech Connect

This report summarizes the research findings of a long-term monitoring plan to evaluate the performance of an energy-efficient home constructed in 2010 in San Antonio, Texas. Monitoring of the energy use, energy generation, and temperature conditions for this project occurred between July 2010 and October 2011. The heating, ventilation, and air conditioning system effectively maintained acceptable temperatures and humidity levels in peak cooling and heating and non-peak operating periods. Discrepancies were found between modeled and actual energy use values, with actual space cooling energy use closest to the corresponding modeled value. Energy consumption predicted for lighting, appliances, and miscellaneous electrical loads was significantly higher than measured amounts, and energy consumption predicted for cooling was significantly lower than measured amounts. A high amount of the 1,600 kWh of PV-generated electricity produced annually was sent to the electric grid every month. The solar thermal DHW system was the main source of hot water for most of the year and performed well; during summer, electrical use by the backup system was rare.

Stecher, D.; Rapport, A.; Allison, K.

2013-07-01T23:59:59.000Z

340

Ventilation and Work Performance in Office Work  

E-Print Network (OSTI)

A). When ventilation rate increases from V to V\\, the ratiowork when ventilation rates increase. Field studies withper 10 L/s person increase in ventilation rate and relative

Seppanen, Olli; Fisk, William J.; Lei, Q.H.

2005-01-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


341

Commissioning Residential Ventilation Systems: A Combined Assessment of  

NLE Websites -- All DOE Office Websites (Extended Search)

Commissioning Residential Ventilation Systems: A Combined Assessment of Commissioning Residential Ventilation Systems: A Combined Assessment of Energy and Air Quality Potential Values Title Commissioning Residential Ventilation Systems: A Combined Assessment of Energy and Air Quality Potential Values Publication Type Report LBNL Report Number LBNL-5969E Year of Publication 2012 Authors Turner, William J. N., Jennifer M. Logue, and Craig P. Wray Date Published 07/2012 Keywords commissioning, energy, health, indoor air quality, residential, valuation, ventilation Abstract Due to changes in building codes, whole-house mechanical ventilation systems are being installed in new California homes. Few measurements are available, but the limited data suggest that these systems don't always perform as code and forecasts predict. Such deficiencies occur because systems are usually field assembled without design specifications, and there is no consistent process to identify and correct problems. The value of such activities in terms of reducing energy use and improving indoor air quality (IAQ) is poorly understood. Commissioning such systems when they are installed or during subsequent building retrofits is a step towards eliminating deficiencies and optimizing the tradeoff between energy use and IAQ.

342

Ventilation Behavior and Household Characteristics in NewCalifornia Houses  

SciTech Connect

A survey was conducted to determine occupant use of windows and mechanical ventilation devices; barriers that inhibit their use; satisfaction with indoor air quality (IAQ); and the relationship between these factors. A questionnaire was mailed to a stratified random sample of 4,972 single-family detached homes built in 2003, and 1,448 responses were received. A convenience sample of 230 houses known to have mechanical ventilation systems resulted in another 67 completed interviews. Some results are: (1) Many houses are under-ventilated: depending on season, only 10-50% of houses meet the standard recommendation of 0.35 air changes per hour. (2) Local exhaust fans are under-utilized. For instance, about 30% of households rarely or never use their bathroom fan. (3) More than 95% of households report that indoor air quality is ''very'' or ''somewhat'' acceptable, although about 1/3 of households also report dustiness, dry air, or stagnant or humid air. (4) Except households where people cook several hours per week, there is no evidence that households with significant indoor pollutant sources get more ventilation. (5) Except households containing asthmatics, there is no evidence that health issues motivate ventilation behavior. (6) Security and energy saving are the two main reasons people close windows or keep them closed.

Price, Phillip N.; Sherman, Max H.

2006-02-01T23:59:59.000Z

343

RESIDENTIAL VENTILATION AND ENERGY CHARACTERISTICS*  

E-Print Network (OSTI)

while still providing ventilation for adequate indoor air quality. Various ASHRAE Standards (e.g., 62 to the ASHRAE Standard 119 levels while still providing adequate ventilation through infiltration or mechanical alternatives. Various ASHRAE Standards are used to assist us. ASHRAE Standard 119-19885 classifies the envelope

344

VENTILATION (HVAC) FAILURE (BUILDING WIDE)  

E-Print Network (OSTI)

VENTILATION (HVAC) FAILURE (BUILDING WIDE) A failure or shutdown of the ventilation system will be signaled by cessation of the audible background "rumbling" sound of the building's HVAC system. As building durations. NOTE: Due to unpredictable pressure differentials in and around the labs during an HVAC failure

Strynadka, Natalie

345

Tax Credits, Rebates & Savings | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Your Home Heating & Cooling Commercial Heating & Cooling Cooling Design & Remodeling Windows, Doors, & Skylights Ventilation Heat Pumps Appliances & Electronics Water Heating...

346

Infiltration as ventilation: Weather-induced dilution  

NLE Websites -- All DOE Office Websites (Extended Search)

Infiltration as ventilation: Weather-induced dilution Title Infiltration as ventilation: Weather-induced dilution Publication Type Report LBNL Report Number LBNL-5795E Year of...

347

Equivalence in Ventilation and Indoor Air Quality  

NLE Websites -- All DOE Office Websites (Extended Search)

62) specify minimum ventilation rates without taking into account the impact of those rates on IAQ. Innovative ventilation management is often a desirable element of reducing...

348

Solar Ventilation Preheating Resources and Technologies | Department...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Ventilation Preheating Resources and Technologies Solar Ventilation Preheating Resources and Technologies October 7, 2013 - 11:50am Addthis Photo of a dark brown perforated metal...

349

Whole-House Ventilation | Department of Energy  

NLE Websites -- All DOE Office Websites (Extended Search)

air quality. There are four basic mechanical whole-house ventilation systems -- exhaust, supply, balanced, and energy recovery. Comparison of Whole-House Ventilation Systems...

350

Improving Ventilation and Saving Energy: Relocatable Classroom...  

NLE Websites -- All DOE Office Websites (Extended Search)

Improving Ventilation and Saving Energy: Relocatable Classroom Field Study Interim Report Title Improving Ventilation and Saving Energy: Relocatable Classroom Field Study Interim...

351

Development of a Residential Integrated Ventilation Controller  

E-Print Network (OSTI)

Passive Ventilation by Constant Area Vents to Maintain Indoor Air Quality in Houses. Passive Ventilation by Constant Area Vents to Maintain Indoor Air Quality in Houses."

Walker, Iain

2013-01-01T23:59:59.000Z

352

Why We Ventilate - Recent Advances  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

WHY WE VENTILATE: WHY WE VENTILATE: Recent Advances Max Sherman BA Stakeholders meeting ASHRAE BIO  Distinguished Lecturer  Exceptional Service Award  Board of Directors; TechC  Chair of committees:  62.2; Standards Committee  TC 4.3; TC 2.5  Holladay Distinguished Fellow OVERVIEW QUESTIONS  What is Ventilation? What is IAQ?  What functions does it provide?  How much do we need? Why?  How should ventilations standards be made? LBL has working on these problems Who Are You?  Engineers (ASHRAE Members & not);  architects,  contractors,  reps,  builders,  vendors,  code officials WHAT IS VENTILATION  Medicine: To Exchange Air In the Lungs  Latin: Ventilare, "to expose to the wind"  Today: To Bring In Outdoor Air And Replace

353

Innovative Energy Efficient Industrial Ventilation  

E-Print Network (OSTI)

This paper was written to describe an innovative on-demand industrial ventilation system for woodworking, metalworking, food processing, pharmaceutical, chemical, and other industries. Having analyzed existing industrial ventilation in 130 factories, we found striking dichotomy between the classical static design of ventilation systems and constantly changing workflow and business demands. Using data from real factories, we are able to prove that classical industrial ventilation design consumes 70 % more energy than necessary. Total potential electricity saving achieved by using on-demand systems instead of classically designed industrial ventilation in the U.S. could be 26 billion kWh. At the average electricity cost of 7 cents per kWh, this would represent $1.875 billion. Eighty such systems are already installed in the USA and European Union.

Litomisky, A.

2005-01-01T23:59:59.000Z

354

Passive Solar Home Design | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Passive Solar Home Design Passive Solar Home Design Passive Solar Home Design June 24, 2013 - 7:18pm Addthis This North Carolina home gets most of its space heating from the passive solar design, but the solar thermal system (top of roof) supplies both domestic hot water and a secondary radiant floor heating system. | Photo courtesy of Jim Schmid Photography. This North Carolina home gets most of its space heating from the passive solar design, but the solar thermal system (top of roof) supplies both domestic hot water and a secondary radiant floor heating system. | Photo courtesy of Jim Schmid Photography. What does this mean for me? A passive solar home means a comfortable home that gets at least part of its heating, cooling, and lighting energy from the sun. How does it work?

355

Operational test report integrated system test (ventilation upgrade)  

Science Conference Proceedings (OSTI)

Operational Final Test Report for Integrated Systems, Project W-030 (Phase 2 test, RECIRC and HIGH-HEAT Modes). Project W-030 provides a ventilation upgrade for the four Aging Waste Facility tanks, including upgraded vapor space cooling and filtered venting of tanks AY101, Ay102, AZ101, AZ102.

HARTY, W.M.

