National Library of Energy BETA

Sample records for bmu sector energy

  1. China-GHG Monitoring | Open Energy Information

    Open Energy Info (EERE)

    Partner on behalf of the Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Low emission...

  2. Maldives-Supporting the Zero Emissions Strategy | Open Energy...

    Open Energy Info (EERE)

    (GIZ) Partner Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Low emission...

  3. Mexican-German Climate Alliance | Open Energy Information

    Open Energy Info (EERE)

    (GIZ) Partner SEMARNAT, Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Low emission...

  4. China-Sino-German Partnership | Open Energy Information

    Open Energy Info (EERE)

    Partner on behalf of the Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Low emission...

  5. Chile-GTZ Public Properties for Grid-connected Renewable Energy...

    Open Energy Info (EERE)

    on behalf of the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Topics Background analysis Website http:www.gtz.deen...

  6. Energy Sector Market Analysis

    SciTech Connect (OSTI)

    Arent, D.; Benioff, R.; Mosey, G.; Bird, L.; Brown, J.; Brown, E.; Vimmerstedt, L.; Aabakken, J.; Parks, K.; Lapsa, M.; Davis, S.; Olszewski, M.; Cox, D.; McElhaney, K.; Hadley, S.; Hostick, D.; Nicholls, A.; McDonald, S.; Holloman, B.

    2006-10-01

    This paper presents the results of energy market analysis sponsored by the Department of Energy's (DOE) Weatherization and International Program (WIP) within the Office of Energy Efficiency and Renewable Energy (EERE). The analysis was conducted by a team of DOE laboratory experts from the National Renewable Energy Laboratory (NREL), Oak Ridge National Laboratory (ORNL), and Pacific Northwest National Laboratory (PNNL), with additional input from Lawrence Berkeley National Laboratory (LBNL). The analysis was structured to identify those markets and niches where government can create the biggest impact by informing management decisions in the private and public sectors. The analysis identifies those markets and niches where opportunities exist for increasing energy efficiency and renewable energy use.

  7. Energy Sector Cybersecurity Framework Implementation Guidance

    Broader source: Energy.gov (indexed) [DOE]

    FOR PUBLIC COMMENT SEPTEMBER, 2014 ENERGY SECTOR CYBERSECURITY FRAMEWORK IMPLEMENTATION GUIDANCE Energy Sector Cybersecurity Framework Implementation Guidance Table of Contents...

  8. Energy Analysis by Sector | Department of Energy

    Office of Environmental Management (EM)

    Information Resources » Energy Analysis by Sector Energy Analysis by Sector Manufacturers often rely on energy-intensive technologies and processes. AMO conducts a range of analyses to explore energy use and trends by sector. Manufacturing Energy and Carbon Footprints Static Manufacturing Energy Sankey Diagrams Dynamic Manufacturing Energy Sankey Tool Energy & Environmental Profiles Bandwidth Studies Large Energy User Manufacturing Facilities by State MANUFACTURING ENERGY and carbon

  9. Sector Collaborative on Energy Efficiency

    SciTech Connect (OSTI)

    none,

    2008-06-01

    Helps stakeholders identify and act on cost-effective opportunities for expanding energy efficiency resources in the hospitality, retail, commercial real estate, grocery, and municipal sectors.

  10. WINDExchange: Wind Energy Market Sectors

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Market Sectors Printable Version Bookmark and Share Utility-Scale Wind Distributed Wind Motivations for Buying Wind Power Buying Wind Power Selling Wind Power Wind Energy Market Sectors U.S. power plants generate electricity for homes, factories, and businesses from a variety of resources, including coal, hydro, natural gas, nuclear, petroleum, and (non-hydro) renewable resources such as wind and solar energy. This power generation mix varies significantly across the country depending on

  11. Federal Sector Renewable Energy Project Implementation: ""What...

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

    Sector Renewable Energy Project Implementation: ""What's Working and Why Federal Sector Renewable Energy Project Implementation: ""What's Working and Why Presentation by Robert...

  12. Energy Efficiency and the Finance Sector | Open Energy Information

    Open Energy Info (EERE)

    and the Finance Sector Jump to: navigation, search Name Energy Efficiency and the Finance Sector AgencyCompany Organization United Nations Environment Programme Sector Energy...

  13. Energy-Sector Stakeholders Attend the Department of Energy's...

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

    Energy-Sector Stakeholders Attend the Department of Energy's 2010 Cybersecurity for Energy Delivery Systems Peer Review Energy-Sector Stakeholders Attend the Department of Energy's...

  14. Energy-Sector Stakeholders Attend the Department of Energy's...

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

    Energy-Sector Stakeholders Attend the Department of Energy's Cybersecurity for Energy Delivery Systems Peer Review Energy-Sector Stakeholders Attend the Department of Energy's...

  15. Template:Energy Generation Facilities by Sector | Open Energy...

    Open Energy Info (EERE)

    Energy Generation Facilities by Sector Jump to: navigation, search This is the Energy Generation Facilities by Sector template. It will display energy generation facilities for the...

  16. Manufacturing Energy and Carbon Footprint - Sector: Computer...

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

    Computers, Electronics and Electrical Equipment (NAICS 334, 335) Process Energy ... Carbon Footprint Sector: Computers, Electronics and Electrical Equipment (NAICS 334, ...

  17. EIA Energy Efficiency-Residential Sector Energy Intensities,...

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

    Residential Sector Energy Intensities RESIDENTIAL SECTOR ENERGY INTENSITIES: 1978-2005 Released Date: August 2004 Page Last Modified:June 2009 These tables provide estimates of...

  18. Electric energy sector in Argentina

    SciTech Connect (OSTI)

    Bastos, C.M.

    1994-06-01

    This article describes how the organization of the electric energy sector in Argentina has changed dramatically from a sector in which state-owned companies worked under a central planning to one in which private companies make their own decisions. The way that the electrical system used to work can be shown by these statements: demand growth estimated by central planning team; projects to be developed and the timetable determined by the same team; unit operations ruled by central dispatch, and under state-owned companies responsibility; integration with neighbor countries focused on physical projects, such as Salto Grande with Uruguay and Yacyreta with Paraguay. Today the electrical system works under these rules: the system has been vertically separated and the companies cannot be integrated; electric energy is considered as an ordinary wealth and the value that consumers give it is taken into account, (the distribution companies pay consumers a penalty for the energy that they cannot supply, the penalty is worth the economic damage consumers suffer due to its lack); producers have to compete for demand. They can sell in two ways: sell under private agreements or sell to the system. Both ways of selling compete with each other because the system buys giving priority to lower costs and, as a consequence, some of the producers do not sell at all.

  19. Chapter 2: Energy Sectors and Systems

    Office of Environmental Management (EM)

    2: Energy Sectors and Systems September 2015 Quadrennial Technology Review 2 Energy Sectors and Systems Issues and RDD&D Opportunities Energy systems are becoming increasingly interconnected and complex. Integrated energy systems present both opportunities for performance improvement as well as risks to operability and security. The size and scope of these opportunities and risks are just beginning to be understood. This chapter addresses both the key issues of energy sectors and their

  20. DOE Issues Energy Sector Cyber Organization NOI

    Office of Environmental Management (EM)

    Issues National Energy Sector Cyber Organization Notice of Intent February 11, 2010 The Department of Energy's (DOE) National Energy Technology Laboratory (NETL) announced on Jan. 7 that it intends to issue a Funding Opportunity Announcement (FOA) for a National Energy Sector Cyber Organization, envisioned as a partnership between the federal government and energy sector stakeholders to protect the bulk power electric grid and aid the integration of smart grid technology to enhance the security

  1. Energy Sector Cybersecurity Framework Implementation Guidance

    Office of Environmental Management (EM)

    JANUARY 2015 ENERGY SECTOR CYBERSECURITY FRAMEWORK IMPLEMENTATION GUIDANCE U.S. DEPARTMENT OF ENERGY OFFICE OF ELECTRICITY DELIVERY AND ENERGY RELIABILITY Energy Sector Cybersecurity Framework Implementation Guidance │ Table of Contents TABLE OF CONTENTS 1. Introduction .............................................................................................................................................. 1 2. Preparing for Framework Implementation

  2. 2015 Energy Sector-Specific Plan

    Broader source: Energy.gov [DOE]

    The U.S. Department of Energy (DOE), as the Sector-Specific Agency for the Energy Sector, has worked closely with government and industry partners to develop the 2015 Energy Sector-Specific Plan (SSP). DOE conducted much of this work in collaboration with the Energy Sector Coordinating Councils (SCCs) and the Energy Government Coordinating Council (GCC). The Energy SCCs represent the interests of the Electricity and Oil and Natural Gas Subsectors; the Energy GCC represents government at various levels—Federal, State, local, territorial, and tribal—as well as international partners. The 2015 Energy SSP is closely aligned with the National Infrastructure Protection Plan 2013: Partnering for Critical Infrastructure Security and Resilience (NIPP 2013) and the joint national priorities, which were developed in collaboration by representatives from all critical infrastructure sectors, including Energy.

  3. Energy Sector Cybersecurity Framework Implementation Guidance...

    Broader source: Energy.gov (indexed) [DOE]

    Department released guidance to help the energy sector establish or align existing cybersecurity risk management programs to meet the objectives of the Cybersecurity Framework...

  4. Energy Sector Cybersecurity Framework Implementation Guidance...

    Energy Savers [EERE]

    - Draft for Public Comment & Comment Submission Form (September 2014) Energy Sector Cybersecurity Framework Implementation Guidance - Draft for Public Comment & Comment Submission...

  5. Draft Energy Sector Cybersecurity Framework Implementation Guidance...

    Broader source: Energy.gov (indexed) [DOE]

    in the Federal Register, inviting the public to comment on DOE's Energy Sector Cybersecurity Framework Implementation Guidance. Comments must be received on or before October...

  6. Energy Sector Cybersecurity Framework Implementation Guidance...

    Broader source: Energy.gov (indexed) [DOE]

    invites public comment on a draft of the Energy Sector Cybersecurity Framework Implementation Guidance. Comments must be received on or before October 14, 2014. The draft document...

  7. DOE Issues Energy Sector Cyber Organization NOI

    Energy Savers [EERE]

    between the federal government and energy sector stakeholders to protect the bulk power electric grid and aid the integration of smart grid technology to enhance the...

  8. Energy Intensity Indicators: Indicators for Major Sectors

    Broader source: Energy.gov [DOE]

    This system of energy intensity indicators for total energy covers the economy as a whole and each of the major end-use sectors—transportation, industry, commercial, and residential, as well as the electric power sector. These sectors are shown in Figure 1.

  9. Energy Outlook for the Transport Sector | Department of Energy

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

    Outlook for the Transport Sector Energy Outlook for the Transport Sector Energy Outlook for the Transport Sector PDF icon deer10_karsner.pdf More Documents & Publications The Outlook for Energy: A View to 2030 The Drive for Energy Diversity and Sustainability: The Impact on Transportation Fuels and Propulsion System Portfolios Algae Biofuels Technology

  10. Energy Sector Cybersecurity Framework Implementation Guidance | Department

    Energy Savers [EERE]

    of Energy Cybersecurity Framework Implementation Guidance Energy Sector Cybersecurity Framework Implementation Guidance On January 8, 2015, the Energy Department released guidance to help the energy sector establish or align existing cybersecurity risk management programs to meet the objectives of the Cybersecurity Framework released by the National Institutes of Standards and Technology (NIST) in February 2014. The voluntary Cybersecurity Framework consists of standards, guidelines, and

  11. Partnership for Energy Sector Climate Resilience | Department of Energy

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

    Partnership for Energy Sector Climate Resilience Partnership for Energy Sector Climate Resilience The Partnership for Energy Sector Climate Resilience is an initiative to enhance U.S. energy security by improving the resilience of energy infrastructure to extreme weather and climate change impacts. The goal is to accelerate investment in technologies, practices, and policies that will enable a resilient 21st century energy system. Under this Partnership, owners and operators of energy assets

  12. Energy Department Announces New Private Sector Partnership to...

    Energy Savers [EERE]

    New Private Sector Partnership to Accelerate Renewable Energy Projects Energy Department Announces New Private Sector Partnership to Accelerate Renewable Energy Projects October 9,...

  13. Dams and Energy Sectors Interdependency Study

    Office of Environmental Management (EM)

    Type text] Dams and Energy Sectors Interdependency Study September 2011 September 2011 Page 2 Abstract The U.S. Department of Energy (DOE) and the U.S. Department of Homeland Security (DHS) collaborated to examine the interdependencies between two critical infrastructure sectors - Dams and Energy. 1 The study highlights the importance of hydroelectric power generation, with a particular emphasis on the variability of weather patterns and competing demands for water which determine the water

  14. Chapter 2 - Energy Sectors and Systems | Department of Energy

    Office of Environmental Management (EM)

    2 - Energy Sectors and Systems Chapter 2 - Energy Sectors and Systems Chapter 2 - Energy Sectors and Systems Within and between the electricity, fuels, transportation, buildings, and manufacturing sectors, increasing interconnectedness and complexity are creating opportunities and challenges that can be approached from a systems perspective. Some of the most transformational opportunities exist at the systems level. They are enabled by the ability to understand, predict, and control very large

  15. New Report Highlights Growth of America's Clean Energy Job Sector |

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

    Department of Energy Report Highlights Growth of America's Clean Energy Job Sector New Report Highlights Growth of America's Clean Energy Job Sector August 23, 2012 - 12:20pm Addthis New Report Highlights Growth of America's Clean Energy Job Sector New Report Highlights Growth of America's Clean Energy Job Sector New Report Highlights Growth of America's Clean Energy Job Sector New Report Highlights Growth of America's Clean Energy Job Sector New Report Highlights Growth of America's Clean

  16. Manufacturing Energy and Carbon Footprint - Sector: Transportation...

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

    2.4 2.6 < 0.1 Manufacturing Energy and Carbon Footprint Sector: Transportation ... Steam Distribution Losses 1 3 23 1 3 7 6 23 16 0 3 0 275 44 132 0 1 2 Conventional Boilers ...

  17. US Energy Sector Vulnerabilities to Climate Change

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

    .......................... 1 Figure 2. Climate change implications for the energy sector ..................................................................................................................... 4 Figure 3. Rate of warming in the United States by region, 1901-2011 .................................................................................................... 8 Figure 4. Wildfire disrupting electricity transmission

  18. US Energy Sector Vulnerabilities to Climate Change

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

    .......................... 1 Figure 2. Climate change implications for the energy sector ..................................................................................................................... 4 Figure 3. Rate of warming in the United States by region, 1901-2011 .................................................................................................... 8 Figure 4. Wildfire disrupting electricity transmission

  19. Energy-Sector Stakeholders Attend the Department of Energy's 2010

    Energy Savers [EERE]

    Cybersecurity for Energy Delivery Systems Peer Review | Department of Energy Energy-Sector Stakeholders Attend the Department of Energy's 2010 Cybersecurity for Energy Delivery Systems Peer Review Energy-Sector Stakeholders Attend the Department of Energy's 2010 Cybersecurity for Energy Delivery Systems Peer Review The Department of Energy conducted a Peer Review of its Cybersecurity for Energy Delivery Systems (CEDS) Research and Development Program on July 20-22, 2010 during which 28

  20. Energy-Sector Stakeholders Attend the Department of Energy's

    Office of Environmental Management (EM)

    Cybersecurity for Energy Delivery Systems Peer Review | Department of Energy Energy-Sector Stakeholders Attend the Department of Energy's Cybersecurity for Energy Delivery Systems Peer Review Energy-Sector Stakeholders Attend the Department of Energy's Cybersecurity for Energy Delivery Systems Peer Review August 15, 2011 - 1:12pm Addthis The Department of Energy conducted a Peer Review of its Cybersecurity for Energy Delivery Systems (CEDS) Research and Development Program on July 20-22,

  1. List of Companies in Geothermal Sector | Open Energy Information

    Open Energy Info (EERE)

    Geothermal Sector Jump to: navigation, search Companies in the Geothermal energy sector: Add a Company Download CSV (rows 1-212) Map of Geothermal energy companies Loading map......