1999-10-05T23:59:59.000Z

356

Multifamily Home Energy Solutions Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Multifamily Home Energy Solutions Program Multifamily Home Energy Solutions Program < Back Eligibility Commercial Multi-Family Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Commercial Weatherization Appliances & Electronics Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Manufacturing Water Heating Program Info Funding Source Public Benefit Fund State Oregon Program Type State Rebate Program Rebate Amount Windows: $2-$3/sq ft, depending on U-value, glazing and type of heating Heat Pumps: $200 - $600, varies by efficiency and original heating type High-Efficiency Gas Boiler: $200 Gas Furnace: $150 Insulation: $0.30-$4 per square foot Exterior Doors: $25

357

Challenge Home  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

DOE Challenge Home DOE Challenge Home Sam Rashkin Building Technologies Office samuel.rashkin@ee.doe.gov/202-2897-1994 April 3, 2013 DOE Challenge Home: Leveraging Our Nation's Investment in High-Performance Home Innovations 2 | Building Technologies Office eere.energy.gov Purpose & Objectives Problem Statement: The U.S. Housing industry is extremely slow to adopt proven innovations from DOE's Building America program that provide compelling benefits to

358

Behavioral Perspectives on Home Energy Audits: The Role of Auditors, Labels, Reports, and Audit Tools on Homeowner Decision Making  

E-Print Network (OSTI)

data for homes using oil for heating was not oil, gas, and electricity as primary sources of heating my home. of homes that used fuel oil as a primary heating

Ingle, Aaron

2013-01-01T23:59:59.000Z

359

Ventilation in Multifamily Buildings  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

, 2011 , 2011 Ventilation in Multifamily Buildings Welcome to the Webinar! We will start at 2:00 PM Eastern Time Be sure that you are also dialed into the telephone conference call: Dial-in number: 888-324-9601; Pass code: 5551971 Download the presentation at: www.buildingamerica.gov/meetings.html Building Technologies Program eere.energy.gov Building America: Introduction November 1, 2011 Cheryn Engebrecht Cheryn.engebrecht@nrel.gov Building Technologies Program Building Technologies Program eere.energy.gov * Reduce energy use in new and existing residential buildings * Promote building science and systems engineering / integration approach * "Do no harm": Ensure safety, health and durability are maintained or improved * Accelerate adoption of high performance technologies

360

Positive Pressure Ventilation  

Science Conference Proceedings (OSTI)

... to the fire and can increase the rate of heat and energy being released. ... of vents open were altered to examine capability and optimization of each. ...

2013-07-16T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


361

Newer U.S. homes are 30% larger but consume about as much energy ...  

U.S. Energy Information Administration (EIA)

*Note: Averages for space heating and air conditioning reflect only those households that heated or cooled their homes in 2009.

362

Airflow Simulation and Energy Analysis in Ventilated Room with a New Type of Air Conditioning  

E-Print Network (OSTI)

Airflow simulation in one ventilated room with radiant heating and natural ventilation has been carried out. Three cases are compared: the closed room, the room with full openings, and the room with small openings. The radiator heating room with small openings is recommended. The airflow and thermal comfort are discussed for the last case. It is suitable for two kinds of civil buildings, housing buildings and office buildings, which take up the largest part of all functional buildings.

Liu, D.; Tang, G.; Zhao, F.

2006-01-01T23:59:59.000Z

363

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Tools of the Trade Tools of the Trade Clockwise: IR thermograph, IR camera, Air flow measurement, Blower door, Combustion test for water heater A hammer and a saw used to be the key tools for home contractors. Today, the best-in-breed also use high-tech equipment while performing a professional energy audit or verifying that construction has been done correctly. Infrared cameras can "see" heat loss and find hidden energy savings opportunities. PFT tests or blower door tests measure a homes air leakage and tell you when sealing has been successful. Combustion monitoring equipment and indoor-air pollution detectors ensure that a heating system is not only efficient but also not dumping dangerous pollutants into the home. All of these practices should be conducted with a

364

Does Mixing Make Residential Ventilation More Effective?  

E-Print Network (OSTI)

2009. ASHRAE Handbook of Fundamentals, Ventilation andleakage. The ASHRAE Handbook of fundamentals (ASHRAE 2009),

Sherman, Max

2011-01-01T23:59:59.000Z

365

TVA Partner Utilities - Energy Right New Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Right New Homes Program Right New Homes Program TVA Partner Utilities - Energy Right New Homes Program < Back Eligibility Construction Installer/Contractor Multi-Family Residential Residential Utility Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Heat Pumps Program Info State Kentucky Program Type Utility Rebate Program Rebate Amount Site Built New Homes Plan: $100-$800 depending on local power company and home efficiency Manufactured Home Heat Pump: $500 Provider Tennessee Valley Authority The Tennessee Valley Authority (TVA) ''energy right'' New Homes Plan provides incentives for all-electric, energy-efficient new homes by offering graduated rebates for new homes. Homes built at least 7% better

366

TVA Partner Utilities - Energy Right New Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

TVA Partner Utilities - Energy Right New Homes Program TVA Partner Utilities - Energy Right New Homes Program TVA Partner Utilities - Energy Right New Homes Program < Back Eligibility Construction Installer/Contractor Multi-Family Residential Residential Utility Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Heat Pumps Program Info State Georgia Program Type Utility Rebate Program Rebate Amount Site Built New Homes Plan: $100-$800 depending on local power company and home efficiency Manufactured Home Heat Pump: Up to $500 The Tennessee Valley Authority (TVA) energy right New Homes Plan provides incentives for all-electric, energy-efficient new homes by offering graduated rebates for new homes. Homes built at least 7% better than code

367

TVA Partner Utilities - Energy Right' New Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Right' New Homes Program Right&#039; New Homes Program TVA Partner Utilities - Energy Right' New Homes Program < Back Eligibility Construction Installer/Contractor Multi-Family Residential Residential Utility Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Heat Pumps Program Info State Mississippi Program Type Utility Rebate Program Rebate Amount Site Built New Homes Plan: $100-$800 depending on local power company and home efficiency Manufactured Home Heat Pump: Up to $500 Provider Tennessee Valley Authority The Tennessee Valley Authority (TVA) ''energy right'' New Homes Plan provides incentives for all-electric, energy-efficient new homes by offering graduated rebates for new homes. Homes built at least 7% better

368

DEMCO- Touchstone Energy Home Program  

Energy.gov (U.S. Department of Energy (DOE))

DEMCO, a Touchstone Energy Cooperative, provides residential customers who have a qualified Touchstone Energy Home, a rebate of up to $0.10 per square foot of living area for electric heat pumps...

369

Heating  

SciTech Connect

According to The Hydronics Institute, the surge in gas-fired boiler shipments brought about 3 years ago by high oil prices and the availability of natural gas after years of curtailment has almost competely subsided. Gas prices continue to escalate and the threat of decontrol by 1985 continues. Likewise, the Gas Appliance Manufacturers Association reports that shipments of gas-fired unit heaters, duct furnaces, and wall furnaces have also dropped as homeowners adopt a wait-and-see attitude toward conversion. However, the market for high- and ultra-high-efficiency furnaces appears to hold potential for expansion. Because of the rebounding home market, a steady replacement market, and increased sales for reasons of efficiency, GAMA expects the total (gas, oil, and electric) central furnace market to increase by 16% in 1983.

1983-04-04T23:59:59.000Z

370

Energy Savers Tips on Saving Energy& Money at Home  

SciTech Connect

Provides consumers with home energy and money savings tips such as insulation, weatherization, heating, cooling, water heating, energy efficient windows, landscaping, lighting, and energy efficient appliances

Not Available

2003-06-01T23:59:59.000Z

371

Ventilating Beta Plane Leases  

Science Conference Proceedings (OSTI)

The theory of warm water lenses on beta planes is extended to include heat exchange between the lenses and their environment. The motivation for this study comes from recent observations of Gulf Stream warm core rings, which clearly show that ...

William K. Dewar

1988-08-01T23:59:59.000Z

372

Heat Flow, Heat Transfer And Lithosphere Rheology In Geothermal...  

Open Energy Info (EERE)

Flow, Heat Transfer And Lithosphere Rheology In Geothermal Areas- Features And Examples Jump to: navigation, search GEOTHERMAL ENERGYGeothermal Home Journal Article: Heat Flow,...

373

Coal home heating and environmental tobacco smoke in relation to lower respiratory illness in Czech children, from birth to 3 years of age  

E-Print Network (OSTI)

The coefficient for wood as a heating source was elevated,distant heating) Natural gas Electricity Coal Wood Unknown/distant heating and use of natural gas, electricity, or wood

2006-01-01T23:59:59.000Z

374

Guide to Energy-Efficient Ventilation Methods for Acceptable Levels of Indoor Air Quality Levels in Commercial Buildings  

Science Conference Proceedings (OSTI)

Indoor air quality is important in commercial buildings to maintain employee health, well-being, and productivity and avoid employer liability. The most common method to improve indoor air quality in commercial buildings is to use outside ventilation air for dilution of the inside air. Unfortunately, the conditioning of outdoor ventilation air may result in increased energy use for cooling, dehumidification, and heating; and humid outdoor ventilation air also can degrade indoor air quality. Some commerci...

2007-12-17T23:59:59.000Z

375

Next Generation Roofs and Attics for Homes  

SciTech Connect

Prototype residential roof and attic assemblies were constructed and field tested in a mixed-humid U.S. climate. Summer field data showed that at peak day irradiance the heat transfer penetrating the roof deck dropped almost 90% compared with heat transfer for a conventional roof and attic assembly. The prototype assemblies use a combination of strategies: infrared reflective cool roofs, radiant barriers, above-sheathing ventilation, low-emittance surfaces, insulation, and thermal mass to reduce the attic air temperature and thus the heat transfer into the home. The prototype assemblies exhibited attic air temperatures that did not exceed the peak day outdoor air temperature. Field results were benchmarked against an attic computer tool and simulations made for the densely populated, hot and dry southeastern and central-basin regions of California. New construction in the central basin could realize a 12% drop in ceiling and air-conditioning annual load compared with a code-compliant roof and attic having solar reflectance of 0.25 and thermal emittance of 0.75. In the hot, dry southeastern region of California, the combined ceiling and duct annual load drops by 23% of that computed for a code-compliant roof and attic assembly. Eliminating air leakage from ducts placed in unconditioned attics yielded savings comparable to the best simulated roof and attic systems. Retrofitting an infrared reflective clay tile roof with 1 -in (0.032-m) of EPS foam above the sheathing and improving existing ductwork by reducing air leakage and wrapping ducts with insulation can yield annual savings of about $200 compared with energy costs for pre-1980 construction.

Miller, William A [ORNL; Kosny, Jan [ORNL

2008-01-01T23:59:59.000Z

376

Energy Basics: Solar Air Heating  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

Homes & Buildings Printable Version Share this resource Lighting & Daylighting Passive Solar Design Space Heating & Cooling Cooling Systems Heating Systems Furnaces & Boilers Wood...

377

Energy Basics: Solar Liquid Heating  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

Homes & Buildings Printable Version Share this resource Lighting & Daylighting Passive Solar Design Space Heating & Cooling Cooling Systems Heating Systems Furnaces & Boilers Wood...

378

NREL Provides Guidance to Improve Air Mixing and Thermal Comfort in Homes (Fact Sheet), NREL Highlights, Research & Development, NREL (National Renewable Energy Laboratory)  

NLE Websites -- All DOE Office Websites (Extended Search)

research determines optimal HVAC system design for research determines optimal HVAC system design for proper air mixing and thermal comfort in homes. As U.S. homes become more energy efficient, heating, ventilation, and cooling (HVAC) systems will be downsized, and the air flow volumes required to meet heating and cooling loads may be too small to maintain uniform room air mixing-which can affect thermal comfort. Researchers at the National Renewable Energy Laboratory (NREL) evalu- ated the performance of high sidewall air supply inlets and confirmed that these systems can achieve good air mixing and provide suitable comfort levels for occupants. Using computational fluid dynamics modeling, NREL scientists tested the performance of high sidewall supply air jets over a wide range of parameters including supply air tempera-

379

Challenge Home  

NLE Websites -- All DOE Office Websites (Extended Search)

Home Innovations 2 | Building Technologies Office eere.energy.gov Purpose & Objectives Problem Statement: The U.S. Housing industry is extremely slow to adopt...

380

Laboratory Evaluation of Energy Recovery Ventilators  

SciTech Connect

As deep retrofit measures and new construction practices are realizing lower infiltration levels in increasingly tighter envelopes, performance issues can arise with water vapor intrusion in building envelopes and the operation of exhaust only appliances in a depressurized home. Unbalancing (reducing exhaust airflows) of an energy recovery ventilator (ERV) can provide a means to supply makeup air and reduce the level of home depressurization to mitigate these issues, helping realize exhaust-only appliance rated performance, achieve safe atmospherically vented combustion, and/or improve envelope durability. ERV balanced flow operation is well documented, but there is not public domain information available that empirically establishes the effect of unbalanced flow on sensible and latent exchange, especially in the now dominant membrane type ERV used in residential applications. This laboratory evaluation focused on unbalanced flow performance of a membrane type ERV delivering 200 standard cubic feet per minute (SCFM )of supply air. The dataset generated yielded a limited set of curve fit algorithms for unbalanced flow performance that can be used to supplement current modeling approaches in simulation tools like EnergyPlus. Building America BA teams can then utilize such models to analyze whole house effects and determine best practices associated with unbalanced ERV operations.

Kosar, D.

2013-05-01T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


381

Questar Gas - Home Builder Gas Appliance Rebate Program (Idaho) |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Questar Gas - Home Builder Gas Appliance Rebate Program (Idaho) Questar Gas - Home Builder Gas Appliance Rebate Program (Idaho) Questar Gas - Home Builder Gas Appliance Rebate Program (Idaho) < Back Eligibility Construction Multi-Family Residential Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Construction Commercial Weatherization Design & Remodeling Appliances & Electronics Water Heating Windows, Doors, & Skylights Program Info State Idaho Program Type Utility Rebate Program Rebate Amount New Construction Home Options Builder Option Package 1: $50 (single family), $50 (multifamily) Builder Option Package 2: $100 (single family), $100 (multifamily) Energy Star 3.0: $300 (single family), $200 (multifamily) High Performance Home: $500 (single family), $300 (multifamily)

382

Singing River Electric Power Association - Comfort Advantage Home Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Singing River Electric Power Association - Comfort Advantage Home Singing River Electric Power Association - Comfort Advantage Home Program Singing River Electric Power Association - Comfort Advantage Home Program < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Heat Pumps Program Info State Mississippi Program Type Utility Rebate Program Rebate Amount Contact Singing River Electric Power Association Provider Singing River Electric Power Association Singing River Electric Power Association provides rebates on energy efficiency measures in new homes and heat pumps that meet [http://www.comfortadvantage.com/Comfort%20Advantage%20brochure.pdf Comfort Advantage] weatherization standards. To qualify for this rebate the home

383

Modeling study of ventilation, IAQ and energy impacts of residential mechanical ventilation  

SciTech Connect

This paper reports on a simulation study of indoor air quality, ventilation and energy impacts of several mechanical ventilation approaches in a single-family residential building. The study focused on a fictitious two-story house in Spokane, Washington and employed the multizone airflow and contaminant dispersal model CONTAM. The model of the house included a number of factors related to airflow including exhaust fan and forced-air system operation, duct leakage and weather effects, as well as factors related to contaminant dispersal including adsorption/desorption of water vapor and volatile organic compounds, surface losses of particles and nitrogen dioxide, outdoor contaminant concentrations, and occupant activities. The contaminants studied include carbon monoxide, carbon dioxide, nitrogen dioxide, water vapor, fine and coarse particles, and volatile organic compounds. One-year simulations were performed for four different ventilation approaches: a base case of envelope infiltration only, passive inlet vents in combination with exhaust fan operation, an outdoor intake duct connected to the forced-air system return balanced by exhaust fan operation, and a continuously-operated exhaust fan. Results discussed include whole building air change rates, air distribution within the house, heating and cooling loads, contaminants concentrations, and occupant exposure to contaminants.

Persily, A.K.

1998-05-01T23:59:59.000Z

384

Indoor Air Quality in 24 California Residences Designed as High Performance Green Homes  

E-Print Network (OSTI)

Cook top ventilation in passive House/LEED home. (2010).Berkeley National Lab. Passive House Institute U.S. (2011).What is a passive house? Retrieved 11/23, 2012, from http://

Less, Brennan

2012-01-01T23:59:59.000Z

385

OPTIMIZED CONTROL STRATEGIES FOR A TYPICAL WATER LOOP HEAT PUMP SYSTEM.  

E-Print Network (OSTI)

??Water Loop Heat Pump (WLHP) System has been widely utilized in the Heating, Ventilating and Air Conditioning (HVAC) industry for several decades. There is no (more)

Lian, Xu

2011-01-01T23:59:59.000Z

386

Classroom HVAC: Improving ventilation and saving energy -- field study plan  

E-Print Network (OSTI)

in this study. Classroom HVAC: Improving Ventilation andV8doc.sas.com/sashtml. Classroom HVAC: Improving VentilationBerkeley, CA 94720. Classroom HVAC: Improving Ventilation

Apte, Michael G.; Faulkner, David; Hodgson, Alfred T.; Sullivan, Douglas P.

2004-01-01T23:59:59.000Z

387

On The Valuation of Infiltration towards Meeting Residential Ventilation Needs  

E-Print Network (OSTI)

Literature Related to Residential Ventilation Requirements.A. 2005. Review of Residential Ventilation Technologies,M.H. and Matson N.E. , Residential Ventilation and Energy

Sherman, Max H.

2008-01-01T23:59:59.000Z

388

Transitioning to High Performance Homes: Successes and Lessons Learned From Seven Builders  

SciTech Connect

As homebuyers are becoming increasingly concerned about rising energy costs and the impact of fossil fuels as a major source of greenhouse gases, the returning new home market is beginning to demand energy-efficient and comfortable high-performance homes. In response to this, some innovative builders are gaining market share because they are able to market their homes comfort, better indoor air quality, and aesthetics, in addition to energy efficiency. The success and marketability of these high-performance homes is creating a builder demand for house plans and information about how to design, build, and sell their own low-energy homes. To help make these and other builders more successful in the transition to high-performance construction techniques, Pacific Northwest National Laboratory (PNNL) partnered with seven interested builders in the hot humid and mixed humid climates to provide technical and design assistance through two building science firms, Florida Home Energy and Resources Organization (FL HERO) and Calcs-Plus, and a designer that offers a line of stock plans designed specifically for energy efficiency, called Energy Smart Home Plans (ESHP). This report summarizes the findings of research on cost-effective high-performance whole-house solutions, focusing on real-world implementation and challenges and identifying effective solutions. The ensuing sections provide project background, profile each of the builders who participated in the program, and describe their houses construction characteristics, key challenges the builders encountered during the construction and transaction process); and present primary lessons learned to be applied to future projects. As a result of this technical assistance, 17 homes have been built featuring climate-appropriate efficient envelopes, ducts in conditioned space, and correctly sized and controlled heating, ventilation, and air-conditioning systems. In addition, most builders intend to integrate high-performance features into most or all their homes in the future. As these seven builders have demonstrated, affordable, high-performance homes are possible, but require attention to detail and flexibility in design to accommodate specific regional geographic or market-driven constraints that can increase cost. With better information regarding how energy-efficiency trade-offs or design choices affect overall home performance, builders can make informed decisions regarding home design and construction to minimize cost without sacrificing performance and energy savings.