  2. Roadmap to Secure Control Systems in the Energy Sector - January...

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

    Roadmap to Secure Control Systems in the Energy Sector - January 2006 Roadmap to Secure Control Systems in the Energy Sector - January 2006 This document, the Roadmap to Secure...

  3. Renewable Energy Cross Sectoral Assessments Terms of Reference...

    Open Energy Info (EERE)

    Renewable Energy Cross Sectoral Assessments Terms of Reference Jump to: navigation, search Tool Summary LAUNCH TOOL Name: Renewable Energy Cross Sectoral Assessments Terms of...

  4. Department of Energy Releases New Report on Energy Sector Vulnerablities |

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Department of Energy New Report on Energy Sector Vulnerablities Department of Energy Releases New Report on Energy Sector Vulnerablities July 11, 2013 - 7:00am Addthis News Media Contact (202) 586-4940 WASHINGTON - The U.S. Department of Energy released a new report which assesses how America's critical energy and electricity infrastructure is vulnerable to the impacts of climate change. Historically high temperatures in recent years have been accompanied by droughts and extreme heat waves,

  5. Energy Critical Infrastructure and Key Resources Sector-Specific...

    Broader source: Energy.gov (indexed) [DOE]

    The Energy Sector has developed a vision statement and six sector security goals that will be used as the framework for developing and implementing effective protective measures....

  6. Manufacturing Energy and Carbon Footprint - Sector: Iron and...

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

    - Sector: Iron and Steel (NAICS 3311, 3312), October 2012 (MECS 2006) Manufacturing Energy and Carbon Footprint - Sector: Iron and Steel (NAICS 3311, 3312), October 2012 (MECS ...

  7. U.S. Energy Sector Vulnerability Report | Department of Energy

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

    U.S. Energy Sector Vulnerability Report U.S. Energy Sector Vulnerability Report As part of the Administration's efforts to support climate change preparedness and resilience planning -- and to advance the Energy Department's goal of promoting energy security -- the Department is assessing the threats of climate change and extreme weather to the Nation' energy system. Two reports have been released that examine the current and potential future impacts of climate change and extreme weather on the

  8. Energy Intensity Changes by Sector, 1985-2011 - Alternative Measures...

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

    Changes by Sector, 1985-2011 - Alternative Measures by Type of Energy Energy Intensity Changes by Sector, 1985-2011 - Alternative Measures by Type of Energy Further insight with ...

  9. Energy Critical Infrastructure and Key Resources Sector-Specific

    Office of Environmental Management (EM)

    Energy Critical Infrastructure and Key Resources Sector-Specific Plan as input to the National Infrastructure Protection Plan (Redacted) May 2007 Department of Energy Energy Sector Government Coordinating Council Letter of Support i ii Energy Sector-Specific Plan (Redacted) Energy Sector Coordinating Councils Letter of Concurrence The National Infrastructure Protection Plan (NIPP) provides the unifying structure for the integration of federal critical infrastructures and key resources (CI/KR)

  10. List of Companies in Wind Sector | Open Energy Information

    Open Energy Info (EERE)

    Wind Sector Jump to: navigation, search WindTurbine-icon.png Companies in the Wind energy sector: Add a Company Download CSV (rows 1-1693) Map of Wind energy companies Loading...

  11. Energy Impact Illinois: Overcoming Barriers in the Multifamily Sector

    Broader source: Energy.gov [DOE]

    Presents how Energy Impact Illinois overcame barriers in the multifamily sector through financing partnerships and expert advice.

  12. U.S. Energy Information Administration (EIA) - Sector

    Annual Energy Outlook [U.S. Energy Information Administration (EIA)]

    RenewableAlternative Nuclear Sector Residential Commercial Industrial Transportation Energy Demand Other Emissions Prices Macroeconomic International Efficiency Publication...

  13. Low Carbon Society Toward 2050: Indonesia Energy Sector | Open...

    Open Energy Info (EERE)

    for Global Environmental Strategies, Mizuho Information & Research Institute - Japan, Kyoto University, Institut Teknologi Bandung (ITB) - Indonesia Sector: Energy Focus...

  14. Retrocommissioning and the Public Sector | Department of Energy

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

    Retrocommissioning and the Public Sector Retrocommissioning and the Public Sector This presentation contains information on Retrocommissioning and the Public Sector. PDF icon Presentation Microsoft Office document icon Transcript More Documents & Publications retrocommissioning_public_sector.doc Transforming Commercial Building Operations - 2013 BTO Peer Review Energy Audit and Retro-Commissioning Policies for Public and Commercial Buildings

  15. Energy Sector Cybersecurity Framework Implementation Guidance - Draft for

    Office of Environmental Management (EM)

    Public Comment & Comment Submission Form (September 2014) | Department of Energy Sector Cybersecurity Framework Implementation Guidance - Draft for Public Comment & Comment Submission Form (September 2014) Energy Sector Cybersecurity Framework Implementation Guidance - Draft for Public Comment & Comment Submission Form (September 2014) On September 12, 2014, the Department issued a Federal Register Notice announcing the availability of the Energy Sector Cybersecurity Framework

  16. Property:DeploymentSector | Open Energy Information

    Open Energy Info (EERE)

    search Property Name DeploymentSector Property Type String Description Depolyment Sector as used in cleanenergysolutions.org Allows the following values: Commercial...

  17. End-Use Sector Flowchart | Department of Energy

    Office of Environmental Management (EM)

    End-Use Sector Flowchart End-Use Sector Flowchart This system of energy intensity indicators for total energy covers the economy as a whole and each of the major end-use sectors-transportation, industry, commercial and residential-identified in Figure 1. By clicking on any of the boxes with the word "Sector" in the title will reveal the more detailed structure within that sector. PDF icon End-Use Sector Flowchart More Documents & Publications Barriers to Industrial Energy

  18. Residential Demand Sector Data, Commercial Demand Sector Data, Industrial Demand Sector Data - Annual Energy Outlook 2006

    SciTech Connect (OSTI)

    2009-01-18

    Tables describing consumption and prices by sector and census division for 2006 - includes residential demand, commercial demand, and industrial demand

  19. Static Sankey Diagram Full Sector Manufacturing | Department of Energy

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

    Full Sector Manufacturing Static Sankey Diagram Full Sector Manufacturing The U.S. Manufacturing Sector Static Sankey diagram shows how total primary energy is used by U.S. manufacturing plants. Click on the Onsite Generation, Process Energy or Nonprocess Energy thumbnails below the diagram to see further detail on energy flows in manufacturing. Also, see the Dynamic Manufacturing Energy Sankey Tool to pan, zoom, and customize the manufacturing Sankey data and compare energy consumption across

  20. DOE has published the revised 2010 Energy Sector Specific Plan

    Office of Energy Efficiency and Renewable Energy (EERE)

    The Department of Energy announces the publication of the Energy Sector-Specific Plan: An Annex to the National Infrastructure Protection Plan 2010.

  1. User:GregZiebold/Sector test | Open Energy Information

    Open Energy Info (EERE)

    search Query all sector types for Companies: Bioenergy Biofuels Biomass Buildings Carbon Efficiency Geothermal energy Hydro Hydrogen Marine and Hydrokinetic Ocean Renewable Energy...

  2. Energy Efficiency Financing for Public Sector Projects | Department...

    Broader source: Energy.gov (indexed) [DOE]

    Info Sector Name State Administrator California Energy Commission Website http:www.energy.ca.govefficiencyfinancingindex.html State California Program Type Loan Program...

  3. Dams and Energy Sectors Interdependency Study, September 2011 | Department

    Energy Savers [EERE]

    of Energy Dams and Energy Sectors Interdependency Study, September 2011 Dams and Energy Sectors Interdependency Study, September 2011 The U.S. Department of Energy (DOE) and the U.S. Department of Homeland Security (DHS) collaborated to examine the interdependencies between two critical infrastructure sectors - Dams and Energy. The study highlights the importance of hydroelectric power generation, with a particular emphasis on the variability of weather patterns and competing demands for

  4. Roadmap to Secure Control Systems in the Energy Sector

    Energy Savers [EERE]

    Roadmap to Secure Control Systems in the Energy Sector -  - Foreword T his document, the Roadmap to Secure Control Systems in the Energy Sector, outlines a coherent plan for improing cyber security in the energy sector. It is the result of an unprecedented collaboration between the energy sector and goernment to identify concrete steps to secure control systems used in the electricity, oil, and natural gas sectors oer the next ten years. The Roadmap proides a strategic

  5. DOE Issues Energy Sector Cyber Organization NOI, Feb 2010

    Broader source: Energy.gov [DOE]

    The Department of Energys (DOE) National Energy Technology Laboratory (NETL) announced on Jan. 7 that it intends to issue a Funding Opportunity Announcement (FOA) for a National Energy Sector...

  6. Energy Department Announces New Private Sector Partnership to Accelerate

    Office of Environmental Management (EM)

    Renewable Energy Projects | Department of Energy New Private Sector Partnership to Accelerate Renewable Energy Projects Energy Department Announces New Private Sector Partnership to Accelerate Renewable Energy Projects October 9, 2009 - 1:09pm Addthis U.S. Energy Secretary Steven Chu today announced the Department of Energy (DOE) will provide up to $750 million in funding from the American Recovery and Reinvestment Act to help accelerate the development of conventional renewable energy

  7. Interacting vacuum energy in the dark sector

    SciTech Connect (OSTI)

    Chimento, L. P.; Carneiro, S.

    2015-03-26

    We analyse three cosmological scenarios with interaction in the dark sector, which are particular cases of a general expression for the energy flux from vacuum to matter. In the first case the interaction leads to a transition from an unstable de Sitter phase to a radiation dominated universe, avoiding in this way the initial singularity. In the second case the interaction gives rise to a slow-roll power-law inflation. Finally, the third scenario is a concordance model for the late-time universe, with the vacuum term decaying into cold dark matter. We identify the physics behind these forms of interaction and show that they can be described as particular types of the modified Chaplygin gas.

  8. Commercial Sector Financing Needs and Opportunities | Department of Energy

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

    Commercial Sector Financing Needs and Opportunities Commercial Sector Financing Needs and Opportunities Large commercial buildings use a great deal of energy and often offer attractive payback periods for energy efficiency investments. The clearest incentives in the large commercial building sector are usually for investment in buildings where the owner pays the energy bills or the tenant has a lease term that is longer than the payback period on the project. If the owner of the facility is

  9. Private Sector Outreach and Partnerships | Department of Energy

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

    The division's domestic capabilities have been greatly enhanced by the relationships that ... The relationships ISER maintains with energy sector owners and operators and public ...

  10. Commercial Sector Demand Module of the National Energy Modeling...

    Gasoline and Diesel Fuel Update (EIA)

    the State Energy Data System (SEDS) historical commercial sector consumption, applying an additive correction term to ensure that simulated model results correspond to published...

  11. Climate Change Mitigation in the Energy and Forestry Sectors...

    Open Energy Info (EERE)

    of Developing Countries Jump to: navigation, search Tool Summary LAUNCH TOOL Name: Climate Change Mitigation in the Energy and Forestry Sectors of Developing Countries...

  12. Category:Public Sectors | Open Energy Information

    Open Energy Info (EERE)

    no pages or media. Retrieved from "http:en.openei.orgwindex.php?titleCategory:PublicSectors&oldid272249" Feedback Contact needs updating Image needs updating...

  13. Property:Sector | Open Energy Information

    Open Energy Info (EERE)

    is a property of type Page. Subproperties This property has the following 1 subproperty: G Green Economy Toolbox Pages using the property "Sector" Showing 25 pages using this...

  14. Fact #792: August 12, 2013 Energy Consumption by Sector and Energy...

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

    2: August 12, 2013 Energy Consumption by Sector and Energy Source, 1982 and 2012 Fact 792: August 12, 2013 Energy Consumption by Sector and Energy Source, 1982 and 2012 In the...

  15. Manufacturing Energy and Carbon Footprint - Sector: Iron and Steel (NAICS

    Office of Environmental Management (EM)

    3311, 3312), October 2012 (MECS 2006) | Department of Energy - Sector: Iron and Steel (NAICS 3311, 3312), October 2012 (MECS 2006) Manufacturing Energy and Carbon Footprint - Sector: Iron and Steel (NAICS 3311, 3312), October 2012 (MECS 2006) PDF icon steel_footprint_2012.pdf More Documents & Publications MECS 2006 - Iron and Steel Iron and Steel (2010 MECS) MECS 2006 - Cement

  16. Restructuring our Transportation Sector | Department of Energy

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

    Restructuring our Transportation Sector Restructuring our Transportation Sector 2010 DOE Vehicle Technologies and Hydrogen Programs Annual Merit Review and Peer Evaluation Meeting, June 7-11, 2010 -- Washington D.C. PDF icon pln001_rogers_2010_o.pdf More Documents & Publications Navistar-Driving efficiency with integrated technology Vehicle Technologies Office FY 2016 Budget At-A-Glance Overview of the DOE High Efficiency Engine Technologies R&D

  17. NREL: Energy Analysis: Electric Sector Integration

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Electric Sector Integration Integrating higher levels of renewable resources into the U.S. electricity system could pose challenges to the operability of the nation's grid. NREL's electric sector integration analysis work investigates the potential impacts of expanding renewable technology deployment on grid operations and infrastructure expansion including: Feasibility of higher levels of renewable electricity generation. Options for increasing electric system flexibility to accommodate higher

  18. Property:ProgramSector | Open Energy Information

    Open Energy Info (EERE)

    + AGI-32 + Energy + ANL Wind Power Forecasting and Electricity Markets + Energy + APEC-Alternative Transport Fuels: Implementation Guidelines + Energy + APFED-Good Practice...

  19. United States Industrial Sector Energy End Use Analysis

    SciTech Connect (OSTI)

    Shehabi, Arman; Morrow, William R.; Masanet, Eric

    2012-05-11

    The United States Department of Energys (DOE) Energy Information Administration (EIA) conducts the Manufacturing Energy Consumption Survey (MECS) to provide detailed data on energy consumption in the manufacturing sector. The survey is a sample of approximately 15,000 manufacturing establishments selected from the Economic Census - Manufacturing Sector. MECS provides statistics on the consumption of energy by end uses (e.g., boilers, process, electric drives, etc.) disaggregated by North American Industry Classification System (NAICS) categories. The manufacturing sector (NAICS Sector 31-33) consists of all manufacturing establishments in the 50 States and the District of Columbia. According to the NAICS, the manufacturing sector comprises establishments engaged in the mechanical, physical, or chemical transformation of materials, substances, or components into new products. The establishments are physical facilities such as plants, factories, or mills. For many of the sectors in the MECS datasets, information is missing because the reported energy use is less than 0.5 units or BTUs, or is withheld to avoid disclosing data for individual establishments, or is withheld because the standard error is greater than 50%. We infer what the missing information likely are using several approximations techniques. First, much of the missing data can be easily calculated by adding or subtracting other values reported by MECS. If this is not possible (e.g. two data are missing), we look at historic MECS reports to help identify the breakdown of energy use in the past and assume it remained the same for the current MECS. Lastly, if historic data is also missing, we assume that 3 digit NAICS classifications predict energy use in their 4, 5, or 6 digit NAICS sub-classifications, or vice versa. Along with addressing data gaps, end use energy is disaggregated beyond the specified MECS allocations using additional industry specific energy consumption data. The result is a completed table of energy end use by sector with mechanical drives broken down by pumps, fans, compressed air, and drives.

  20. Roadmap to Secure Control Systems in the Energy Sector 2006 ...

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

    Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation to the 2008 ieRoadmap Workshop Presentation by Hank Kenchington on the 2006 roadmap to secure control ...

  1. Slideshow: Innovation in the Manufacturing Sector | Department of Energy

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

    Slideshow: Innovation in the Manufacturing Sector Slideshow: Innovation in the Manufacturing Sector December 12, 2013 - 5:00pm Addthis AEMC Summit 1 of 12 AEMC Summit In partnership with the Council on Competitiveness, the Energy Department hosted the first American Energy and Manufacturing Competitiveness (AEMC) Summit in Washington, DC. A culmination of a series of dialogues held across the country over the past year, the summit focused on how we can increase U.S. competitiveness in clean

  2. Roadmap to Secure Control Systems in the Energy Sector - January 2006 |

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

    Department of Energy Energy Sector - January 2006 Roadmap to Secure Control Systems in the Energy Sector - January 2006 This document, the Roadmap to Secure Control Systems in the Energy Sector, outlines a coherent plan for improving cyber security in the energy sector. It is the result of an unprecedented collaboration between the energy sector and government to identify concrete steps to secure control systems used in the electricity, oil, and natural gas sectors over the next ten years.

  3. Energy Sector-Specific Plan: An Annex to the National Infrastructure

    Energy Savers [EERE]

    Protection Plan | Department of Energy Sector-Specific Plan: An Annex to the National Infrastructure Protection Plan Energy Sector-Specific Plan: An Annex to the National Infrastructure Protection Plan In its role as the lead Sector-Specific Agency for the Energy Sector, the Department of Energy has worked closely with dozens of government and industry partners to prepare this updated 2010 Energy Sector-Specific Plan (SSP). Much of that work was conducted through the two Energy Sector

  4. Climate Change and the U.S. Energy Sector: Regional Vulnerabilities...

    Energy Savers [EERE]

    Change and the U.S. Energy Sector: Regional Vulnerabilities and Resilience Solutions Climate Change and the U.S. Energy Sector: Regional Vulnerabilities and Resilience Solutions ...

  5. Number of Large Energy User Manufacturing Facilities by Sector and State (with Industrial Energy Consumption by State and Manufacturing Energy Consumption by Sector)

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

    Number of Large Energy User Manufacturing Facilities by Sector and State (with Industrial Energy Consumption by State and Manufacturing Energy Consumption by Sector) State Industrial Site Energy Consumption (TBtu) by State in 2010* Estimated Number of Large Energy User Manufacturing Facilities** by Sector (NAICS Code) and by State in 2005 Food Manufacturing & Beverage and Tobacco Product Manufacturing Wood Product Manufacturing & Paper Manufacturing Petroleum and Coal Products

  6. Fact #792: August 12, 2013 Energy Consumption by Sector and Energy Source,

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

    1982 and 2012 | Department of Energy 2: August 12, 2013 Energy Consumption by Sector and Energy Source, 1982 and 2012 Fact #792: August 12, 2013 Energy Consumption by Sector and Energy Source, 1982 and 2012 In the last 30 years, overall energy consumption has grown by about 22 quadrillion Btu. The share of energy consumption by the transportation sector has seen modest growth in that time - from about 26% to 28% of the energy consumed. The electric utility sector saw the greatest increase

  7. Annual Energy Outlook 2015 Modeling updates in the Transportation sector

    Gasoline and Diesel Fuel Update (EIA)

    For AEO2015 Working Group July 30, 2014 | Washington, DC By Nicholas Chase, Trisha Hutchins, John Maples Office of Energy Consumption and Efficiency Analysis Modeling updates in the transportation sector Data updates 2 * Update historical fuel consumption data to latest state energy data (2011), annual national data from Monthly Energy Review (2012), and most recent Short-Term Energy Outlook * Update historical light-duty vehicle attribute data through 2013 (pending) * Update historical

  8. Nexus of Energy Use and Technology in the Buildings Sector

    Gasoline and Diesel Fuel Update (EIA)

    Nexus of Energy Use and Technology in the Buildings Sector EIA Energy Conference July 15, 2014 | Washington, DC Tom Leckey, EIA Director, Office of Energy Consumption and Efficiency Statistics 2. Select segments 1. Select Primary Sampling Units (PSUs) - counties or groups of counties Main St Diagonal Ave 3. Select buildings How is CBECS Conducted? Nexus of Energy Use and and Technology, Buildings July 15, 2014 2 * No comprehensive source of buildings exists * Area frame - Randomly select small,

  9. Working to Achieve Cybersecurity in the Energy Sector | Department of

    Broader source: Energy.gov (indexed) [DOE]

    Energy Presentation covers cybersecurity in the energy sector and is given at the Spring 2011 Federal Utility Partnership Working Group (FUPWG) meeting. PDF icon fupwg_spring11_wells.pdf More Documents & Publications DOE/OE National SCADA Test Bed Fiscal Year 2009 Work Plan Cybersecurity for Energy Delivery Systems 2010 Peer Review Cybersecurity for Energy Delivery Systems (CEDS) Fact Sheets

  10. Category:Sectors | Open Energy Information

    Open Energy Info (EERE)

    are in this category, out of 18 total. B Bioenergy Biofuels Biomass Buildings C Carbon E Efficiency G Geothermal energy H Hydro Hydrogen Hydropower M Marine and Hydrokinetic O...

  11. Public Sector Energy Efficiency Aggregation Program

    Broader source: Energy.gov [DOE]

    Please note that, like all Illinois Energy Now programs, the Aggregation Program is subject to the state appropriation process, and no funds can be committed or released until a final budget is...

  12. On-Line Tool to Boost Implementation of Energy Sector Roadmap for Control

    Energy Savers [EERE]

    Systems | Department of Energy On-Line Tool to Boost Implementation of Energy Sector Roadmap for Control Systems On-Line Tool to Boost Implementation of Energy Sector Roadmap for Control Systems News Release: Implementating the Roadmap to Secure Control Systems in the Energy Sector PDF icon On-Line Tool to Boost Implementation of Energy Sector Roadmap for Control Systems More Documents & Publications Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation to the 2008

  13. Infrastructure opportunities in South America: Energy sector. Export trade information

    SciTech Connect (OSTI)

    1995-06-01

    The report, conducted by CG/LA, Inc., was funded by the U.S. Trade and Development Agency. The report was assembled for the South American Infrastructure Conference held in New Orleans. It contains a regional overview of infrastructure activities in ten countries represented at the conference. Also covered are project listings in five sectors, including Energy, Transportation, Environment, Telecommunications, and Industry. The study covers TDA case studies as well as project financeability. The ten countries covered in the report include the following: Argentina, Bolivia, Brazil, Chile, Colombia, Ecuador, Paraguay, Peru, Uruguay, and Venezuela. This volume focuses on the Energy Sector in South America.

  14. Secure Control Systems for the Energy Sector

    SciTech Connect (OSTI)

    Smith, Rhett; Campbell, Jack; Hadley, Mark

    2012-03-31

    Schweitzer Engineering Laboratories (SEL) will conduct the Hallmark Project to address the need to reduce the risk of energy disruptions because of cyber incidents on control systems. The goals is to develop solutions that can be both applied to existing control systems and designed into new control systems to add the security measures needed to mitigate energy network vulnerabilities. The scope of the Hallmark Project contains four primary elements: 1. Technology transfer of the Secure Supervisory Control and Data Acquisition (SCADA) Communications Protocol (SSCP) from Pacific Northwest National Laboratories (PNNL) to Schweitzer Engineering Laboratories (SEL). The project shall use this technology to develop a Federal Information Processing Standard (FIPS) 140-2 compliant original equipment manufacturer (OEM) module to be called a Cryptographic Daughter Card (CDC) with the ability to directly connect to any PC enabling that computer to securely communicate across serial to field devices. Validate the OEM capabilities with another vendor. 2. Development of a Link Authenticator Module (LAM) using the FIPS 140-2 validated Secure SCADA Communications Protocol (SSCP) CDC module with a central management software kit. 3. Validation of the CDC and Link Authenticator modules via laboratory and field tests. 4. Creation of documents that record the impact of the Link Authenticator to the operators of control systems and on the control system itself. The information in the documents can assist others with technology deployment and maintenance.

  15. Energy Intensity Changes by Sector, 1985-2011 - Alternative Measures by

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

    Type of Energy | Department of Energy Changes by Sector, 1985-2011 - Alternative Measures by Type of Energy Energy Intensity Changes by Sector, 1985-2011 - Alternative Measures by Type of Energy Further insight with regard to the comparison of intensity changes by sector can be gained by looking at how they differ with respect to different definitions of energy use. Source energy attributes all the energy used for electricity generation and transmission to the specific end-use sector,

  16. Workforce Training for the Electric Power Sector | Department of Energy

    Broader source: Energy.gov (indexed) [DOE]

    04-08-2010_SG_Workforce_Selections.pdf More Documents & Publications Workforce Training for the Electric Power Sector: Awards Energy & Manufacturing Workforce Training Topics List - Version 1.7 (02.11.14) Microsoft Word - PSRP Updates 6-25-10_v2

  17. Nepal-Sectoral Climate Impacts Economic Assessment | Open Energy...

    Open Energy Info (EERE)

    Nepal-Sectoral Climate Impacts Economic Assessment (Redirected from Nepal Sectoral Climate impacts Economic Assessment) Jump to: navigation, search Name Nepal Sectoral Climate...

  18. Energy Efficiency Services Sector: Workforce Size and Expectations for Growth

    SciTech Connect (OSTI)

    Goldman, Charles; Fuller, Merrian C.; Stuart, Elizabeth; Peters, Jane S.; McRae, Marjorie; Albers, Nathaniel; Lutzenhiser, Susan; Spahic, Mersiha

    2010-03-22

    The energy efficiency services sector (EESS) is poised to become an increasingly important part of the U.S. economy. Climate change and energy supply concerns, volatile and increasing energy prices, and a desire for greater energy independence have led many state and national leaders to support an increasingly prominent role for energy efficiency in U.S. energy policy. The national economic recession has also helped to boost the visibility of energy efficiency, as part of a strategy to support economic recovery. We expect investment in energy efficiency to increase dramatically both in the near-term and through 2020 and beyond. This increase will come both from public support, such as the American Recovery and Reinvestment Act (ARRA) and significant increases in utility ratepayer funds directed toward efficiency, and also from increased private spending due to codes and standards, increasing energy prices, and voluntary standards for industry. Given the growing attention on energy efficiency, there is a concern among policy makers, program administrators, and others that there is an insufficiently trained workforce in place to meet the energy efficiency goals being put in place by local, state, and federal policy. To understand the likelihood of a potential workforce gap and appropriate response strategies, one needs to understand the size, composition, and potential for growth of the EESS. We use a bottom-up approach based upon almost 300 interviews with program administrators, education and training providers, and a variety of EESS employers and trade associations; communications with over 50 sector experts; as well as an extensive literature review. We attempt to provide insight into key aspects of the EESS by describing the current job composition, the current workforce size, our projections for sector growth through 2020, and key issues that may limit this growth.

  19. Energy and water sector policy strategies for drought mitigation.

    SciTech Connect (OSTI)

    Kelic, Andjelka; Vugrin, Eric D.; Loose, Verne W.; Vargas, Vanessa N.

    2009-03-01

    Tensions between the energy and water sectors occur when demand for electric power is high and water supply levels are low. There are several regions of the country, such as the western and southwestern states, where the confluence of energy and water is always strained due to population growth. However, for much of the country, this tension occurs at particular times of year (e.g., summer) or when a region is suffering from drought conditions. This report discusses prior work on the interdependencies between energy and water. It identifies the types of power plants that are most likely to be susceptible to water shortages, the regions of the country where this is most likely to occur, and policy options that can be applied in both the energy and water sectors to address the issue. The policy options are designed to be applied in the near term, applicable to all areas of the country, and to ease the tension between the energy and water sectors by addressing peak power demand or decreased water supply.

  20. Solar energy research and development: federal and private sector roles

    SciTech Connect (OSTI)

    Not Available

    1982-09-01

    The Energy Research Advisory Board convened a Solar R and D Panel to determine the status of the solar industry and solar R and D in the United States and to recommend to DOE appropriate roles for the Federal and private sectors. The Panel's report acknowledges the new Administration policy reorienting the Federal role in energy development to long-term, high-risk, high-payoff R and D, and leaving commercialization to the private sector. The Panel's recommendations are further predicated on an assumption of continued, substantially reduced funding in the near-term. The Panel found that solar energy technologies have progressed significantly in the past 10 years and represent a group of highly promising energy options for the United States. However, it also found the solar industry to be in a precarious condition, fluctuating energy demand and prices, and uncertain Federal tax and regulatory policies. The Business Energy and Residential Tax Credits are essential to the near-term health of the solar industry. Commercialization has already begun for some solar technologies; for others, decreases in Federal funding will result in a slowdown or termination. The primary Federal roles in solar R and D should be in support of basic and applied research, high-risk, high-payoff technology development and other necessary research for which there are insufficient market incentives. The Federal Government should also move strongly to transfer technology to the private sector for near-commerical technologies. Large demonstration and commercialization projects cannot be justified for Federal funding under current economic conditions. These should be pursued by the private sector. The Panel examined seven technology areas and made specific findings and recommendations for each.

  1. Why is energy use rising in the freight sector?

    SciTech Connect (OSTI)

    Mintz, M.; Vyas, A.D.