Widder, Sarah H.; Kora, Angela R.; Baechler, Michael C.; Fonorow, Ken; Jenkins, David W.; Stroer, Dennis

2013-03-01T23:59:59.000Z

389

Ventilation Industrielle de Bretagne VIB | Open Energy Information  

Open Energy Info (EERE)

Ventilation Industrielle de Bretagne VIB Ventilation Industrielle de Bretagne VIB Jump to: navigation, search Name Ventilation Industrielle de Bretagne (VIB) Place Ploudalmezeau, France Zip 29839 Sector Geothermal energy, Solar Product Ploudalmezeau-based company producing and marketing energy efficient and ventilation products including air source heat pumps, geothermal water source heat pumps, efficient air filtration systems and solar products. Coordinates 48.540325°, -4.657904° Loading map... {"minzoom":false,"mappingservice":"googlemaps3","type":"ROADMAP","zoom":14,"types":["ROADMAP","SATELLITE","HYBRID","TERRAIN"],"geoservice":"google","maxzoom":false,"width":"600px","height":"350px","centre":false,"title":"","label":"","icon":"","visitedicon":"","lines":[],"polygons":[],"circles":[],"rectangles":[],"copycoords":false,"static":false,"wmsoverlay":"","layers":[],"controls":["pan","zoom","type","scale","streetview"],"zoomstyle":"DEFAULT","typestyle":"DEFAULT","autoinfowindows":false,"kml":[],"gkml":[],"fusiontables":[],"resizable":false,"tilt":0,"kmlrezoom":false,"poi":true,"imageoverlays":[],"markercluster":false,"searchmarkers":"","locations":[{"text":"","title":"","link":null,"lat":48.540325,"lon":-4.657904,"alt":0,"address":"","icon":"","group":"","inlineLabel":"","visitedicon":""}]}

390

Air Sealing Your Home | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Air Sealing Your Home Air Sealing Your Home Air Sealing Your Home November 26, 2013 - 6:22pm Addthis Save on heating and cooling costs by checking for air leaks in common trouble spots in your home. Save on heating and cooling costs by checking for air leaks in common trouble spots in your home. What does this mean for me? Save money and energy by air sealing your house. Caulking and weatherstripping are simple, effective ways of sealing air leaks in your home. Reducing the amount of air that leaks in and out of your home is a cost-effective way to cut heating and cooling costs, improve durability, increase comfort, and create a healthier indoor environment. Caulking and weatherstripping are two simple and effective air-sealing techniques that offer quick returns on investment, often one year or less. Caulk is

391

Air Sealing Your Home | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Your Home Your Home Air Sealing Your Home November 26, 2013 - 6:22pm Addthis Save on heating and cooling costs by checking for air leaks in common trouble spots in your home. Save on heating and cooling costs by checking for air leaks in common trouble spots in your home. What does this mean for me? Save money and energy by air sealing your house. Caulking and weatherstripping are simple, effective ways of sealing air leaks in your home. Reducing the amount of air that leaks in and out of your home is a cost-effective way to cut heating and cooling costs, improve durability, increase comfort, and create a healthier indoor environment. Caulking and weatherstripping are two simple and effective air-sealing techniques that offer quick returns on investment, often one year or less. Caulk is

392

Residential ventilation standards scoping study  

SciTech Connect

The goals of this scoping study are to identify research needed to develop improved ventilation standards for California's Title 24 Building Energy Efficiency Standards. The 2008 Title 24 Standards are the primary target for the outcome of this research, but this scoping study is not limited to that timeframe. We prepared this scoping study to provide the California Energy Commission with broad and flexible options for developing a research plan to advance the standards. This document presents the findings of a scoping study commissioned by the Public Interest Energy Research (PIER) program of the California Energy Commission to determine what research is necessary to develop new residential ventilation requirements for California. This study is one of three companion efforts needed to complete the job of determining the ventilation needs of California residences, determining the bases for setting residential ventilation requirements, and determining appropriate ventilation technologies to meet these needs and requirements in an energy efficient manner. Rather than providing research results, this scoping study identifies important research questions along with the level of effort necessary to address these questions and the costs, risks, and benefits of pursuing alternative research questions. In approaching these questions and corresponding levels of effort, feasibility and timing were important considerations. The Commission has specified Summer 2005 as the latest date for completing this research in time to update the 2008 version of California's Energy Code (Title 24).

McKone, Thomas E.; Sherman, Max H.

2003-10-01T23:59:59.000Z

393

Ventilation, temperature, and HVAC characteristics in small and medium  

NLE Websites -- All DOE Office Websites (Extended Search)

Ventilation, temperature, and HVAC characteristics in small and medium Ventilation, temperature, and HVAC characteristics in small and medium commercial buildings in California Title Ventilation, temperature, and HVAC characteristics in small and medium commercial buildings in California Publication Type Journal Article Refereed Designation Refereed Year of Publication 2012 Authors Bennett, Deborah H., William J. Fisk, Michael G. Apte, X. Wu, Amber L. Trout, David Faulkner, and Douglas P. Sullivan Journal Indoor Air Volume 22 Issue 4 Pagination 309-20 Abstract This field study of 37 small and medium commercial buildings throughout California obtained information on ventilation rate, temperature, and heating, ventilating, and air-conditioning (HVAC) system characteristics. The study included seven retail establishments; five restaurants; eight offices; two each of gas stations, hair salons, healthcare facilities, grocery stores, dental offices, and fitness centers; and five other buildings. Fourteen (38%) of the buildings either could not or did not provide outdoor air through the HVAC system. The air exchange rate averaged 1.6 (s.d. = 1.7) exchanges per hour and was similar between buildings with and without outdoor air supplied through the HVAC system, indicating that some buildings have significant leakage or ventilation through open windows and doors. Not all buildings had sufficient air exchange to meet ASHRAE 62.1 Standards, including buildings used for fitness centers, hair salons, offices, and retail establishments. The majority of the time, buildings were within the ASHRAE temperature comfort range. Offices were frequently overcooled in the summer. All of the buildings had filters, but over half the buildings had a filter with a minimum efficiency reporting value rating of 4 or lower, which are not very effective for removing fine particles. PRACTICAL IMPLICATIONS: Most U.S. commercial buildings (96%) are small- to medium-sized, using nearly 18% of the country's energy, and sheltering a large population daily. Little is known about the ventilation systems in these buildings. This study found a wide variety of ventilation conditions, with many buildings failing to meet relevant ventilation standards. Regulators may want to consider implementing more complete building inspections at commissioning and point of sale.

394

Kansas City Power and Light - Home Performance with ENERGY STAR |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

You are here You are here Home » Kansas City Power and Light - Home Performance with ENERGY STAR Kansas City Power and Light - Home Performance with ENERGY STAR < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Design & Remodeling Windows, Doors, & Skylights Ventilation Maximum Rebate $1200 Program Info State Missouri Program Type Utility Rebate Program Rebate Amount Varies Provider Kansas City Power and Light Kansas City Power and Light (KCP&L) offers rebates to residential customers towards the cost of an ENERGY STAR Home Energy Assessment and a portion of the installed efficiency improvements. Home assessments must be performed by a certified Home Performance with ENERGY STAR contractor or consultant

395

PEPCO - Home Performance with Energy Star Incentive Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

PEPCO - Home Performance with Energy Star Incentive Program PEPCO - Home Performance with Energy Star Incentive Program PEPCO - Home Performance with Energy Star Incentive Program < Back Eligibility Installer/Contractor Residential Savings Category Home Weatherization Commercial Weatherization Other Sealing Your Home Ventilation Manufacturing Windows, Doors, & Skylights Maximum Rebate Recommended measures resulting from Energy Audit: $2,000 Program Info Funding Source Maryland Energy Administration State Maryland Program Type Utility Rebate Program Rebate Amount Home Energy Audit: Cost discounted to $100 Home Insulation: 50% of cost, up to $2,000 Windows: 50% of cost, up to $2,000 Provider Maryland Energy Administration The Potomac Electric Power Company (PEPCO) offers the Home Performance with Energy Star Program which provides incentives for residential customers who

396

Effect of attic ventilation on the performance of radiant barriers  

Science Conference Proceedings (OSTI)

The objective of the experiments was to quantify how attic ventilation would affect the performance of a radiant barrier. Ceiling heat flux and space cooling load were both measured. Results of side-by-side radiant barrier experiments using two identical 13.38 m[sup 2] (nominal) test houses are presented in this paper. The test houses responded similarly to weather variations. Indoor temperatures of the test houses were controlled to within 0.2 [degrees] C. Ceiling heat fluxes and space cooling load were within a 2.5 percent difference between both test houses. The results showed that a critical attic ventilation flow rate of 1.3 (1/sec)/m[sup 2] of the attic floor existed after which the percentage reduction in ceiling heat fluxes produced by the radiant barriers did not change with increasing attic airflow rates. The ceiling heat flux reductions produced by the radiant barriers were between 25 and 35 percent, with 28 percent being the percent reduction observed most often in the presence of attic ventilation. The space-cooling load reductions observed were between two to four percent. All results compiled in this paper were for attics with unfaced fiberglass insulation with a resistance level of 3.35 m[sup 2]K/W (nominal) and for a perforated radiant barrier with low emissivities (less than 0.05) on both sides.

Medina, M.A.; O'Neal, D.L. (Texas A and M Univ., College Station, TX (United States). Dept. of Mechanical Engineering); Turner, W.D. (Texas A and M Univ., College Station, TX (United States). Coll. of Engineering)

1992-11-01T23:59:59.000Z

397

Numerical Analysis of the Channel Wheel Fresh Air Ventilator Under Frosting Conditions  

E-Print Network (OSTI)

As new equipment, the channel wheel fresh air ventilator has become increasingly popular in recent years. However, when such equipment is operated under low ambient temperature in the freezing area in winter, the formation of frost on the outdoor waste air surface becomes problematic, leading to the degradation of the channel wheel fresh air ventilator's performance or even the shutdown of equipment. Therefore, it is necessary to have a detailed investigation on the operational characteristics of the channel wheel fresh air ventilator under frosting in order to guide its application. This paper first reports on the development of a detailed model for the channel wheel heat exchanger, which is the core part of the channel wheel fresh air ventilator under frosting conditions. The model developed, first seen in open literature, consists of a frosting sub-model and a channel wheel heat exchanger sub-model. This is followed by reporting an evaluation of the operational characteristics of a frosted channel wheel heat exchanger under different ambient conditions using the model developed. These include frost formation on the surface of the channel wheel heat exchanger, and impacts on the operational performance of the channel wheel fresh air ventilator. Furthermore, the interval of defrosting is obtained, which provides the basis for the adoption of effective defrosting measures, and thus increasing the channel wheel fresh air ventilator's energy efficiency and operating reliability.

Gao, B.; Dong, Z.; Cheng, Z.; Luo, E.

2006-01-01T23:59:59.000Z

398

Energy-Efficient Home Design | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Design Home Design Energy-Efficient Home Design April 13, 2012 - 11:39am Addthis The Home Energy Score is a national rating system developed by the U.S. Department of Energy. The Score reflects the energy efficiency of a home based on the home's structure and heating, cooling, and hot water systems. The Home Facts provide details about the current structure and systems. Recommendations show how to improve the energy efficiency of the home to achieve a higher score and save money. The Home Energy Score is a national rating system developed by the U.S. Department of Energy. The Score reflects the energy efficiency of a home based on the home's structure and heating, cooling, and hot water systems. The Home Facts provide details about the current structure and systems.

399

Energy-Efficient Home Design | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Design Home Design Energy-Efficient Home Design April 13, 2012 - 11:39am Addthis The Home Energy Score is a national rating system developed by the U.S. Department of Energy. The Score reflects the energy efficiency of a home based on the home's structure and heating, cooling, and hot water systems. The Home Facts provide details about the current structure and systems. Recommendations show how to improve the energy efficiency of the home to achieve a higher score and save money. The Home Energy Score is a national rating system developed by the U.S. Department of Energy. The Score reflects the energy efficiency of a home based on the home's structure and heating, cooling, and hot water systems. The Home Facts provide details about the current structure and systems.

400

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Profitability of Energy Efficiency Upgrades Profitability of Energy Efficiency Upgrades Application of these 10 energy efficiency measures in a typical home yields nearly $600 in annual bill savings, and an impressive 16% overall return on investment. Diagram providing a representative view of the high profitability of energy efficiency upgrades This diagram provides a representative view of the high profitability of energy efficiency upgrades. Note that the home evaluated here is located in an average U.S. climate and has a heat pump, electric water heater, clothes washer, clothes dryer, and dishwasher. The example cost-effectively surpasses the 30% savings target for existing homes under PATH (The Partnership for Advancing Technology in Housing). In fact, all of these measures yield a higher return on investment than an

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


401

Improving Ventilation and Saving Energy: Laboratory Study in a Modular  

NLE Websites -- All DOE Office Websites (Extended Search)

Improving Ventilation and Saving Energy: Laboratory Study in a Modular Improving Ventilation and Saving Energy: Laboratory Study in a Modular Classroom Test Bed Title Improving Ventilation and Saving Energy: Laboratory Study in a Modular Classroom Test Bed Publication Type Report Year of Publication 2005 Authors Apte, Michael G., Ian S. Buchanan, David Faulkner, William J. Fisk, Chi-Ming Lai, Michael Spears, and Douglas P. Sullivan Publisher Lawrence Berkeley National Laboratory Abstract The primary goals of this research effort were to develop, evaluate, and demonstrate a practical HVAC system for classrooms that consistently provides classrooms with the quantity of ventilation in current minimum standards, while saving energy, and reducing HVAC-related noise levels. This research was motivated by several factors, including the public benefits of energy efficiency, evidence that many classrooms are under-ventilated, and public concerns about indoor environmental quality in classrooms. This project involved the installation and verification of the performance of an Improved Heat Pump Air Conditioning (IHPAC) system, and its comparison, a standard HVAC system having an efficiency of 10 SEER. The project included the verification of the physical characteristics suitable for direct replacement of existing 10 SEER systems, quantitative demonstration of improved energy efficiency, reduced acoustic noise levels, quantitative demonstration of improved ventilation control, and verification that the system would meet temperature control demands necessary for the thermal comfort of the occupants. Results showed that the IHPAC met these goals. The IHPAC was found to be a direct bolt-on replacement for the 10 SEER system. Calculated energy efficiency improvements based on many days of classroom cooling or heating showed that the IHPAC system is about 44% more efficient during cooling and 38% more efficient during heating than the 10 SEER system. Noise reduction was dramatic, with measured A-weighed sound level for fan only operation conditions of 34.3 dB(A), a reduction of 19 dB(A) compared to the 10 SEER system. Similarly, the IHPAC stage-1 and stage-2 compressor plus fan sound levels were 40.8 dB(A) and 42.7 dB(A), reductions of 14 and 13 dB(A), respectively. Thus, the IHPAC is 20 to 35 times quieter than the 10 SEER systems depending upon the operation mode. The IHPAC system met the ventilation requirements and was able to provide consistent outside air supply throughout the study. Indoor CO2 levels with simulated occupancy were maintained below 1000 ppm. Finally temperature settings were met and controlled accurately. The goals of the laboratory testing phase were met and this system is ready for further study in a field test of occupied classrooms

402

Energy-Efficient New Homes Tax Credit for Home Builders | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Energy-Efficient New Homes Tax Credit for Home Builders Energy-Efficient New Homes Tax Credit for Home Builders Energy-Efficient New Homes Tax Credit for Home Builders < Back Eligibility Construction Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Maximum Rebate $2,000 Program Info Start Date 1/1/2006 Expiration Date 12/31/2013 Program Type Corporate Tax Credit Rebate Amount $1,000 - $2,000 (depends on energy savings and home type) Provider U.S. Internal Revenue Service '''''This credit expired at the end of 2011. The American Taxpayer Relief Act of 2012 retroactively renewed this tax credit effective January 1, 2012, expiring again on December 31, 2013. Any qualified home constructed and purchased in 2012 or 2013 is eligible for this credit. '''''

403

Coast Electric Power Association - Comfort Advantage Home Program |  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Coast Electric Power Association - Comfort Advantage Home Program Coast Electric Power Association - Comfort Advantage Home Program Coast Electric Power Association - Comfort Advantage Home Program < Back Eligibility Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heat Pumps Program Info State Mississippi Program Type Utility Rebate Program Rebate Amount 300 - 500, varies by home efficiency 150 per additional qual$300 - $500, varies by home efficiency Geothermal Heat Pumps: $400 - $500 Additional Heat Pump Units (When Required): $150ified heat pump system Provider Coast Electric Power Association Coast Electric Power Association (CEPA) provides rebates on heat pumps to new homes which meet certain weatherization standards. To qualify for this rebate the home must have: * Attic insulation of at least R-38 or encapsulated foam attic insulation

404

Midlevel Ventilations Constraint on Tropical Cyclone Intensity  

Science Conference Proceedings (OSTI)

Midlevel ventilation, or the flux of low-entropy air into the inner core of a tropical cyclone (TC), is a hypothesized mechanism by which environmental vertical wind shear can constrain a tropical cyclones intensity. An idealized framework based ...

Brian Tang; Kerry Emanuel

2010-06-01T23:59:59.000Z

405

Does Mixing Make Residential Ventilation More Effective?  

E-Print Network (OSTI)

under Contract No. DE-AC02-05CH11231. References ASHRAE.2009. ASHRAE Handbook of Fundamentals, Ventilation andChapter. Atlanta GA: ASHRAE. ASHRAE. 2007. Ventilation and

Sherman, Max

2011-01-01T23:59:59.000Z

406

May 1999 LBNL -42975 ASHRAE'S RESIDENTIAL VENTILATION  

E-Print Network (OSTI)

May 1999 LBNL - 42975 ASHRAE'S RESIDENTIAL VENTILATION STANDARD: EXEGESIS OF PROPOSED STANDARD 62 Berkeley National Laboratory Berkeley, CA 94720 April 1999 In January 1999 ASHRAE's Standard Project, approved ASHRAE's first complete standard on residential ventilation for public review

407

Ventilation Controller for Improved Indoor Air Quality  

Iain Walker and colleagues at Berkeley Lab have developed a dynamic control system for whole-house ventilation fans that provides maximal air quality while reducing by 18-44% the energy spent on ventilation. The system, the Residential Integrated ...

408

BigHorn Home Improvement Center Energy Performance  

Science Conference Proceedings (OSTI)

The BigHorn Development Project, located in Silverthorne, Colorado, is one of the nation's first commercial building projects to integrate extensive high-performance design into a retail space. The BigHorn Home Improvement Center, completed in the spring of 2000, is a 42,366-ft2 (3,936 m2) hardware store, warehouse, and lumberyard. The authors were brought in at the design stage of the project to provide research-level guidance to apply an integrated design process and perform a postoccupancy evaluation. An aggressive energy design goal of 60% energy cost saving was set early in the process, which focused the efforts of the design team and provided a goal for measuring the success of the project. The extensive use of natural light, combined with energy-efficient electrical lighting design, provides good illumination and excellent energy savings. The reduced lighting loads, management of solar gains, and cool climate allow natural ventilation to meet the cooling loads. A hydronic radiant floor system, gas-fired radiant heaters, and a transpired solar collector deliver heat. An 8.9-kW roof-integrated photovoltaic (PV) system offsets a portion of the electricity. After construction, the authors installed monitoring equipment to collect energy performance data and analyzed the building's energy performance for two and one-half years. The authors also helped program the building controls and provided recommendations for improving operating efficiency. The building shows an estimated 53% energy cost saving and a 54% source energy saving. These savings were determined with whole-building energy simulations that were calibrated with measured data. This paper discusses lessons learned related to the design process, the daylighting performance, the PV system, and the heating, ventilating, and air-conditioning system.

Deru, M.; Pless, S. D.; Torcellini, P. A.

2006-01-01T23:59:59.000Z

409

Passive heating and cooling strategies for single family housing in Fresno, California: a case study  

E-Print Network (OSTI)

This study focuses on the integration of passive heating, cooling, and ventilating techniques for detached single family housing in Fresno, California. The energy use and patterns of energy use were simulated for a typical tract house in Fresno, and serves as a case study, to which energy saving strategies were applied and evaluated using Ener-Win software. The effectiveness of each strategy was assessed based on the annual savings, the initial cost, and a life-cycle cost analysis. Specific areas of evaluation include: shading, improving the R-value and infiltration rate of the building envelope, thermal mass, natural ventilation, and evaporative cooling. The optimum strategies selected utilize only traditional building techniques. Evaporative cooling used in conjunction with an air conditioner was the most effective energy reducing strategy, but a combination of purely passive strategies yield competitive results. Although the typical Fresno home is already energy efficient, small alterations provide energy savings up to 75% for space conditioning.