    1991-12-31

    Trends in transportation sector energy use and carbon dioxide emissions are analyzed with an emphasis on three freight modes -- rail, truck, and marine. A recent set of energy use projections is presented and freight mode energy characteristics are discussed. Transportation sector energy use, which nearly doubled between 1960 and 1985, is projected to grow more slowly during the period 1985{endash}2010. Most of the growth is projected to come from non-personal modes (freight and commercial air). Trends in freight mode energy intensities are discussed and a variety of factors behind these trends are analyzed. Rail and marine modes improved their energy intensities during sudden fuel price rises of the 1970s. Though there is room for further technological improvement, long power plant life cycles preclude rapid penetration of new technologies. Thus, energy intensities in these modes are more likely to improve through operational changes. Because of relatively stable fuel prices, the energy share of truck operating expenses is likely to remain low. Coupled with increasing labor costs, this portends only modest improvements in truck energy efficiency over the next two decades.

  2. Why is energy use rising in the freight sector

    SciTech Connect (OSTI)

    Mintz, M.; Vyas, A.D.

    1991-01-01

    Trends in transportation sector energy use and carbon dioxide emissions are analyzed with an emphasis on three freight modes -- rail, truck, and marine. A recent set of energy use projections is presented and freight mode energy characteristics are discussed. Transportation sector energy use, which nearly doubled between 1960 and 1985, is projected to grow more slowly during the period 1985{endash}2010. Most of the growth is projected to come from non-personal modes (freight and commercial air). Trends in freight mode energy intensities are discussed and a variety of factors behind these trends are analyzed. Rail and marine modes improved their energy intensities during sudden fuel price rises of the 1970s. Though there is room for further technological improvement, long power plant life cycles preclude rapid penetration of new technologies. Thus, energy intensities in these modes are more likely to improve through operational changes. Because of relatively stable fuel prices, the energy share of truck operating expenses is likely to remain low. Coupled with increasing labor costs, this portends only modest improvements in truck energy efficiency over the next two decades.

  3. Energy Efficiency Services Sector: Workforce Education and Training Needs

    SciTech Connect (OSTI)

    Goldman, Charles A.; Peters, Jane S.; Albers, Nathaniel; Stuart, Elizabeth; Fuller, Merrian C.

    2010-03-19

    This report provides a baseline assessment of the current state of energy efficiency-related education and training programs and analyzes training and education needs to support expected growth in the energy efficiency services workforce. In the last year, there has been a significant increase in funding for 'green job' training and workforce development (including energy efficiency), through the American Recovery and Reinvestment Act (ARRA). Key segments of the energy efficiency services sector (EESS) have experienced significant growth during the past several years, and this growth is projected to continue and accelerate over the next decade. In a companion study (Goldman et al. 2009), our research team estimated that the EESS will increase two- to four-fold by 2020, to 220,000 person-years of employment (PYE) (low-growth scenario) or up to 380,000 PYE (high-growth scenario), which may represent as many as 1.3 million individuals. In assessing energy efficiency workforce education and training needs, we focus on energy-efficiency services-related jobs that are required to improve the efficiency of residential and nonresidential buildings. Figure ES-1 shows the market value chain for the EESS, sub-sectors included in this study, as well as the types of market players and specific occupations. Our assessment does not include the manufacturing, wholesale, and retail distribution subsectors, or energy efficiency-focused operations and maintenance performed by facility managers.

  4. Fact #689: August 22, 2011 Energy Use by Sector and Source | Department of

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

    Energy 9: August 22, 2011 Energy Use by Sector and Source Fact #689: August 22, 2011 Energy Use by Sector and Source The transportation sector consumed 28% of U.S. energy in 2010, nearly all of it (93.5%) in petroleum use. The industrial sector used about 40% petroleum and 40% natural gas. The electric utility sector used little petroleum, but was dependent on coal for nearly half of the energy it consumed. Renewables, such as biofuels for transportation, were being used in every sector in

  5. End use energy consumption data base: transportation sector

    SciTech Connect (OSTI)

    Hooker, J.N.; Rose, A.B.; Greene, D.L.

    1980-02-01

    The transportation fuel and energy use estimates developed a Oak Ridge National Laboratory (ORNL) for the End Use Energy Consumption Data Base are documented. The total data base contains estimates of energy use in the United States broken down into many categories within all sectors of the economy: agriculture, mining, construction, manufacturing, commerce, the household, electric utilities, and transportation. The transportation data provided by ORNL generally cover each of the 10 years from 1967 through 1976 (occasionally 1977 and 1978), with omissions in some models. The estimtes are broken down by mode of transport, fuel, region and State, sector of the economy providing transportation, and by the use to which it is put, and, in the case of automobile and bus travel, by the income of the traveler. Fuel types include natural gas, motor and aviation gasoline, residual and diesel oil, liuqefied propane, liquefied butane, and naphtha- and kerosene-type jet engine fuels. Electricity use is also estimated. The mode, fuel, sector, and use categories themselves subsume one, two, or three levels of subcategories, resulting in a very detailed categorization and definitive accounting.

  6. Static Sankey Diagram of Process Energy in U.S. Manufacturing Sector |

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

    Department of Energy Process Energy in U.S. Manufacturing Sector Static Sankey Diagram of Process Energy in U.S. Manufacturing Sector The Process Energy Static Sankey diagram shows how energy is used directly for production by U.S. manufacturing plants. Click on the Full Sector, Onsite Generation, and Nonprocess Energy thumbnails below the diagram to see further detail on energy flows in manufacturing. Also, see the Dynamic Manufacturing Energy Sankey Tool to pan, zoom, and customize the

  7. Static Sankey Diagram of Nonprocess Energy in U.S. Manufacturing Sector |

    Energy Savers [EERE]

    Department of Energy Nonprocess Energy in U.S. Manufacturing Sector Static Sankey Diagram of Nonprocess Energy in U.S. Manufacturing Sector The Nonprocess Energy Static Sankey diagram shows how energy is used for supporting functions by U.S. manufacturing plants. Click on the Full Sector, Onsite Generation, and Process Energy thumbnails below the diagram to see further detail on energy flows in manufacturing. Also, see the Dynamic Manufacturing Energy Sankey Tool to pan, zoom, and customize

  8. Static Sankey Diagram of Process Energy in U.S. Manufacturing Sector |

    Energy Savers [EERE]

    Department of Energy Static Sankey Diagram of Process Energy in U.S. Manufacturing Sector Static Sankey Diagram of Process Energy in U.S. Manufacturing Sector The Process Energy Static Sankey diagram shows how energy is used directly for production by U.S. manufacturing plants. Click on the Full Sector, Onsite Generation, and Nonprocess Energy thumbnails below the diagram to see further detail on energy flows in manufacturing. Also, see the Dynamic Manufacturing Energy Sankey Tool to pan,

  9. ImSET: Impact of Sector Energy Technologies

    SciTech Connect (OSTI)

    Roop, Joseph M.; Scott, Michael J.; Schultz, Robert W.

    2005-07-19

    This version of the Impact of Sector Energy Technologies (ImSET) model represents the ''next generation'' of the previously developed Visual Basic model (ImBUILD 2.0) that was developed in 2003 to estimate the macroeconomic impacts of energy-efficient technology in buildings. More specifically, a special-purpose version of the 1997 benchmark national Input-Output (I-O) model was designed specifically to estimate the national employment and income effects of the deployment of Office of Energy Efficiency and Renewable Energy (EERE) -developed energy-saving technologies. In comparison with the previous versions of the model, this version allows for more complete and automated analysis of the essential features of energy efficiency investments in buildings, industry, transportation, and the electric power sectors. This version also incorporates improvements in the treatment of operations and maintenance costs, and improves the treatment of financing of investment options. ImSET is also easier to use than extant macroeconomic simulation models and incorporates information developed by each of the EERE offices as part of the requirements of the Government Performance and Results Act.

  10. Energy Sector-Specific Plan: An Annex to the National Infrastructure...

    Broader source: Energy.gov (indexed) [DOE]

    In its role as the lead Sector-Specific Agency for the Energy Sector, the Department of Energy has worked closely with dozens of government and industry partners to prepare this...

  11. Roadmap to Secure Control Systems in the Energy Sector- January 2006

    Broader source: Energy.gov [DOE]

    This document, the Roadmap to Secure Control Systems in the Energy Sector, outlines a coherent plan for improving cyber security in the energy sector. It is the result of an unprecedented...

  12. Industrial Sector Energy Demand: Revisions for Non-Energy-Intensive Manufacturing (released in AEO2007)

    Reports and Publications (EIA)

    2007-01-01

    For the industrial sector, the Energy Information Administration's (EIA) analysis and projection efforts generally have focused on the energy-intensive industriesfood, bulk chemicals, refining, glass, cement, steel, and aluminumwhere energy cost averages 4.8% of annual operating cost. Detailed process flows and energy intensity indicators have been developed for narrowly defined industry groups in the energy-intensive manufacturing sector. The non-energy-intensive manufacturing industries, where energy cost averages 1.9% of annual operating cost, previously have received somewhat less attention, however. In Annual Energy Outlook 2006 (AEO), energy demand projections were provided for two broadly aggregated industry groups in the non-energy-intensive manufacturing sector: metal-based durables and other non-energy-intensive. In the AEO2006 projections, the two groups accounted for more than 50% of the projected increase in industrial natural gas consumption from 2004 to 2030.

  13. Energy Critical Infrastructure and Key Resources Sector-Specific Plan as

    Energy Savers [EERE]

    input to the National Infrastructure Protection Plan (Redacted) | Department of Energy Energy Critical Infrastructure and Key Resources Sector-Specific Plan as input to the National Infrastructure Protection Plan (Redacted) Energy Critical Infrastructure and Key Resources Sector-Specific Plan as input to the National Infrastructure Protection Plan (Redacted) The Energy Sector has developed a vision statement and six sector security goals that will be used as the framework for developing and

  14. South Africa-Danish Government Sector Programmes | Open Energy...

    Open Energy Info (EERE)

    Sector Programmes Jump to: navigation, search Name South Africa-Danish Government Sector Programmes AgencyCompany Organization Danish Government Partner Danish Ministry for...

  15. List of Companies in Hydrogen Sector | Open Energy Information

    Open Energy Info (EERE)

    Companies in Hydrogen Sector Jump to: navigation, search Companies in the Hydrogen sector: Add a Company Download CSV (rows 1-196) Map of Hydrogen companies Loading map......

  16. Nepal-Sectoral Climate Impacts Economic Assessment | Open Energy...

    Open Energy Info (EERE)

    Nepal-Sectoral Climate Impacts Economic Assessment Jump to: navigation, search Name Nepal Sectoral Climate impacts Economic Assessment AgencyCompany Organization Climate and...

  17. Energy Use in China: Sectoral Trends and Future Outlook

    SciTech Connect (OSTI)

    Zhou, Nan; McNeil, Michael A.; Fridley, David; Lin, Jiang; Price,Lynn; de la Rue du Can, Stephane; Sathaye, Jayant; Levine, Mark

    2007-10-04

    This report provides a detailed, bottom-up analysis ofenergy consumption in China. It recalibrates official Chinese governmentstatistics by reallocating primary energy into categories more commonlyused in international comparisons. It also provides an analysis of trendsin sectoral energy consumption over the past decades. Finally, itassesses the future outlook for the critical period extending to 2020,based on assumptions of likely patterns of economic activity,availability of energy services, and energy intensities. The followingare some highlights of the study's findings: * A reallocation of sectorenergy consumption from the 2000 official Chinese government statisticsfinds that: * Buildings account for 25 percent of primary energy, insteadof 19 percent * Industry accounts for 61 percent of energy instead of 69percent * Industrial energy made a large and unexpected leap between2000-2005, growing by an astonishing 50 percent in the 3 years between2002 and 2005. * Energy consumption in the iron and steel industry was 40percent higher than predicted * Energy consumption in the cement industrywas 54 percent higher than predicted * Overall energy intensity in theindustrial sector grew between 2000 and 2003. This is largely due tointernal shifts towards the most energy-intensive sub-sectors, an effectwhich more than counterbalances the impact of efficiency increases. *Industry accounted for 63 percent of total primary energy consumption in2005 - it is expected to continue to dominate energy consumption through2020, dropping only to 60 percent by that year. * Even assuming thatgrowth rates in 2005-2020 will return to the levels of 2000-2003,industrial energy will grow from 42 EJ in 2005 to 72 EJ in 2020. * Thepercentage of transport energy used to carry passengers (instead offreight) will double from 37 percent to 52 percent between 2000 to 2020,.Much of this increase is due to private car ownership, which willincrease by a factor of 15 from 5.1 million in 2000 to 77 million in2020. * Residential appliance ownership will show signs of saturation inurban households. The increase in residential energy consumption will belargely driven by urbanization, since rural homes will continue to havelow consumption levels. In urban households, the size of appliances willincrease, but its effect will be moderated by efficiency improvements,partially driven by government standards. * Commercial energy increaseswill be driven both by increases in floor space and by increases inpenetration of major end uses such as heating and cooling. Theseincreases will be moderated somewhat, however, by technology changes,such as increased use of heat pumps. * China's Medium- and Long-TermDevelopment plan drafted by the central government and published in 2004calls for a quadrupling of GDP in the period from 2000-2020 with only adoubling in energy consumption during the same period. A bottom-upanalysis with likely efficiency improvements finds that energyconsumption will likely exceed the goal by 26.12 EJ, or 28 percent.Achievements of these goals will there fore require a more aggressivepolicy of encouraging energy efficiency.

  18. Fact #582: August 3, 2009 Energy Shares by Sector and Source | Department

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

    of Energy 2: August 3, 2009 Energy Shares by Sector and Source Fact #582: August 3, 2009 Energy Shares by Sector and Source The transportation sector consumed about 28% of U.S. energy in 2008, nearly all of it (95%) in petroleum use. The industrial sector used about 40% petroleum and 40% natural gas. The electric utility sector used little petroleum, but was dependent on coal for more than half of the energy it consumed. Renewables, such as biofuels for transportation, were being used in

  19. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    3.3 Commercial Sector Expenditures March 2012 3.3.3 Commercial Buildings Aggregate Energy Expenditures, by Year and Major Fuel Type ($2010 Billion) (1) Electricity Natural Gas Petroleum (2) Total 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 148.6 37.0 17.0 202.6 148.9 37.2 17.1 203.2 145.9 36.2

  20. Major models and data sources for residential and commercial sector energy conservation analysis. Final report

    SciTech Connect (OSTI)

    Not Available

    1980-09-01

    Major models and data sources are reviewed that can be used for energy-conservation analysis in the residential and commercial sectors to provide an introduction to the information that can or is available to DOE in order to further its efforts in analyzing and quantifying their policy and program requirements. Models and data sources examined in the residential sector are: ORNL Residential Energy Model; BECOM; NEPOOL; MATH/CHRDS; NIECS; Energy Consumption Data Base: Household Sector; Patterns of Energy Use by Electrical Appliances Data Base; Annual Housing Survey; 1970 Census of Housing; AIA Research Corporation Data Base; RECS; Solar Market Development Model; and ORNL Buildings Energy Use Data Book. Models and data sources examined in the commercial sector are: ORNL Commercial Sector Model of Energy Demand; BECOM; NEPOOL; Energy Consumption Data Base: Commercial Sector; F.W. Dodge Data Base; NFIB Energy Report for Small Businesses; ADL Commercial Sector Energy Use Data Base; AIA Research Corporation Data Base; Nonresidential Buildings Surveys of Energy Consumption; General Electric Co: Commercial Sector Data Base; The BOMA Commercial Sector Data Base; The Tishman-Syska and Hennessy Data Base; The NEMA Commercial Sector Data Base; ORNL Buildings Energy Use Data Book; and Solar Market Development Model. Purpose; basis for model structure; policy variables and parameters; level of regional, sectoral, and fuels detail; outputs; input requirements; sources of data; computer accessibility and requirements; and a bibliography are provided for each model and data source.