Winchester, Nathan James

1995-01-01T23:59:59.000Z

410

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Watt about Water? Watt about Water? Water uses energy. Energy uses water. The "water-energy nexus" - as it has come to be known - is one of the emerging hot topics when it comes to making homes greener and more resource-efficient. The Home Energy Saver does not currently provide recommendations for reducing water use, but it does help you understand where your water is currently going (see the Appliances drill-down report from the Compare > Summary page). The material on this page provides some more background and resources for you to keep in mind. Water uses energy The most tangible link is that when your water is heated, every drop contains a hidden "drop" of energy. Saving hot water translates directly into water-heating energy savings. Such savings are available at hot water

411

Home Energy Saver  

NLE Websites -- All DOE Office Websites (Extended Search)

Lowest-Hanging Fruit Lowest-Hanging Fruit Get the Weekly Energy Saving Tip widget and many other great free widgets at Widgetbox! Not seeing a widget? (More info) The analysis you've done in the Home Energy Saver is a great beginning, but not the end of your quest. You now know where you stand and how much you can improve. Time to get started. In the following links you will find dozens of no-cost tips for things you can do to start saving energy immediately, many of which can be done without even opening your wallet! Air Leaks Home office electronics Lighting Heating & cooling Water heating Windows Making it Happen Roadmap to Results Seasons of Life The Lowest-Hanging Fruit Investing for Profit and Comfort Creating Successful Projects Financial Incentives Watt About Water? Choosing a Good Contractor

412

Home Page  

Gasoline and Diesel Fuel Update (EIA)

Electronic Access and Related Reports The AEO98 will be available on CD-ROM and the EIA Home Page on the Internet (http:www.eia.govoiafaeo98homepage.html), including text,...

413

Ameren Illinois (Electric) - Multi-Family Properties Energy Efficiency...  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Weatherization Commercial Weatherization Sealing Your Home Ventilation Manufacturing Heat Pumps Appliances & Electronics Commercial Lighting Lighting Maximum Rebate See rebate...

414

Fire protection countermeasures for containment ventilation systems  

SciTech Connect

The goal of this project is to find countermeasures to protect High Efficiency Particulate Air (HEPA) filters, in exit ventilation ducts, from the heat and smoke generated by fire. Initially, methods were developed to cool fire-heated air by fine water spray upstream of the filters. It was recognized that smoke aerosol exposure to HEPA filters could also cause disruption of the containment system. Through testing and analysis, several methods to partially mitigate the smoke exposure to the HEPA filters were identified. A continuous, movable, high-efficiency prefilter using modified commercial equipment was designed. The technique is capable of protecting HEPA filters over the total time duration of the test fires. The reason for success involved the modification of the prefiltration media. Commercially available filter media has particle sorption efficiency that is inversely proportional to media strength. To achieve properties of both efficiency and strength, rolling filter media were laminated with the desired properties. The approach was Edisonian, but truncation in short order to a combination of prefilters was effective. The application of this technique was qualified, since it is of use only to protect HEPA filters from fire-generated smoke aerosols. It is not believed that this technique is cost effective in the total spectrum of containment systems, especially if standard fire protection systems are available in the space. But in areas of high-fire risk, where the potential fuel load is large and ignition sources are plentiful, the complication of a rolling prefilter in exit ventilation ducts to protect HEPA filters from smoke aerosols is definitely justified.

Alvares, N.; Beason, D.; Bergman, V.; Creighton, J.; Ford, H.; Lipska, A.

1980-08-25T23:59:59.000Z

415

Newer U.S. homes are 30% larger but consume about as much ...  

U.S. Energy Information Administration (EIA)

Includes hydropower, solar, wind, geothermal, biomass and ethanol. ... These new homes consumed 21% less energy for space heating on average than older homes ...

416

Ventilation Based on ASHRAE 62.2  

E-Print Network (OSTI)

Indoor Ventilation Based on ASHRAE 62.2 Arnold Schwarzenegger Governor California Energy Commission Ventilation (ASHRAE 62.2) Minimum Best Practices Guide - Exhaust-Only Ventilation Introduction: The California Energy Commission has created the following guide to provide assistance in complying with ANSI/ASHRAE

417

Ventilation problems in heritage buildings  

Science Conference Proceedings (OSTI)

The control of indoor conditions in heritage buildings, such as castles or museums, is of paramount importance for the proper preservation of the artworks kept in. As heritage buildings are often not equipped with HVAC systems, it is necessary to provide ... Keywords: CO2 concentration, IAQ, heritage buildings, ventilation

S. Costanzo; A. Cusumano; C. Giaconia; S. Mazzacane

2007-05-01T23:59:59.000Z

418

NREL Provides Guidance to Improve Air Mixing and Thermal Comfort in Homes (Fact Sheet)  

DOE Green Energy (OSTI)

NREL research determines optimal HVAC system design for proper air mixing and thermal comfort in homes. As U.S. homes become more energy efficient, heating, ventilation, and cooling (HVAC) systems will be downsized, and the air flow volumes required to meet heating and cooling loads may be too small to maintain uniform room air mixing-which can affect thermal comfort. Researchers at the National Renewable Energy Laboratory (NREL) evaluated the performance of high sidewall air supply inlets and confirmed that these systems can achieve good air mixing and provide suitable comfort levels for occupants. Using computational fluid dynamics modeling, NREL scientists tested the performance of high sidewall supply air jets over a wide range of parameters including supply air temperature, air velocity, and inlet size. This technique uses the model output to determine how well the supply air mixes with the room air. Thermal comfort is evaluated by monitoring air temperature and velocity in more than 600,000 control volumes that make up the occupied zone of a single room. The room has an acceptable comfort level when more than 70% of the control volumes meet the comfort criteria on both air temperature and velocity. The study shows that high sidewall supply air jets achieve uniform mixing in a room, which is essential for providing acceptable comfort levels. The study also provides information required to optimize overall space conditioning system design in both heating and cooling modes.

Not Available

2012-02-01T23:59:59.000Z

419

Entergy Texas - Energy Star Homes Program for Builders | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Entergy Texas - Energy Star Homes Program for Builders Entergy Texas - Energy Star Homes Program for Builders Entergy Texas - Energy Star Homes Program for Builders < Back Eligibility Construction Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Program Info State Texas Program Type Utility Rebate Program Rebate Amount Single-Family Homes - Tier I (ENERGY STAR V-2.0): $150 per home Single-Family Homes - Tier II (ENERGY STAR V-2.5): $300 per home Attached Homes: 50% of single-family incentive per housing unit Advanced Lighting Package: $50 per single-family home ENERGY STAR V-3.0 HVAC Check Lists: $150 per single-family home Provider Entergy Texas Entergy Texas offers an incentive to builders in its service territory for

420

Fresh Way to Cut Combustion, Crop and Air Heating Costs Avoids Million BTU Purchases: Inventions and Innovation Combustion Success Story  

DOE Green Energy (OSTI)

Success story written for the Inventions and Innovation Program about a new space heating method that uses solar energy to heat incoming combustion, crop, and ventilation air.

Wogsland, J.

2001-01-17T23:59:59.000Z

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


421

Empire District Electric - Low Income New Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Empire District Electric - Low Income New Homes Program Empire District Electric - Low Income New Homes Program Empire District Electric - Low Income New Homes Program < Back Eligibility Construction Low-Income Residential Savings Category Home Weatherization Commercial Weatherization Heating & Cooling Commercial Heating & Cooling Cooling Heat Pumps Appliances & Electronics Commercial Lighting Lighting Maximum Rebate Total: $1,100 Program Info State Missouri Program Type Utility Rebate Program Rebate Amount Insulation: full incremental cost above the appropriate baseline Heat Pumps: $400 Central AC: $400 Refrigerator: $200 Lighting: $100 Provider Empire District Electric Empire District Electric offers rebates for the utilization of energy efficient measures and appliances in new, low-income homes. Rebates are

422

Development of a Residential Integrated Ventilation Controller  

NLE Websites -- All DOE Office Websites (Extended Search)

Development of a Residential Integrated Ventilation Controller Development of a Residential Integrated Ventilation Controller Title Development of a Residential Integrated Ventilation Controller Publication Type Report LBNL Report Number LBNL-5554E Year of Publication 2012 Authors Walker, Iain S., Max H. Sherman, and Darryl J. Dickerhoff Keywords ashrae standard 62,2, california title 24, residential ventilation, ventilation controller Abstract The goal of this study was to develop a Residential Integrated Ventilation Controller (RIVEC) to reduce the energy impact of required mechanical ventilation by 20%, maintain or improve indoor air quality and provide demand response benefits. This represents potential energy savings of about 140 GWh of electricity and 83 million therms of natural gas as well as proportional peak savings in California. The RIVEC controller is intended to meet the 2008 Title 24 requirements for residential ventilation as well as taking into account the issues of outdoor conditions, other ventilation devices (including economizers), peak demand concerns and occupant preferences. The controller is designed to manage all the residential ventilation systems that are currently available. A key innovation in this controller is the ability to implement the concept of efficacy and intermittent ventilation which allows time shifting of ventilation. Using this approach ventilation can be shifted away from times of high cost or high outdoor pollution towards times when it is cheaper and more effective. Simulations, based on the ones used to develop the new residential ventilation requirements for the California Buildings Energy code, were used to further define the specific criteria and strategies needed for the controller. These simulations provide estimates of the energy, peak power and contaminant improvement possible for different California climates for the various ventilation systems. Results from a field test of the prototype controller corroborate the predicted performance.

423

New Homes Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

New Homes Program New Homes Program New Homes Program < Back Eligibility Installer/Contractor Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Program Info Start Date 07/01/2012 State Wisconsin Program Type State Rebate Program Rebate Amount Varies based on efficiency level Provider Focus on Energy Focus on Energy's New Homes Program certifies homes that are built more efficient than the current [http://dsireusa.org/incentives/incentive.cfm?Incentive_Code=WI13R&re=0&ee=0 Wisconsin Building Code]. Incentives are available depending on the level of efficiency that the new home achieves, and are claimed by the builder or the homeowner that serves as the general contractor and holds the permits.

424

Space Heating and Cooling  

Energy.gov (U.S. Department of Energy (DOE))

A wide variety of technologies are available for heating and cooling homes and other buildings. In addition, many heating and cooling systems have certain supporting equipment in common, such as...