  1. End-Use Sector Flowcharts, Energy Intensity Indicators

    Broader source: Energy.gov (indexed) [DOE]

    Economy Transportation Sector Commercial Sector Residential Sector Electric Power Sector Industrial Sector Manufacturing NAICS 311-339 Food, Beverages, & Tobacco NAICS 311/312 Textile Mills and Products NAICS 313/314 Apparel & Leather Products NAICS 315/316 Wood Products NAICS 321 Paper NAICS 322 Printing & Related Support NAICS 323 Petroleum & Coal Products NAICS 324 Chemicals NAICS 325 Plastics & Rubber Products NAICS 326 Nonmetallic Mineral Products NAICS 327 Primary

  2. Private Sector Outreach and Partnerships | Department of Energy

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

    Private Sector Outreach and Partnerships Private Sector Outreach and Partnerships ISER's partnerships with the private sector are a strength which has enabled the division to respond to the needs of the sector and the nation. The division's domestic capabilities have been greatly enhanced by the relationships that have been created over years of collaborations with companies from all parts the sector, including electricity, oil, and natural gas. Specific mission areas, such as risk and system

  3. EIA Energy Efficiency-Commercial Buildings Sector Energy Intensities...

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

    Building Activity (Table 1b) html table 1b excel table 1b pdf table 1b. Total Primary Energy Consumption (U.S. and Census Region) By Principal Building Activity (Table 1c) html...

  4. Energy Sector Control Systems Working Group to Meet March 25, 2008 |

    Energy Savers [EERE]

    Department of Energy Control Systems Working Group to Meet March 25, 2008 Energy Sector Control Systems Working Group to Meet March 25, 2008 The Energy Sector Control Systems Working Group is a unique public-private partnership recently formed to help guide implementation of the priorities identified in the industry-led Roadmap to Secure Control Systems in the Energy Sector. The group seeks to provide a platform for pursuing innovative and practical activities that will improve the security

  5. List of Companies in Biofuels Sector | Open Energy Information

    Open Energy Info (EERE)

    List of Companies in Biofuels Sector Jump to: navigation, search BiomassImage.JPG Companies in the Biofuels sector: Add a Company Download CSV (rows 1-256) Map of Biofuels...

  6. Sectoral trends in global energy use and greenhouse gasemissions

    SciTech Connect (OSTI)

    Price, Lynn; de la Rue du Can, Stephane; Sinton, Jonathan; Worrell, Ernst; Zhou, Nan; Sathaye, Jayant; Levine, Mark

    2006-07-24

    In 2000, the Intergovernmental Panel on Climate Change (IPCC) published a new set of baseline greenhouse gas (GHG) emissions scenarios in the Special Report on Emissions Scenarios (SRES) (Nakicenovic et al., 2000). The SRES team defined four narrative storylines (A1, A2, B1 and B2) describing the relationships between the forces driving GHG and aerosol emissions and their evolution during the 21st century. The SRES reports emissions for each of these storylines by type of GHG and by fuel type to 2100 globally and for four world regions (OECD countries as of 1990, countries undergoing economic reform, developing countries in Asia, rest of world). Specific assumptions about the quantification of scenario drivers, such as population and economic growth, technological change, resource availability, land-use changes, and local and regional environmental policies, are also provided. End-use sector-level results for buildings, industry, or transportation or information regarding adoption of particular technologies and policies are not provided in the SRES. The goal of this report is to provide more detailed information on the SRES scenarios at the end use level including historical time series data and a decomposition of energy consumption to understand the forecast implications in terms of end use efficiency to 2030. This report focuses on the A1 (A1B) and B2 marker scenarios since they represent distinctly contrasting futures. The A1 storyline describes a future of very rapid economic growth, low population growth, and the rapid introduction of new and more efficient technologies. Major underlying themes are convergence among regions, capacity building, and increased cultural and social interactions, with a substantial reduction in regional differences in per capita income. The B2 storyline describes a world with an emphasis on economic, social, and environmental sustainability, especially at the local and regional levels. It is a world with moderate population growth, intermediate levels of economic development, and less rapid and more diverse technological change (Nakicenovic et al., 2000). Data were obtained from the SRES modeling teams that provide more detail than that reported in the SRES. For the A1 marker scenario, the modeling team provided final energy demand and carbon dioxide (CO{sub 2}) emissions by fuel for industry, buildings, and transportation for nine world regions. Final energy use and CO{sub 2} emissions for three sectors (industry, transport, buildings) for the four SRES world regions were provided for the B2 marker scenario. This report describes the results of a disaggregation of the SRES projected energy use and energy-related CO{sub 2} emissions for the industrial, transport, and buildings sectors for 10 world regions (see Appendix 1) to 2030. An example of further disaggregation of the two SRES scenarios for the residential buildings sector in China is provided, illustrating how such aggregate scenarios can be interpreted at the end use level.

  7. Energy Assessment Training Reduces Energy Costs for the U.S. Coast Guard Sector Guam: Success Stories (Fact Sheet)

    SciTech Connect (OSTI)

    Not Available

    2013-05-01

    U.S. Coast Guard Sector Guam experiences considerable energy cost and use savings after implementing training from NREL's energy assessment training.

  8. U.S. Building-Sector Energy Efficiency Potential

    SciTech Connect (OSTI)

    Brown, Rich; Borgeson, Sam; Koomey, Jon; Biermayer, Peter

    2008-09-30

    This paper presents an estimate of the potential for energy efficiency improvements in the U.S. building sector by 2030. The analysis uses the Energy Information Administration's AEO 2007 Reference Case as a business-as-usual (BAU) scenario, and applies percentage savings estimates by end use drawn from several prior efficiency potential studies. These prior studies include the U.S. Department of Energy's Scenarios for a Clean Energy Future (CEF) study and a recent study of natural gas savings potential in New York state. For a few end uses for which savings estimates are not readily available, the LBNL study team compiled technical data to estimate savings percentages and costs of conserved energy. The analysis shows that for electricity use in buildings, approximately one-third of the BAU consumption can be saved at a cost of conserved energy of 2.7 cents/kWh (all values in 2007 dollars), while for natural gas approximately the same percentage savings is possible at a cost of between 2.5 and 6.9 $/million Btu. This cost-effective level of savings results in national annual energy bill savings in 2030 of nearly $170 billion. To achieve these savings, the cumulative capital investment needed between 2010 and 2030 is about $440 billion, which translates to a 2-1/2 year simple payback period, or savings over the life of the measures that are nearly 3.5 times larger than the investment required (i.e., a benefit-cost ratio of 3.5).

  9. Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation

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

    to the 2008 ieRoadmap Workshop | Department of Energy Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation to the 2008 ieRoadmap Workshop Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation to the 2008 ieRoadmap Workshop Presentation by Hank Kenchington on the 2006 roadmap to secure control systems in the energy sector at the ieRoadmap Workshop in Chicago, May 28-29, 2008. PDF icon Roadmap to Secure Control Systems in the Energy Sector More

  10. Forest Products Sector (NAICS 321 and 322) Energy and GHG Combustion Emissions Profile, November 2012

    Office of Environmental Management (EM)

    U.S. Manufacturing Energy Use and Greenhouse Gas Emissions Analysis 2.3 FOREST PRODUCTS SECTOR (NAICS 321 AND 322) 2.3.1. Overview of the Forest Products Manufacturing Sector The forest products sector produces thousands of products from renewable raw materials (wood) that are essential for communication, packaging, consumer goods, and construction. The sector is divided into two major categories: Wood Product Manufacturing (NAICS 321) and Paper Manufacturing (NAICS 322). These industries are

  11. EA-0513: Approaches for Acquiring Energy Savings in Commercial Sector Buildings, Bonneville Power Administration

    Broader source: Energy.gov [DOE]

    This EA evaluates the environmental impacts of a proposal for DOE's Bonneville Power Administration to use several diverse approaches to purchase or acquire energy savings from commercial sector...

  12. NAMA-Programme for the construction sector in Asia | Open Energy...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Market analysis Website http:www.unep.orgsbcipdfs...

  13. Climate Change and the U.S. Energy Sector: Regional Vulnerabilities and Resilience Solutions

    Broader source: Energy.gov [DOE]

    This report examines current and potential future impacts of these climate trends on the U.S. energy sector by region, and explores possible resilience solutions.

  14. Detection and Analysis of Threats to the Energy Sector: DATES

    SciTech Connect (OSTI)

    Alfonso Valdes

    2010-03-31

    This report summarizes Detection and Analysis of Threats to the Energy Sector (DATES), a project sponsored by the United States Department of Energy and performed by a team led by SRI International, with collaboration from Sandia National Laboratories, ArcSight, Inc., and Invensys Process Systems. DATES sought to advance the state of the practice in intrusion detection and situational awareness with respect to cyber attacks in energy systems. This was achieved through adaptation of detection algorithms for process systems as well as development of novel anomaly detection techniques suited for such systems into a detection suite. These detection components, together with third-party commercial security systems, were interfaced with the commercial Security Information Event Management (SIEM) solution from ArcSight. The efficacy of the integrated solution was demonstrated on two testbeds, one based on a Distributed Control System (DCS) from Invensys, and the other based on the Virtual Control System Environment (VCSE) from Sandia. These achievements advance the DOE Cybersecurity Roadmap [DOE2006] goals in the area of security monitoring. The project ran from October 2007 until March 2010, with the final six months focused on experimentation. In the validation phase, team members from SRI and Sandia coupled the two test environments and carried out a number of distributed and cross-site attacks against various points in one or both testbeds. Alert messages from the distributed, heterogeneous detection components were correlated using the ArcSight SIEM platform, providing within-site and cross-site views of the attacks. In particular, the team demonstrated detection and visualization of network zone traversal and denial-of-service attacks. These capabilities were presented to the DistribuTech Conference and Exhibition in March 2010. The project was hampered by interruption of funding due to continuing resolution issues and agreement on cost share for four months in 2008. This resulted in delays in finalizing agreements with commercial partners, and in particular the Invensys testbed was not installed until December 2008 (as opposed to the March 2008 plan). The project resulted in a number of conference presentations and publications, and was well received when presented at industry forums. In spite of some interest on the part of the utility sector, we were unfortunately not able to engage a utility for a full-scale pilot deployment.

  15. Mobilizing $4 Billion in Private-Sector Support for Clean Energy Innovation

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

    | Department of Energy Mobilizing $4 Billion in Private-Sector Support for Clean Energy Innovation Mobilizing $4 Billion in Private-Sector Support for Clean Energy Innovation June 16, 2015 - 9:00am Addthis Innovations in clean energy like wind power are a crucial part of fighting climate change. | Photo courtesy of the Department of Energy Loan Programs Office. Innovations in clean energy like wind power are a crucial part of fighting climate change. | Photo courtesy of the Department of

  16. Public Finance Mechanisms to Catalyze Sustainable Energy Sector...

    Open Energy Info (EERE)

    all aspects of the sector including technology innovation, project development, (SME) business and industry support, consumer awareness and end-user finance. Regardless of...

  17. Changes in Energy Intensity in the Manufacturing Sector 1985...

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

    (34) Machinery (35) El. Equip.(36) Instruments (38) Misc. (39) Appendices Survey Design Quality of Data Sector Description Nonobservation Errors Glossary Intensity Sites...

  18. Fact Sheet: Detection and Analysis of Threats to the Energy Sector (DATES)

    Office of Environmental Management (EM)

    and Analysis of Threats to the Energy Sector (DATES) A groundbreaking integrated capability in intrusion detection, security event management, and sector-wide threat analysis Detecting cyber attacks against digital control systems quickly and accurately is essential to energy sector security. Current intrusion detection systems (IDS) continuously scan control system communication paths and alert operators of suspicious network traffc. But existing IDS, often not tailored to the control

  19. U.S. Energy Sector Vulnerabilities to Climate Change and Extreme Weather |

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

    Department of Energy U.S. Energy Sector Vulnerabilities to Climate Change and Extreme Weather U.S. Energy Sector Vulnerabilities to Climate Change and Extreme Weather This report-part of the Administration's efforts to support national climate change adaptation planning through the Interagency Climate Change Adaptation Task Force and Strategic Sustainability Planning process established under Executive Order 13514 and to advance the U.S. Department of Energy's goal of promoting energy

  20. DOE Launches the "Partnership for Energy Sector Climate Resilience"

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    with 17 Electric Utilities | Department of Energy DOE Launches the "Partnership for Energy Sector Climate Resilience" with 17 Electric Utilities DOE Launches the "Partnership for Energy Sector Climate Resilience" with 17 Electric Utilities June 2, 2015 - 12:00pm Addthis Melanie A. Kenderdine Melanie A. Kenderdine Director of the Office of Energy Policy and Systems Analysis On April 30, Energy Secretary Moniz and Deputy Secretary Elizabeth Sherwood-Randall welcomed senior

  1. Issues in International Energy Consumption Analysis: Electricity Usage in Indias Housing Sector

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Issues in International Energy Consumption Analysis: Electricity Usage in India's Housing Sector November 2014 Independent Statistics & Analysis www.eia.gov U.S. Department of Energy Washington, DC 20585 U.S. Energy Information Administration | Issues in International Energy Consumption Analysis: Electricity Usage in India's Housing Sector i This report was prepared by the U.S. Energy Information Administration (EIA), the statistical and analytical agency within the U.S. Department of

  2. DOE Seeks Public-Private Sector Expressions of Interest for Global Nuclear Energy Partnership Initiative

    Broader source: Energy.gov [DOE]

    WASHINGTON, DC - U.S. Secretary of Energy Samuel Bodman today announced that the Department of Energy (DOE) is seeking expressions of interest from the public and private sectors by March 31, 2006,...

  3. Draft Energy Sector Cybersecurity Framework Implementation Guidance Available for Public Comment

    Broader source: Energy.gov [DOE]

    The Department of Energy (DOE) has issued a Notice of Public Comment in the Federal Register, inviting the public to comment on DOE's Energy Sector Cybersecurity Framework Implementation Guidance. The document is available for a 30 day comment period.

  4. Commercial Buildings Sector Agent-Based Model | Open Energy Informatio...

    Open Energy Info (EERE)

    OpenEI Keyword(s): EERE tool, Commercial Buildings Sector Agent-Based Model Language: English References: Building Efficiency: Development of an Agent-based Model of the US...