425

Home Energy Checklist | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Home Energy Checklist Home Energy Checklist Home Energy Checklist October 7, 2013 - 4:46pm Addthis This checklist outlines actions that conserve energy within homes. Today Checkbox Turn down the temperature of your water heater to the warm setting (120°F). You'll save energy and avoid scalding your hands. Checkbox Check if your water heater has an insulating blanket. An insulating blanket will pay for itself in one year or less! Checkbox Heating can account for almost half of the average family's winter energy bill. Make sure your furnace or heat pump receives professional maintenance each year. And look for the ENERGY STAR® label when replacing your system. Checkbox Review additional strategies to reduce your water heating bills. Water heating can account for 14%-25% of the energy consumed in your home.

426

Water Heating | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Water Heating Water Heating August 19, 2013 - 11:15am Addthis A variety of systems are available for water heating in homes and buildings. Learn about: Conventional Storage Water...

427

TVA Partner Utilities - Energy Right New Homes Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Residential Residential Utility Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Heat Pumps Program Info State North Carolina Program Type Utility Rebate Program Rebate Amount Site Built New Homes Plan: $100-$800 depending on local power company and home efficiency Manufactured Home Heat Pump: up to $500 The Tennessee Valley Authority (TVA) ''energy right'' New Homes Plan provides incentives for all-electric, energy-efficient new homes by offering graduated rebates for new homes. Homes built at least 7% better than code qualify for the entry level of the program while those built 15% better qualify as energy right Platinum or Platinum Certified (ENERGY STAR Certified). A variety of efficiency standards must be met in order to reach

428

Questar Gas - Home Builder Gas Appliance Rebate Program | Department of  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Questar Gas - Home Builder Gas Appliance Rebate Program Questar Gas - Home Builder Gas Appliance Rebate Program Questar Gas - Home Builder Gas Appliance Rebate Program < Back Eligibility Construction Residential Savings Category Heating & Cooling Commercial Heating & Cooling Heating Home Weatherization Construction Commercial Weatherization Design & Remodeling Appliances & Electronics Water Heating Program Info Start Date 7/1/2009 State Wyoming Program Type Utility Rebate Program Rebate Amount Energy Star Home Certification: $500 Storage Water Heater: $50 Tankless Water Heater: $300 Furnace: $300 Boiler: $400 Provider Questar Gas Questar Gas provides incentives for home builders to construct energy efficient homes. Rebates are provided for both energy efficient gas equipment and whole home Energy Star certification. All equipment and

429

Home Automation  

E-Print Network (OSTI)

In this paper I briefly discuss the importance of home automation system. Going in to the details I briefly present a real time designed and implemented software and hardware oriented house automation research project, capable of automating house's electricity and providing a security system to detect the presence of unexpected behavior.

Ahmed, Zeeshan

2010-01-01T23:59:59.000Z

430

Energy Efficient Ventilation for Maintaining Indoor Air Quality in Large Buildings  

E-Print Network (OSTI)

this paper was presented at the 3rd International Conference on Cold Climate Heating, Ventilating and Air-conditioning, Sapporo, Japan, November 2000 C. Y. Shaw Rsum Institute for Research in Construction, National Research Council Canada Achieving good indoor air quality in large residential and commercial buildings continues to be a top priority for owners, designers, building managers and occupants alike. Large buildings present a greater challenge in this regard than do smaller buildings and houses. The challenge is greater today because there are many new materials, furnishings, products and processes used in these buildings that are potential sources of air contaminants. There are three strategies for achieving acceptable indoor air quality: ventilation (dilution), source control and air cleaning/filtration. Of the three, the most frequently used strategy, and in most cases the only one available to building operators, is ventilation. Ventilation is the process of supplying outdoor air to an enclosed space and removing stale air from this space. It can control the indoor air quality by both diluting the indoor air with less contaminated outdoor air and removing the indoor contaminants with the exhaust air. Ventilation costs money because the outdoor air needs to be heated in winter and cooled in summer. To conserve energy, care must be taken to maximize the efficiency of the ventilation system. In this regard, a number of factors come into play

C. Y. Shaw; C. Y. Shaw Rsum

2000-01-01T23:59:59.000Z

431

Development of a Residential Integrated Ventilation Controller  

SciTech Connect

The goal of this study was to develop a Residential Integrated Ventilation Controller (RIVEC) to reduce the energy impact of required mechanical ventilation by 20percent, maintain or improve indoor air quality and provide demand response benefits. This represents potential energy savings of about 140 GWh of electricity and 83 million therms of natural gas as well as proportional peak savings in California. The RIVEC controller is intended to meet the 2008 Title 24 requirements for residential ventilation as well as taking into account the issues of outdoor conditions, other ventilation devices (including economizers), peak demand concerns and occupant preferences. The controller is designed to manage all the residential ventilation systems that are currently available. A key innovation in this controller is the ability to implement the concept of efficacy and intermittent ventilation which allows time shifting of ventilation. Using this approach ventilation can be shifted away from times of high cost or high outdoor pollution towards times when it is cheaper and more effective. Simulations, based on the ones used to develop the new residential ventilation requirements for the California Buildings Energy code, were used to further define the specific criteria and strategies needed for the controller. These simulations provide estimates of the energy, peak power and contaminant improvement possible for different California climates for the various ventilation systems. Results from a field test of the prototype controller corroborate the predicted performance.

Staff Scientist; Walker, Iain; Sherman, Max; Dickerhoff, Darryl

2011-12-01T23:59:59.000Z

432

Passive ventilation for residential air quality control  

SciTech Connect

Infiltration has long served the residential ventilation needs in North America. In Northern Europe it has been augmented by purpose-provided natural ventilation systems--so-called passive ventilation systems--to better control moisture problems in dwellings smaller than their North American counterparts and in a generally wetter climate. The growing concern for energy consumption, and the environmental impacts associated with it, has however led to tighter residential construction standards on both continents and as a result problems associated with insufficient background ventilation have surfaced. Can European passive ventilation systems be adapted for use in North American dwellings to provide general background ventilation for air quality control? This paper attempts to answer this question. The configuration, specifications and performance of the preferred European passive ventilation system--the passive stack ventilation (PSV) system--will be reviewed; innovative components and system design strategies recently developed to improve the traditional PSV system performance will be outlined; and alternative system configurations will be presented that may better serve the climatic extremes and more urban contexts of North America. While these innovative and alternative passive ventilation systems hold great promise for the future, a rational method to size the components of these systems to achieve the control and precision needed to meet the conflicting constraints of new ventilation and air tightness standards has not been forthcoming. Such a method will be introduced in this paper and an application of this method will be presented.

Axley, J.

1999-07-01T23:59:59.000Z

433

Satilla REMC - HomePlus Loan Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Satilla REMC - HomePlus Loan Program Satilla REMC - HomePlus Loan Program Satilla REMC - HomePlus Loan Program < Back Eligibility Residential Savings Category Home Weatherization Commercial Weatherization Sealing Your Home Heating & Cooling Commercial Heating & Cooling Cooling Design & Remodeling Windows, Doors, & Skylights Heat Pumps Heating Program Info State Georgia Program Type Utility Loan Program Rebate Amount Loans $500 - $3,000 at 7.9% APR up to 24 months Loans $3,001 - $7,500 at 7.9% APR, 25 - 60 months Loans $7,502 - $25,000 at 6.5% APR, 61 - 84 months Provider Satilla Rural Electric Membership Corporation Satilla Rural Electric Member Corporation offers the HomePlus Loan Program to members to install energy efficient improvements in their homes. Members can receive financing for improvements in areas such as heating and

434

Evaluation of Humidity Control Options in Hot-Humid Climate Homes (Fact Sheet)  

DOE Green Energy (OSTI)

This technical highlight describes NREL research to analyze the indoor relative humidity in three home types in the hot-humid climate zone, and examine the impacts of various dehumidification equipment and controls. As the Building America program researches construction of homes that achieve greater source energy savings over typical mid-1990s construction, proper modeling of whole-house latent loads and operation of humidity control equipment has become a high priority. Long-term high relative humidity can cause health and durability problems in homes, particularly in a hot-humid climate. In this study, researchers at the National Renewable Energy Laboratory (NREL) used the latest EnergyPlus tool equipped with the moisture capacitance model to analyze the indoor relative humidity in three home types: a Building America high-performance home; a mid-1990s reference home; and a 2006 International Energy Conservation Code (IECC)-compliant home in hot-humid climate zones. They examined the impacts of various dehumidification equipment and controls on the high-performance home where the dehumidification equipment energy use can become a much larger portion of whole-house energy consumption. The research included a number of simulated cases: thermostat reset, A/C with energy recovery ventilator, heat exchanger assisted A/C, A/C with condenser reheat, A/C with desiccant wheel dehumidifier, A/C with DX dehumidifier, A/C with energy recovery ventilator, and DX dehumidifier. Space relative humidity, thermal comfort, and whole-house source energy consumption were compared for indoor relative humidity set points of 50%, 55%, and 60%. The study revealed why similar trends of high humidity were observed in all three homes regardless of energy efficiency, and why humidity problems are not necessarily unique in the high-performance home. Thermal comfort analysis indicated that occupants are unlikely to notice indoor humidity problems. The study confirmed that supplemental dehumidification is needed to maintain space relative humidity (RH) below 60% in a hot-humid climate home. Researchers also concluded that while all the active dehumidification options included in the study successfully controlled space relative humidity excursions, the increase in whole-house energy consumption was much more sensitive to the humidity set point than the chosen technology option. In the high-performance home, supplemental dehumidification equipment results in a significant source energy consumption penalty at 50% RH set point (12.6%-22.4%) compared to the consumption at 60% RH set point (1.5%-2.7%). At 50% and 55% RH set points, A/C with desiccant wheel dehumidifier and A/C with ERV and high-efficiency DX dehumidifier stand out as the two cases resulting in the smallest increase of source energy consumption. At an RH set point of 60%, all explicit dehumidification technologies result in similar insignificant increases in source energy consumption and thus are equally competitive.

Not Available

2011-12-01T23:59:59.000Z

435

First Energy Ohio - New Home Builder Incentive Program (Ohio) | Department  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

First Energy Ohio - New Home Builder Incentive Program (Ohio) First Energy Ohio - New Home Builder Incentive Program (Ohio) First Energy Ohio - New Home Builder Incentive Program (Ohio) < Back Eligibility Construction Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Maximum Rebate $1,200/home Program Info State Ohio Program Type Utility Rebate Program Rebate Amount New Home: $400, plus $0.10/kWh saved annually over the reference home, as calculated by REM/Rate Ohio subsidiaries of FirstEnergy (Ohio Edison, The Illuminating Company, Toledo Edison) offer rebates for builders of new, energy efficient homes. Each newly built home is eligible for a rebate of $400, plus $0.10/kWh saved annually over the reference home, as calculated by REM/Rate. The

436

PNM - Energy Star Home Builder Rebate Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

PNM - Energy Star Home Builder Rebate Program PNM - Energy Star Home Builder Rebate Program PNM - Energy Star Home Builder Rebate Program < Back Eligibility Construction Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Program Info Expiration Date 12/31/2012 State New Mexico Program Type Utility Rebate Program Rebate Amount Energy Star for Homes Version 2.5: $750/home Provider PNM PNM is offering home builders a rebate for each Energy Star-qualified home they build in PNM service areas. Every Energy Star-qualified home must include effective insulation and air sealing, high performance windows, doors and skylights, tight construction and ducts, and independent testing and inspection. The builder must arrange for a qualified Home Energy Rater

437

Flathead Electric Cooperative - New and Manufactured Home Incentive Program  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Flathead Electric Cooperative - New and Manufactured Home Incentive Flathead Electric Cooperative - New and Manufactured Home Incentive Program Flathead Electric Cooperative - New and Manufactured Home Incentive Program < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Program Info State Montana Program Type Utility Rebate Program Rebate Amount New Montana Home: $1,500 NEEM Home: $750 (homeowner), $150 (sales representative) Provider Flathead Electric Cooperative Flathead Electric encourages its residential customers to occupy energy efficient homes. Owners and builders of new homes which meet the "Montana Homes" requirements listed on the program web site are eligible for a rebate of $1,500. All application information and home testing must be

438

heating oil - U.S. Energy Information Administration (EIA)  

U.S. Energy Information Administration (EIA)

Crude oil, gasoline, heating oil, diesel, ... Home; Browse by Tag; Most Popular Tags. ... High heating oil prices discourage heating oil supply contracts for the ...

439

Massachusetts New Homes with ENERGY STAR | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Massachusetts New Homes with ENERGY STAR Massachusetts New Homes with ENERGY STAR Massachusetts New Homes with ENERGY STAR < Back Eligibility Construction Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Maximum Rebate $8,000 Program Info Funding Source Energy Efficiency Fund (Public Benefits Fund) Expiration Date 12/2013 State Massachusetts Program Type State Rebate Program Rebate Amount Varies depending on type of housing (single or multi-family) and level achieved Provider ICF International Program Incentives may change in 2013; contact the program administrators to confirm. In Massachusetts, home builders constructing new homes in territories of sponsoring utilities and energy efficiency service providers* can receive

440

Energy Basics: Wood and Pellet Heating  

Office of Energy Efficiency and Renewable Energy (EERE) Indexed Site

Heating & Cooling Systems Water Heating Wood and Pellet Heating Wood-burning and pellet fuel appliances use biomass or waste resources to heat homes or buildings. Types of Wood-...

Note: This page contains sample records for the topic "home ventilation heating" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
to obtain the most current and comprehensive results.


441

Home Energy Rebate Program | Department of Energy  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

Energy Rebate Program Energy Rebate Program Home Energy Rebate Program < Back Eligibility Residential Savings Category Heating & Cooling Home Weatherization Construction Commercial Weatherization Commercial Heating & Cooling Design & Remodeling Other Maximum Rebate $10,000 for energy efficiency improvements (plus $500 for energy audit); $7,500 qualified new 5 Star Plus homes Program Info Funding Source Alaska Housing Finance Corporation State Alaska Program Type State Rebate Program Rebate Amount Varies, depending on energy efficiency improvements made Provider Alaska Housing Finance Corporation Under the Home Energy Rebate Program, homeowners who want to make their own energy efficiency improvements on their home can receive a rebate for some of their expenditures. The program requires a home energy rater to evaluate

442

Home Energy Saver | Open Energy Information  

Open Energy Info (EERE)

Home Energy Saver Home Energy Saver Jump to: navigation, search Tool Summary LAUNCH TOOL Name: Home Energy Saver Agency/Company /Organization: Lawrence Berkeley National Laboratory (LBNL) Sector: Energy Focus Area: Buildings - Residential Phase: Evaluate Effectiveness and Revise as Needed Topics: Opportunity Assessment & Screening Resource Type: Online calculator User Interface: Website Website: hes.lbl.gov/consumer/ OpenEI Keyword(s): Energy Efficiency and Renewable Energy (EERE) Tools Equivalent URI: cleanenergysolutions.org/content/home-energy-saver Language: English Policies: Deployment Programs DeploymentPrograms: Technical Assistance References: Home Energy Saver[1] Quickly compute a home's energy use for all end uses, including heating, cooling, water heating, appliances, and lighting; get recommended

443

Building America Top Innovations Hall of Fame Profile … Outside Air Ventilation Controller  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

partner Davis Energy partner Davis Energy Group worked with Monley Cronin Construction to build 100 energy-efficient homes in Woodland, CA, with night- cooling ventilation systems. BUILDING AMERICA TOP INNOVATIONS HALL OF FAME PROFILE INNOVATIONS CATEGORY: 1. Advanced Technologies and Practices 1.3 Assured Health, Safety, and Durability Outside Air Ventilation Controller Building America researchers developed technologies to harness the natural day-night temperature swings in the U.S. Southwest to cut cooling energy peak demand with no compromise in comfort. Building America research has shown that, in dry climates, the use of ventilation cooling can significantly reduce, delay, or completely eliminate air conditioner operation resulting in both energy savings and reduction of peak demand

444

Test Plan to Evaluate the Relationship Among IAQ, Comfort, Moisture, and Ventilation in Humid Climates  

Science Conference Proceedings (OSTI)

This experimental plan describes research being conducted by Pacific Northwest National Laboratory (PNNL), in coordinatation with Florida Solar Energy Center (FSEC), Florida HERO, and Lawrence Berkeley National Laboratory (LBNL) to evaluate the impact of ventilation rate on interior moisture levels, temperature distributions, and indoor air contaminant concentrations. Specifically, the research team will measure concentrations of indoor air contaminants, ventilation system flow rates, energy consumption, and temperature and relative humidity in ten homes in Gainesville, FL to characterize indoor pollutant levels and energy consumption associated with the observed ventilation rates. PNNL and FSEC have collaboratively prepared this experimental test plan, which describes background and context for the proposed study; the experimental design; specific monitoring points, including monitoring equipment, and sampling frequency; key research questions and the associated data analysis approach; experimental logistics, including schedule, milestones, and team member contact information; and clearly identifies the roles and responsibilities of each team in support of project objectives.

Widder, Sarah H.; Martin, Eric

2013-03-15T23:59:59.000Z

445

BCP Home  

NLE Websites -- All DOE Office Websites (Extended Search)

Boulder Canyon Project Information Module Boulder Canyon Project Information Module HOME MODULE OVERVIEW LEGISLATION TIMELINE TIMELINE SUMMARY CASE LAW PROJECT HISTORY MISC. DOCUMENTS RELATED LINKS Home Page Image Welcome Hoover Dam is the highest and third largest concrete dam in the United States. The dam, power plant, and high-voltage switchyards are located in the Black Canyon of the Colorado River on the Arizona-Nevada state line. Lake Mead, the reservoir behind the dam, will hold the average two-year flow of the Colorado River. Hoover Dam´s authorized purposes are: first, river regulation, improvement of navigation, and flood control; second, delivery of stored water for irrigation and other domestic uses; and third, power generation. This Page was last modified on : 05-12-2009

446

Homes Blog  

Energy.gov (U.S. Department of Energy (DOE)) Indexed Site

homes-blog Office of Energy Efficiency & Renewable homes-blog Office of Energy Efficiency & Renewable Energy Forrestal Building 1000 Independence Avenue, SW Washington, DC 20585 en Mississippi Adopts New Rules to Save Energy, Money http://energy.gov/eere/articles/mississippi-adopts-new-rules-save-energy-money-0 Mississippi Adopts New Rules to Save Energy, Money

447

Analysis of Demand Controlled Ventilation Technology and ...  

Science Conference Proceedings (OSTI)

... The actual health, comfort, and productivity impacts of mechanical ventilation ... p strat i csp o ... in California and elsewhere is the impact of ambient air ...

2011-01-11T23:59:59.000Z

448

Summary of human responses to ventilation  

E-Print Network (OSTI)

coils of commercial air-conditioning systems. Proceedings ofrefrigerating and air-conditioning engineers, inc. pp 601-for ventilation and air-conditioning systems - offices and

Seppanen, Olli A.; Fisk, William J.

2004-01-01T23:59:59.000Z

449

Mixed-Mode Ventilation and Building Retrofits  

E-Print Network (OSTI)

November 1994, ENTPE, Lyon. [CIBSE] Chartered Institution ofMixed-mode ventilation. CIBSE Applications Manual AM13.incorporated by the design. CIBSE, 2000 Mixed-mode

Brager, Gail; Ackerly, Katie

2010-01-01T23:59:59.000Z

450

Available Technologies: Ventilation Controller for Improved Indoor ...  

Iain Walker and colleagues at Berkeley Lab have developed a dynamic control system for whole-house ventilation fans that provides maximal air quality while reducing ...

451

Case Study 1 - Ventilation in Manufactured Houses  

Science Conference Proceedings (OSTI)

... Ventilation in Manufactured Houses. ... fan operation, an outdoor air intake duct installed on the forced-air return, and whole house exhaust with and ...