  5. Novolyte Charging Up Electric Vehicle Sector | Department of Energy

    Energy Savers [EERE]

    Novolyte Charging Up Electric Vehicle Sector Novolyte Charging Up Electric Vehicle Sector August 11, 2010 - 10:15am Addthis Electric vehicles are powered by electricity that comes in the form of electrically charged molecules known as ions. Those ions need a substance to transport them throughout the system as they travel from the anode to the cathode and back again. That substance is an electrolyte. | Staff Photo Illustration Electric vehicles are powered by electricity that comes in the form

  6. Turkey energy and environmental review - Task 7 energy sector modeling : executive summary.

    SciTech Connect (OSTI)

    Conzelmann, G.; Koritarov, V.; Decision and Information Sciences

    2008-02-28

    Turkey's demand for energy and electricity is increasing rapidly. Since 1990, energy consumption has increased at an annual average rate of 4.3%. As would be expected, the rapid expansion of energy production and consumption has brought with it a wide range of environmental issues at the local, regional and global levels. With respect to global environmental issues, Turkey's carbon dioxide (CO2) emissions have grown along with its energy consumption. Emissions in 2000 reached 211 million metric tons. With GDP projected to grow at over 6% per year over the next 25 years, both the energy sector and the pollution associated with it are expected to increase substantially. This is expected to occur even if assuming stricter controls on lignite and hard coal-fired power generation. All energy consuming sectors, that is, power, industrial, residential, and transportation, will contribute to this increased emissions burden. Turkish Government authorities charged with managing the fundamental problem of carrying on economic development while protecting the environment include the Ministry of Environment (MOE), the Ministry of Energy and Natural Resources (MENR), and the Ministry of Health, as well as the Turkish Electricity Generation & Transmission Company (TEAS). The World Bank, working with these agencies, is planning to assess the costs and benefits of various energy policy alternatives under an Energy and Environment Review (EER). Eight individual studies have been conducted under this activity to analyze certain key energy technology issues and use this analysis to fill in the gaps in data and technical information. This will allow the World Bank and Turkish authorities to better understand the trade-offs in costs and impacts associated with specific policy decisions. The purpose of Task 7-Energy Sector Modeling, is to integrate information obtained in other EER tasks and provide Turkey's policy makers with an integrated systems analysis of the various options for addressing the various energy and environmental concerns. The work presented in this report builds on earlier analyses presented at the COP 6 conference in Bonn.

  7. Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation

    Energy Savers [EERE]

    to the 2008 ieRoadmap Workshop | Department of Energy 2006 - Presentation to the 2008 ieRoadmap Workshop Roadmap to Secure Control Systems in the Energy Sector 2006 - Presentation to the 2008 ieRoadmap Workshop Presentation by Hank Kenchington on the 2006 roadmap to secure control systems in the energy sector at the ieRoadmap Workshop in Chicago, May 28-29, 2008. PDF icon Roadmap to Secure Control Systems in the Energy Sector More Documents & Publications Security is Not an Option

  8. Energy Sector Stakeholders Attend the Department of Energy¬タルs 2010 Cybersecurity for Energy Delivery Systems Peer Review

    Office of Environmental Management (EM)

    Sector Stakeholders Attend the Department of Energy's Cybersecurity for Energy Delivery Systems Peer Review July 29, 2010 The Department of Energy conducted a Peer Review of its Cybersecurity for Energy Delivery Systems (CEDS) Research and Development Program on July 20-22, during which 28 R&D projects were presented for review by industry stakeholders. More than 65 energy sector stakeholders came to network, present, and learn about DOE projects, while more than 20 joined in by webinar. The

  9. List of Companies in Services Sector | Open Energy Information

    Open Energy Info (EERE)

    n":"","group":"","inlineLabel":"","visitedicon":"","text":"EnergyCo." title"Able Energy Co.">Able Energy Co.","title":"Able Energy...

  10. Site Attracts Private Sector Investments for Reuse | Department of Energy

    Energy Savers [EERE]

    Attracts Private Sector Investments for Reuse Site Attracts Private Sector Investments for Reuse June 26, 2013 - 12:00pm Addthis This 13,000-square-foot building constructed by Babcock Services, Inc. is a sign of continued success for the East Tennessee Technology Park Heritage Center. This 13,000-square-foot building constructed by Babcock Services, Inc. is a sign of continued success for the East Tennessee Technology Park Heritage Center. A new solar installation was recently dedicated at the

  11. Energy: Critical Infrastructure and Key Resources Sector-Specific Plan as

    Energy Savers [EERE]

    input to the National Infrastructure Protection Plan (Redacted) | Department of Energy Energy: Critical Infrastructure and Key Resources Sector-Specific Plan as input to the National Infrastructure Protection Plan (Redacted) Energy: Critical Infrastructure and Key Resources Sector-Specific Plan as input to the National Infrastructure Protection Plan (Redacted) In June 2006, the U.S. Department of Homeland Security (DHS) announced completion of the National Infrastructure Protection Plan

  12. Energy Sector Vulnerability to Climate Change: Adaptation Options to Increase Resilience (Presentation)

    SciTech Connect (OSTI)

    Newmark, R. L.; Bilello, D.; Macknick, J.; Hallet, K. C.; Anderson, R.; Tidwell, V.; Zamuda, C.

    2013-02-01

    The U.S. Department of Energy is conducting an assessment of vulnerabilities of the U.S. energy sector to climate change and extreme weather. Emphasizing peer reviewed research, it seeks to quantify vulnerabilities and identify specific knowledge or technology gaps. It draws upon a July 2012 workshop, ?Climate Change and Extreme Weather Vulnerability Assessment of the US Energy Sector?, hosted by the Atlantic Council and sponsored by DOE to solicit industry input.

  13. Federal Sector Renewable Energy Project Implementation: "What's Working and Why"

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

    Federal Sector Renewable Energy Project Implementation: "What's Working and Why" Implementation: What s Working and Why DOD-DOE Waste-to- Energy and Fuel Cell Workshop January 13, 2011 Bob Westby Bob Westby NREL Laboratory Program Manager: Federal Energy Management Program NREL is a national laboratory of the U.S. Department of Energy Office of Energy Efficiency and Renewable Energy operated by the Alliance for Sustainable Energy, LLC Innovation for Our Energy Future Contents Federal

  14. Market leadership by example: Government sector energy efficiency in developing countries

    SciTech Connect (OSTI)

    Van Wie McGrory, Laura; Harris, Jeffrey; Breceda, Miguel; Campbell, Stephanie; Sachu, Constantine; della Cava, Mirka; Gonzalez Martinez, Jose; Meyer, Sarah; Romo, Ana Margarita

    2002-05-20

    Government facilities and services are often the largest energy users and major purchasers of energy-using equipment within a country. In developing as well as industrial countries, government ''leadership by example'' can be a powerful force to shift the market toward energy efficiency, complementing other elements of a national energy efficiency strategy. Benefits from more efficient energy management in government facilities and operations include lower government energy bills, reduced greenhouse gas emissions, less demand on electric utility systems, and in many cases reduced dependence on imported oil. Even more significantly, the government sector's buying power and example to others can generate broader demand for energy-efficient products and services, creating entry markets for domestic suppliers and stimulating competition in providing high-efficiency products and services. Despite these benefits, with the exception of a few countries government sector actions have often lagged behind other energy efficiency policies. This is especially true in developing countries and transition economies - even though energy used by public agencies in these countries may represent at least as large a share of total energy use as the public sector in industrial economies. This paper summarizes work in progress to inventory current programs and policies for government sector energy efficiency in developing countries, and describes successful case studies from Mexico's implementation of energy management in the public sector. We show how these policies in Mexico, begun at the federal level, have more recently been extended to state and local agencies, and consider the applicability of this model to other developing countries.

  15. List of Companies in Efficiency Sector | Open Energy Information

    Open Energy Info (EERE)

    ":"","group":"","inlineLabel":"","visitedicon":"","text":"EnergyGroupInc" title"Acela Energy Group Inc">Acela Energy Group Inc<...

  16. Behavioral Assumptions Underlying California Residential Sector Energy Efficiency Programs (2009 CIEE Report)

    Broader source: Energy.gov [DOE]

    This paper examines the behavioral assumptions that underlie California’s residential sector energy efficiency programs and recommends improvements that will help to advance the state’s ambitious greenhouse gas reduction goals.

  17. Climate Change and the U.S. Energy Sector: Regional Vulnerabilities...

    Broader source: Energy.gov (indexed) [DOE]

    it in a modern browser. This report examines the current and potential future impacts of climate change and extreme weather on the U.S. energy sector at the regional level. It...

  18. Working with the Private Sector to Achieve a Clean Energy Economy |

    Broader source: Energy.gov (indexed) [DOE]

    Department of Energy Doug Schultz Program Director, Loan Programs Office of the Department of Energy. What does this project do? Brings more certainty to the market by incentivizing the capital markets. Increases non-government lending capacity to the renewable sector. Provides a bridge between innovative but high tech risk projects and commercial technology projects whose risk profiles banks readily assume. It's an example of how the Administration is working with the private sector to

  19. List of Companies in Biomass Sector | Open Energy Information

    Open Energy Info (EERE)

    lygons":,"circles":,"rectangles":,"locations":"text":"Energy Ltd">A A Energy Ltd","title":"A A Energy...

  20. Federal Sector Renewable Energy Project Implementation: ""What's Working and Why

    Broader source: Energy.gov [DOE]

    Presentation by Robert Westby, National Renewable Energy Laboratory, at the Waste-to-Energy Using Fuel Cells Workshop held Jan. 13, 2011.

  1. Residential Sector Demand Module of the National Energy Modeling...

    Gasoline and Diesel Fuel Update (EIA)

    Stoves Geothermal Heat Pump Natural Gas Heat Pump Variables: HSYSSHR 2001,eg,b,r Benchmarking Data from Short-Term Energy Outlook Definition: Household energy consumption by...

  2. Energy Department Announces New Private Sector Partnership to...

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

    and the Department's Loan Guarantee Program. Energy and Climate Stakeholders Briefing (PDF) Media contact(s): (202) 586-4940 Addthis Related Articles Energy Department Announces...

  3. Energy Sector Framework Implementation Guidance Notice of Stakeholder Participation: Federal Register Notice Volume 79, No.- 119 June 20, 2014

    Broader source: Energy.gov [DOE]

    The Department of Energy (DOE) invites public participation in DOE’s efforts to develop a guidance document entitled: Energy Sector Framework Implementation Guidance.

  4. Energy Sector Cybersecurity Framework Implementation Guidance- Notice of Public Comment: Federal Register Notice, Volume 79, No. 177, September 12, 2014

    Broader source: Energy.gov [DOE]

    The Department of Energy invites public comment on a draft of the Energy Sector Cybersecurity Framework Implementation Guidance. Comments must be received on or before October 14, 2014.

  5. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    7 Range 10 4 48 Clothes Dryer 359 (2) 4 49 Water Heating Water Heater-Family of 4 40 64 (3) 26 294 Water Heater-Family of 2 40 32 (3) 12 140 Note(s): Source(s): 1) $1.139/therm. 2) Cycles/year. 3) Gallons/day. A.D. Little, EIA-Technology Forecast Updates - Residential and Commercial Building Technologies - Reference Case, Sept. 2, 1998, p. 30 for range and clothes dryer; LBNL, Energy Data Sourcebook for the U.S. Residential Sector, LBNL-40297, Sept. 1997, p. 62-67 for water heating; GAMA,

  6. Climate Change and the U.S. Energy Sector: Regional Vulnerabilities and Resilience Solutions

    Broader source: Energy.gov (indexed) [DOE]

    Climate Change and the U.S. Energy Sector: Regional Vulnerabilities and Resilience Solutions October 2015 U.S. Department of Energy Office of Energy Policy and Systems Analysis Acknowledgements This report was produced by the U.S. Department of Energy's Office of Energy Policy and Systems Analysis (DOE-EPSA) under the direction of Craig Zamuda. Matt Antes, C.W. Gillespie, Anna Mosby, and Beth Zotter of Energetics Incorporated provided analysis, drafting support, and technical editing.

  7. AEO2011: Energy Consumption by Sector and Source - Mountain ...

    Open Energy Info (EERE)

    comes from the Energy Information Administration (EIA), and is part of the 2011 Annual Energy Outlook Report (AEO2011). This dataset is table 8, and contains only the reference...

  8. Property:Incentive/ImplSector | Open Energy Information

    Open Energy Info (EERE)

    Efficiency Programs (Texas) + Utility + AEP Appalachian Power - Commercial and Industrial Rebate Programs (West Virginia) + Utility + AEP Appalachian Power - Residential Energy...

  9. Utility Sector Leaders Make Firm Commitment to Energy Efficiency

    Broader source: Energy.gov [DOE]

    More than 80 energy, environmental and other organizations announced commitments and public statements in support of the National Action Plan for Energy Efficiency (NAPEE), released today, which provides energy consumers and providers information on policies and techniques to save money as well as protect the environment. By adopting the plan's recommendations on low-cost, under-used energy efficiency, Americans could save hundreds of billions of dollars on their gas and electric utility bills, cut greenhouse gas emissions, and lower the costs for energy and pollution controls.

  10. Study of energy R and D in the private sector

    SciTech Connect (OSTI)

    Not Available

    1980-01-01

    This study supplies DOE with information pertinent to the formulation of realistic national energy research policies and facilitates cooperation between government and business in the development and commercialization of new and improved energy technologies. The study gathered information on the amount of energy-related research and development that private companies are doing, types of energy-related programs they report, and their perceptions about appropriate areas for government support. Mail questionnaires obtained data on the amount of corporate research funding in specific energy-related technology areas and the interviews gathered information on corporate energy strategies, major commercial activities, and specific research plans in four major areas - conservation, supply, energy production and transmission, and new products. (MCW)

  11. Petroleum Refining Sector (NAICS 324110) Energy and GHG Combustion Emissions Profile, November 2012

    Energy Savers [EERE]

    69 2.4 PETROLEUM REFINING SECTOR (NAICS 324110) 2.4.1. Overview of the Petroleum Refining Manufacturing Sector Petroleum refining is a complex industry that generates a diverse slate of fuel products and petrochemicals, from gasoline to asphalt. Refining requires a range of processing steps, including distillation, cracking, reforming, and treating. Most of these processes are highly reliant on process heating and steam energy. Petroleum refineries are an essential part of the U.S. economy.

  12. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    3 2005 Average Household Expenditures, by Census Region ($2010) Item Energy (1) Shelter (2) Food Telephone, water and other public services Household supplies, furnishings and equipment (3) Transportation (4) Healthcare Education Personal taxes (5) Other expenditures Average Annual Income Note(s): Source(s): 1) Average household energy expenditures are calculated from the Residential Energy Consumption Survey (RECS), while average expenditures for other categories are calculated from the

  13. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    4 2005 Average Household Expenditures as Percent of Annual Income, by Census Region ($2010) Item Energy (1) Shelter (2) Food Telephone, water and other public services Household supplies, furnishings and equipment (3) Transportation (4) Healthcare Education Personal taxes (5) Average Annual Expenditures Average Annual Income Note(s): Source(s): 1) Average household energy expenditures are calculated from the Residential Energy Consumption Survey (RECS), while average expenditures for other

  14. Dams and Energy Sectors Interdependency Study, September 2011...

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

    patterns and competing demands for water which determine the water available for hydropower production. Dams-Energy Interdependency Study.pdf More Documents & Publications 2014...

  15. New Report Highlights Growth of America's Clean Energy Job Sector...

    Broader source: Energy.gov (indexed) [DOE]

    Gerrity. INFOGRAPHIC | Made in America: Clean Energy Jobs Nebraska Biofuel Enzyme Plant Hosts Tour with Senior DOE Official Saft America Advanced Batteries Plant...

  16. Vietnam-Danish Government Sector Programmes | Open Energy Information

    Open Energy Info (EERE)

    Low emission development planning, -LEDS, Policiesdeployment programs Program End 2012 Country Vietnam South-Eastern Asia References Denmark1 Promoting wind energy in...

  17. List of Companies in Carbon Sector | Open Energy Information

    Open Energy Info (EERE)

    Cove Capital Advisors Novomer ORYXE Energy International Inc Osmosis Capital Pacific Fuel Cell Corp PFCE Paragon Airheater Technologies Plane Tree Capital LLP PlaneCarbon...

  18. Buildings Energy Data Book: 1.2 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    Residential Sector Energy Consumption March 2012 1.2.9 Implicit Price Deflators (2005 = 1.00) Year Year Year 1980 0.48 1990 0.72 2000 0.89 1981 0.52 1991 0.75 2001 0.91 1982 0.55 1992 0.77 2002 0.92 1983 0.58 1993 0.78 2003 0.94 1984 0.60 1994 0.80 2004 0.97 1985 0.62 1995 0.82 2005 1.00 1986 0.63 1996 0.83 2006 1.03 1987 0.65 1997 0.85 2007 1.06 1988 0.67 1998 0.86 2008 1.09 1989 0.70 1999 0.87 2009 1.10 2010 1.11 Source(s): EIA, Annual Energy Review 2010, August 2011, Appendix D, p. 353.

  19. Opportunities for Synergy Between Natural Gas and Renewable Energy in the Electric Power and Transportation Sectors

    SciTech Connect (OSTI)

    Lee, A.; Zinaman, O.; Logan, J.

    2012-12-01

    Use of both natural gas and renewable energy has grown significantly in recent years. Both forms of energy have been touted as key elements of a transition to a cleaner and more secure energy future, but much of the current discourse considers each in isolation or concentrates on the competitive impacts of one on the other. This paper attempts, instead, to explore potential synergies of natural gas and renewable energy in the U.S. electric power and transportation sectors.

  20. Profiles in Renewable Energy: Case Studies of Successful Utility-Sector

    Office of Scientific and Technical Information (OSTI)

    Projects Profiles in Renewable Energy: Case Studies of Successful Utility-Sector Projects The Shape of Renewable Energy Technologies Today Biomass Wood-Burning Plant Reduces Air Pollution Kettle Falls Wood-Fired Plant Washington Power Company Regulatory Changes Spur Wood-Fired Plant Grayling Generating Station Decker Energy International, Inc. Community Partnership Leads to Waste-Burning Plant Bristol Waste-to-Energy Plant Ogden Martin Systems Geothermal Geothermal Loan Encourages New Power

  1. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    4 Cost of a Generic Quad Used in the Residential Sector ($2010 Billion) (1) Residential 1980 10.45 1981 11.20 1982 11.58 1983 11.85 1984 11.65 1985 11.43 1986 10.90 1987 10.55 1988 10.18 1989 9.98 1990 10.12 1991 9.94 1992 9.78 1993 9.77 1994 9.78 1995 9.44 1996 9.44 1997 9.59 1998 9.23 1999 8.97 2000 9.57 2001 10.24 2002 9.33 2003 10.00 2004 10.32 2005 11.10 2006 11.60 2007 11.61 2008 12.29 2009 11.65 2010 9.98 2011 9.99 2012 9.87 2013 9.77 2014 9.76 2015 9.88 2016 9.85 2017 9.83 2018 9.86 2019

  2. South Africa-Developing Climate Policy Capacity within the South...

    Open Energy Info (EERE)

    Affairs (DEA), Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Background analysis,...

  3. Costa Rica-Supporting the Zero Emissions Strategy of Costa Rica...

    Open Energy Info (EERE)

    (GIZ) Partner Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU) Sector Energy Focus Area Energy Efficiency Topics Low emission...

  4. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    4 FY 2007 Federal Buildings Energy Prices and Expenditures, by Fuel Type ($2010) Fuel Type Electricity (1) Natural Gas Fuel Oil Coal Purchased Steam LPG/Propane Other Average Total Note(s): Source(s): 17.05 6028.63 Prices and expenditures are for Goal-Subject buildings. 1) $0.0776/kWh. 2) Energy used in Goal-Subject buildings in FY 2007 accounted for 33.8% of the total Federal energy bill. DOE/FEMP, Annual Report to Congress on FEMP FY 2007, Jan. 2010, Table A-4, p. 93 for prices and

  5. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    1 2005 Energy Expenditures per Household, by Housing Type and Square Footage ($2010) Per Household Single-Family 1.16 Detached 1.16 Attached 1.20 Multi-Family 1.66 2 to 4 units 1.90 5 or more units 1.53 Mobile Home 1.76 All Homes 1.12 Note(s): Source(s): 1) Energy expenditures per square foot were calculated using estimates of average heated floor space per household. According to the 2005 Residential Energy Consumption Survey (RECS), the average heated floor space per household in the U.S. was

  6. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    2 2005 Household Energy Expenditures, by Vintage ($2010) | Year | Prior to 1950 887 | 22% 1950 to 1969 771 | 22% 1970 to 1979 736 | 16% 1980 to 1989 741 | 16% 1990 to 1999 752 | 16% 2000 to 2005 777 | 9% | Average 780 | Total 100% Note(s): Source(s): 1.24 2,003 1) Energy expenditures per square foot were calculated using estimates of average heated floor space per household. According to the 2005 Residential Energy Consumption Survey (RECS), the average heated floor space per household in the

  7. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    0 2003 Energy Expenditures per Square Foot of Commercial Floorspace, by Vintage ($2010) Vintage $/SF Prior to 1960 1.44 1960 to 1969 1.70 1970 to 1979 1.88 1980 to 1989 2.09 1990 to 1999 1.88 2000 to 2003 1.72 Average 1.77 Source(s): EIA, 2003 Commercial Buildings Energy Consumption and Expenditures: Consumption and Expenditures Tables, Table C4; and EIA, Annual Energy Review 2010, Aug. 2011, Appendix D, p. 353 for price deflators

  8. List of Companies in Vehicles Sector | Open Energy Information

    Open Energy Info (EERE)

    Forge KPIT Cummins JV Bluebird Automotive Boston Power Brammo, Inc. CalCars California Fuel Cell Partnership CaFCP Century Asset Management China Titans Energy Technology Group Co...

  9. Industry Trends in the U.S. Wind Energy Sector

    Broader source: Energy.gov [DOE]

    Electricity supplied by wind energy exceeded 4.5 percent in the U.S. in 2013 and has the potential to reach as much as 35 percent by 2050. Join The Pew Charitable Trusts for a webinar with the...

  10. Energy Sector Management Assistance Program of the World Bank...

    Open Energy Info (EERE)

    that will help developing and middle-income countries integrate large shares of wind and solar energy into their electricity grids.

  11. Evolving Role of the Power Sector Regulator: A Clean Energy Regulators Initiative Report

    SciTech Connect (OSTI)

    Zinaman, O.; Miller, M.; Bazilian, M.

    2014-04-01

    This paper seeks to briefly characterize the evolving role of power sector regulation. Given current global dynamics, regulation of the power sector is undergoing dramatic changes. This transformation is being driven by various factors including technological advances and cost reductions in renewable energy, energy efficiency, and demand management; increasing air pollution and climate change concerns; and persistent pressure for ensuring sustainable economic development and increased access to energy services by the poor. These issues add to the already complex task of power sector regulation, of which the fundamental remit remains to objectively and transparently ensure least-cost service delivery at high quality. While no single regulatory task is trivial to undertake, it is the prioritization and harmonization of a multitude of objectives that exemplifies the essential challenge of power sector regulation. Evolving regulatory roles can be understood through the concept of existing objectives and an additional layer of emerging objectives. Following this categorization, we describe seven existing objectives of power sector regulators and nine emerging objectives, highlighting key challenges and outlining interdependencies. This essay serves as a preliminary installment in the Clean Energy Regulatory Initiative (CERI) series, and aims to lay the groundwork for subsequent reports and case studies that will explore these topics in more depth.

  12. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    5 2005 Households and Energy Expenditures, by Income Level ($2010) Energy Expenditures by Household Income Households (millions) Household Less than $10,000 9.9 9% $10,000 to $14,999 8.5 8% $15,000 to $19,999 8.4 8% $20,000 to $29,999 15.1 14% $30,000 to $39,999 13.6 12% $40,000 to $49,999 11.0 10% $50,000 to $74,999 19.8 18% $75,000 to $99,999 10.6 10% $100,000 or more 14.2 13% Total 111.1 100% Note(s): Source(s): 7% 1) See Table 2.3.15 for more on energy burdens. 2) A household is defined as a

  13. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    0 2005 Energy End-Use Expenditures for an Average Household, by Region ($2010) Northeast Midwest South West National Space Heating 1,050 721 371 352 575 Air-Conditioning 199 175 456 262 311 Water Heating 373 294 313 318 320 Refrigerators 194 145 146 154 157 Other Appliances and Lighting 827 665 715 716 725 Total (1) 2,554 1,975 1,970 1,655 2,003 Note(s): 1) Due to rounding, end-uses do not sum to totals. Source(s): EIA, 2005 Residential Energy Consumption Survey, Oct. 2008, Table US-15; EIA,

  14. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    1 Energy Service Company (ESCO) Industry Activity ($Million Nominal) (1) Low High 1990 143 342 Market Segment Share 1991 218 425 MUSH (2) 69% 1992 331 544 Federal 15% 1993 505 703 Commercial & Industrial 7% 1994 722 890 Residential 6% 1995 1,105 1,159 Public Housing 3% 1996 1,294 1,396 1997 1,394 1,506 1998 1,551 1,667 2008 Revenues by Project/Technology Type 1999 1,764 1,925 2000 1,876 2,186 Market Segment Share 2001 - - Energy Efficiency 75% 2002 - - Onsite Renewables 14% 2003 - -

  15. Transportation Sector Model of the National Energy Modeling System. Volume 2 -- Appendices: Part 1

    SciTech Connect (OSTI)

    1998-01-01

    This volume contains input data and parameters used in the model of the transportation sector of the National Energy Modeling System. The list of Transportation Sector Model variables includes parameters for the following: Light duty vehicle modules (fuel economy, regional sales, alternative fuel vehicles); Light duty vehicle stock modules; Light duty vehicle fleet module; Air travel module (demand model and fleet efficiency model); Freight transport module; Miscellaneous energy demand module; and Transportation emissions module. Also included in these appendices are: Light duty vehicle market classes; Maximum light duty vehicle market penetration parameters; Aircraft fleet efficiency model adjustment factors; and List of expected aircraft technology improvements.

  16. Session 5: Renewable Energy in the Transportation and Power SectorsŽ

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

    5: "Renewable Energy in the Transportation and Power Sectors" Mr. Michael Schaal: Well, let's get started and we'll have people come in as we move along. Welcome to the session which addresses the topic of renewable energy and the transportation and power sectors, a topic that is very much on the minds of the public at large, policymakers who are pondering the cost benefits and preferred outcomes of a variety of current and potential future laws and regulations, and also researchers

  17. Changes in Energy Intensity in the Manufacturing Sector 1985...

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

    1. Introduction Rankeda EI Numbers of Total Inputs of Energy SIC Codeb Intensity for 1985c Intensity for 1994c 29 18.11 25.85 26 17.82 17.71 33 19.57 16.27 32 14.75 14.69 28 11.09...

  18. Program Program Organization Country Region Topic Sector Sector

    Open Energy Info (EERE)

    European Union EU United Nations Development Programme UNDP Nature Conservation and Nuclear Safety BMU Australian Agency for International Development AusAID Argentina South...

  19. A Network-based View of the U.S. Energy Sector

    Gasoline and Diesel Fuel Update (EIA)

    A Network-based View of the U.S. Energy Sector Vipin Arora | Elizabeth Sendich | Julia Teng February 2016 Independent Statistics & Analysis www.eia.gov U.S. Energy Information Administration Washington, DC 20585 This paper is released to encourage discussion and critical comment. The analysis and conclusions expressed here are those of the authors and not necessarily those of the U.S. Energy Information Administration. WORKING PAPER SERIES February 2016 Vipin Arora, Elizabeth Sendich, and

  20. Kyiv institutional buildings sector energy efficiency program: Technical assessment

    SciTech Connect (OSTI)

    Secrest, T.J.; Freeman, S.L.; Popelka, A.; Shestopal, P.A.; Gagurin, E.V.

    1997-08-01

    The purpose of this assessment is to characterize the economic energy efficiency potential and investment requirements for space heating and hot water provided by district heat in the stock of state and municipal institutional buildings in the city of Kyiv. The assessment involves three activities. The first is a survey of state and municipal institutions to characterize the stock of institutional buildings. The second is to develop an estimate of the cost-effective efficiency potential. The third is to estimate the investment requirements to acquire the efficiency resource. Institutional buildings are defined as nonresidential buildings owned and occupied by state and municipal organizations. General categories of institutional buildings are education, healthcare, and cultural. The characterization activity provides information about the number of buildings, building floorspace, and consumption of space heating and hot water energy provided by the district system.

  1. Buildings Energy Data Book: 3.2 Commercial Sector Characteristics

    Buildings Energy Data Book [EERE]

    1 Total Commercial Floorspace and Number of Buildings, by Year 1980 50.9 (1) N.A. 3.1 (3) 1990 64.3 N.A. 4.5 (3) 2000 (4) 68.5 N.A. 4.7 (5) 2008 78.8 15% N.A. 2010 81.1 26% N.A. 2015 84.1 34% N.A. 2020 89.2 43% N.A. 2025 93.9 52% N.A. 2030 98.2 60% N.A. 2035 103.0 68% N.A. Note(s): Source(s): EIA, Annual Energy Outlook 1994, Jan. 1994, Table A5, p. 62 for 1990 floorspace; EIA, AEO 2003, Jan. 2003, Table A5, p. 127-128 for 2000 floorspace; EIA, Annual Energy Outlook 2012 Early Release, Jan. 2012,

  2. Buildings Energy Data Book: 2.2 Residential Sector Characteristics

    Buildings Energy Data Book [EERE]

    6 Residential Heated Floorspace, as of 2005 (Percent of Total Households) Floorspace (SF) Fewer than 500 6% 500 to 999 26% 1,000 to 1,499 24% 1,500 to 1,999 16% 2,000 to 2,499 9% 2,500 to 2,999 7% 3,000 or more 11% Total 100% Source(s): EIA, 2005 Residential Energy Consumption Survey, Oct. 2008, Table HC1-3.

  3. Buildings Energy Data Book: 3.2 Commercial Sector Characteristics

    Buildings Energy Data Book [EERE]

    4 Share of Commercial Floorspace, by Census Region and Vintage, as of 2003 (Percent) Region Prior to 1960 1960 to 1989 1990 to 2003 Total Northeast 9% 8% 3% 20% Midwest 8% 11% 6% 25% South 5% 18% 14% 37% West 3% 9% 5% 18% 100% Source(s): EIA, 2003 Commercial Buildings Energy Consumption Survey: Building Characteristics Tables, Oct. 2006, Table A2, p. 3-4

  4. Buildings Energy Data Book: 3.2 Commercial Sector Characteristics

    Buildings Energy Data Book [EERE]

    6 Commercial Building Vintage, as of 2003 1919 or Before 5% 1920 to 1945 10% 1946 to 1959 10% 1960 to 1969 12% 1970 to 1979 17% 1980 to 1989 17% 1990 to 1999 20% 2000 to 2003 9% Total 100% Source(s): Percent of Total Floorspace EIA, 2003 Commercial Buildings Energy Consumption Survey: Building Characteristics Tables, Oct. 2006, Table A1, p. 1-

  5. Status of national CO{sub 2}-mitigation projects and initiatives in the Philippine energy sector

    SciTech Connect (OSTI)

    Tupas, C.T.

    1996-12-31

    The Philippines has a huge energy requirement for the next 30 years in order to achieve its economic growth target. Based on an expected annual GDP growth rate of 6.9 percent, the Philippines total energy requirement is estimated to increase at an average of 6.6 percent annually from 1996 to 2025. Gross energy demand shall increase from 219.0 million barrels of fuel oil equivalent (MMBFOE) in 1996 to 552.4 MMBFOE in 2010 and 1,392.6 MMBFOE by 2025. These energy demand levels shall be driven primarily by the substantial increase in fuel requirements for power generation whose share of total energy requirement is 28.3 percent in 1996, 48.0 percent in 2010 and 55.0 percent in 2025. With the expected increase in energy demand, there will necessarily be adverse impacts on the environment. Energy projects and their supporting systems - from fuel extraction and storage to distribution - can and will be major contributors not only to local but also to regional and global environmental pollution and degradation. International experiences and trends in greenhouse gas (GHG) emissions inventory have shown that the energy sector has always been the dominant source of carbon dioxide (CO{sub 2}) - the principal contributor to global climate change. The energy sector`s CO{sub 2} emissions come primarily from fossil fuels combustion. Since energy use is the dominant source of CO{sub 2} emissions, efforts should therefore be concentrated on designing a mitigation strategy in this sector.

  6. Buildings Energy Data Book: 2.2 Residential Sector Characteristics

    Buildings Energy Data Book [EERE]

    2 Share of Households, by Housing Type and Type of Ownership, as of 2005 (Percent) Housing Type Owned Rented Total Single-Family: 61.5% 10.3% 71.7% Detached 57.7% 7.2% 64.9% Attached 3.8% 3.1% 6.8% Multi-Family: 3.7% 18.3% 22.0% 2 to 4 units 1.6% 5.3% 6.9% 5 or more units 2.1% 13.0% 15.0% Mobile Homes 5.1% 1.1% 6.2% Total 70.3% 29.6% 100% Source(s): EIA, 2005 Residential Energy Consumption Survey, Oct. 2008, Table HC3-1 and HC4

  7. Buildings Energy Data Book: 2.2 Residential Sector Characteristics

    Buildings Energy Data Book [EERE]

    5 Characteristics of U.S. Housing by Vintage, as of 2005 Vintage Prior to 1950 20% | 2,677 1,021 775 1950 to 1969 23% | 2,433 927 775 1970 to 1979 17% | 2,666 869 948 1980 to 1989 17% | 2,853 909 1,008 1990 to 1999 16% | 3,366 940 1,245 2000 to 2005 8% | 3,680 1,047 1,425 111.1 2,838 941 1,062 Note(s): Source(s): Total U.S. Homes (millions) U.S. Average 1) Average home sizes include both heated and unheated floor space, including garages. EIA, 2005 Residential Energy Consumption Survey, Oct.

  8. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    3 Residential Aggregate Energy Expenditures, by Year and Major Fuel Type ($2010 Billion) (1) Electricity Total 1980 158.5 1981 164.0 1982 172.3 1983 176.1 1984 178.5 1985 176.8 1986 169.2 1987 167.1 1988 170.1 1989 172.8 1990 168.2 1991 169.9 1992 166.7 1993 175.6 1994 174.9 1995 172.7 1996 181.8 1997 180.0 1998 173.5 1999 174.0 2000 192.8 2001 203.3 2002 192.1 2003 208.8 2004 215.1 2005 236.7 2006 240.0 2007 246.1 2008 259.6 2009 241.6 2010 251.8 2011 251.3 2012 247.1 2013 240.3 2014 239.4 2015

  9. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    Commercial Energy Prices, by Year and Major Fuel Type ($2010 per Million Btu) Electricity Natural Gas Petroleum (1) Average 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 (2) 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 27.39 10.47 27.48 21.15 27.10 10.45 27.73 21.01 27.56 10.32 27.04 21.10 27.52 10.45 27.28 21.18 27.86 10.05 26.41 21.06

  10. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    2 Commercial Energy Prices, by Year and Fuel Type ($2010) Electricity Natural Gas Distillate Oil Residual Oil ($/gal) ($/gal) 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 9.39 104.50 2.79 3.78 9.35 104.74 2.81 3.81 9.47 101.25 2.73 3.69 9.40 103.22 2.76 3.75 9.54 99.28 2.67 3.60 9.51 100.49 2.70

  11. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    9 2003 Energy Expenditures per Square Foot of Commercial Floorspace and per Building, by Building Type ($2010) ($2010) Food Service 4.88 27.2 Mercantile 2.23 38.1 Food Sales 4.68 26.0 Education 1.43 36.6 Health Care 2.76 68.0 Service 1.39 9.1 Public Order and Safety 2.07 32.0 Warehouse and Storage 0.80 13.5 Office 2.01 29.8 Religious Worship 0.76 7.8 Public Assembly 1.73 24.6 Vacant 0.34 4.8 Lodging 1.72 61.5 Other 2.99 65.5 Note(s): Source(s): Mall buildings are no longer included in most CBECs

  12. Implementing Effective Enterprise Security Governance Outline for Energy Sector Executives and Boards

    Office of Environmental Management (EM)

    Implementing Effective Enterprise Security Governance Outline for Energy Sector Executives and Boards Introduction As recent attacks, Presidential Executive Order for Improving Critical Infrastructure Cybersecurity, and Presidential Policy Directive 21 for Critical Infrastructure Security and Resilience have illustrated, managing security risks to our most important organizations and systems, including the electric grid, has become a national security priority. Enterprise security program

  13. Potential for Energy Efficiency Improvement Beyond the Light-Duty Sector

    Broader source: Energy.gov [DOE]

    While there has been considerable research focusing on energy efficiency and fuel substitution options for LDVs, much less attention has been given to non-LDV modes, even though they constitute close to half of the energy used in the transportation sector. We conducted an extensive literature review of the non-LDV modes, and in this report we bring together the salient findings concerning future energy efficiency options in the time period up to 2050. The studies reviewed provided potential energy savings for individual technologies within each mode, as well as an overall energy savings representing the case where all possible improvements are implemented.

  14. Employment-generating projects for the energy and minerals sectors of Honduras. Proyectos generadores de empleos para los sectores energetico y minero de Honduras

    SciTech Connect (OSTI)

    Frank, J.A.

    1988-12-01

    A mission to Honduras invited by the Government of Honduras and sponsored by the Organization of American States addressed the generation of employment in various areas of interest to the country. The mission was made up of experts from numerous countries and international agencies. In the energy sector, the mission recommended consolidating the sector under a coordinating body; carrying out projects to promote reforestation, tree farms, and rational forest utilization; encouraging industrial energy conservation; developing alternative energy sources; and promoting rural electrification and expansion of the electrical grid. In the mining sector, the mission supported promotion and technical assistance for small gold-leaching and placer operations, the national mineral inventory, detailed exploration of promising sites, and the development of a mining school. 13 refs., 7 tabs.

  15. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    1 Building Energy Prices, by Year and Major Fuel Type ($2010 per Million Btu) Residential Buildings Commercial Buildings Building Electricity Natural Gas Petroleum (1) Avg. Electricity Natural Gas Petroleum (2) Avg. Avg. (3) 1980 36.40 8.35 16.77 17.64 37.22 7.70 13.06 18.52 17.99 1981 38.50 8.88 18.35 19.09 39.06 8.29 14.78 20.56 19.68 1982 40.15 10.08 17.28 19.98 40.15 9.40 13.28 21.21 20.48 1983 40.43 11.30 16.08 21.00 39.51 10.43 12.53 21.55 21.23 1984 38.80 11.02 15.61 20.20 38.68 10.00

  16. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    2 Building Energy Prices, by Year and Fuel Type ($2010) (cents/therm) (cents/gal) ($/gal) 1980 12.42 83.51 1.53 2.24 12.70 77.01 1.43 2.05 1981 13.14 88.83 1.47 2.51 13.33 82.90 1.63 2.32 1982 13.70 100.83 1.54 2.30 13.70 93.95 1.40 2.11 1983 13.79 113.04 1.51 2.14 13.48 104.33 1.30 1.75 1984 13.24 110.16 1.46 2.10 13.20 100.01 1.37 1.68 1985 13.28 106.80 1.37 1.96 13.06 95.96 1.21 1.56 1986 13.05 99.76 1.25 1.54 12.66 86.86 0.71 1.01 1987 12.72 92.16 1.22 1.42 11.92 79.32 0.79 1.05 1988 12.36

  17. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    3 Buildings Aggregate Energy Expenditures, by Year and Major Fuel Type ($2010 Billion) (1) Residential Buildings Commercial Buildings Total Building Electricity Natural Gas Petroleum (2) Total Electricity Natural Gas Petroleum (3) Total Expenditures 1980 89.1 40.5 28.9 158.5 70.9 20.5 17.2 108.6 267.2 1981 94.9 41.3 27.8 164.0 79.4 21.4 16.5 117.3 281.3 1982 99.9 47.9 24.5 172.3 83.4 25.1 13.7 122.2 294.5 1983 103.6 51.0 21.4 176.1 83.6 26.1 14.6 124.3 300.4 1984 103.3 51.6 23.6 178.5 87.6 25.9

  18. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    5 2010 Buildings Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal Electricity Total Percent Space Heating (3) 53.7 14.2 0.9 8.0 0.6 23.7 0.1 23.2 100.8 23.4% Space Cooling 0.4 61.3 61.7 14.3% Lighting 59.3 59.3 13.8% Water Heating 18.3 2.6 2.0 4.6 17.8 40.7 9.4% Refrigeration (4) 26.9 26.9 6.2% Electronics (5) 26.1 26.1 6.1% Ventilation (6) 15.9 15.9 3.7% Cooking 4.0 0.8 0.8 8.8 13.6 3.2% Computers 12.1 12.1 2.8% Wet

  19. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    6 2015 Buildings Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Gas Distil. Resid. LPG Oth(2) Total Coal Total Percent Space Heating (3) 49.5 15.9 1.3 8.1 0.7 25.9 0.2 18.7 94.3 22.7% Space Cooling 0.3 48.0 48.3 11.6% Lighting 45.9 45.9 11.0% Water Heating 17.6 2.6 1.5 4.1 18.3 40.0 9.6% Refrigeration (4) 24.9 24.9 6.0% Electronics (5) 19.8 19.8 4.7% Ventilation (6) 15.1 15.1 3.6% Computers 11.6 11.6 2.8% Wet Cleaning (7) 0.6 10.8 11.4 2.7% Cooking 3.9 0.9 0.9 4.4

  20. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    7 2025 Buildings Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal Electricity Total Percent Space Heating (3) 56.7 14.3 1.5 7.8 0.7 24.3 0.2 19.5 100.7 22.0% Space Cooling 0.3 50.5 50.9 11.1% Lighting 45.2 45.2 9.9% Water Heating 21.3 2.3 1.3 3.6 19.6 44.4 9.7% Refrigeration (4) 24.9 24.9 5.4% Electronics (5) 23.2 23.2 5.1% Computers 13.2 13.2 2.9% Wet Clean (6) 0.8 9.8 10.5 2.3% Cooking 4.8 0.8 0.8 4.9 10.5 2.3%

  1. Buildings Energy Data Book: 1.2 Building Sector Expenditures

    Buildings Energy Data Book [EERE]

    8 2035 Buildings Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal Electricity Total Percent Space Heating (3) 63.4 13.0 1.6 7.7 0.8 23.1 0.2 20.6 107.2 20.9% Water Heating 23.8 2.2 1.2 3.4 35.8 63.0 12.3% Space Cooling 0.4 55.7 56.1 10.9% Lighting 47.8 47.8 9.3% Electronics (4) 27.2 27.2 5.3% Refrigeration (5) 27.0 27.0 5.3% Computers 14.8 14.8 2.9% Cooking 5.8 0.8 0.8 5.4 12.1 2.3% Wet Clean (6) 0.9 10.4 11.3 2.2%

  2. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    Residential Energy Prices, by Year and Major Fuel Type ($2010 per Million Btu) Electricity Natural Gas Petroleum (1) Avg. 1980 36.40 8.35 16.77 17.64 1981 38.50 8.88 18.35 19.09 1982 40.15 10.08 17.28 19.98 1983 40.43 11.30 16.08 21.00 1984 38.80 11.02 15.61 20.20 1985 38.92 10.68 14.61 20.10 1986 38.24 9.98 11.88 19.38 1987 37.29 9.22 11.23 18.73 1988 36.22 8.80 10.83 18.02 1989 35.67 8.71 11.96 17.93 1990 35.19 8.63 13.27 18.64 1991 34.88 8.38 12.49 18.31 1992 34.79 8.28 11.23 17.76 1993

  3. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    2 Residential Energy Prices, by Year and Fuel Type ($2010) LPG ($/gal) 1980 2.24 1981 2.51 1982 2.30 1983 2.14 1984 2.10 1985 1.96 1986 1.54 1987 1.42 1988 1.39 1989 1.48 1990 1.69 1991 1.56 1992 1.40 1993 1.33 1994 1.27 1995 1.22 1996 1.37 1997 1.34 1998 1.15 1999 1.16 2000 1.70 2001 1.59 2002 1.42 2003 1.67 2004 1.84 2005 2.36 2006 2.64 2007 2.81 2008 3.41 2009 2.52 2010 2.92 2011 3.62 2012 3.65 2013 3.43 2014 3.60 2015 3.74 2016 3.79 2017 3.86 2018 3.89 2019 3.92 2020 3.96 2021 3.99 2022 4.02

  4. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    5 2010 Residential Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. LPG Kerosene Total Coal Electricity Total Percent Space Heating (2) 38.7 11.2 8.0 19.8 0.0 14.3 72.9 28.9% Space Cooling (3) 0.0 35.4 35.4 14.0% Water Heating (4) 14.3 2.1 2.0 4.0 14.2 32.6 12.9% Lighting 22.6 22.6 9.0% Refrigeration (5) 14.9 14.9 5.9% Electronics (6) 17.8 17.8 7.1% Cooking 2.4 0.8 0.8 6.0 9.2 3.7% Wet Cleaning (7) 0.6 10.7 11.3 4.5% Computers 5.6 5.6 2.2% Other

  5. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    6 2015 Residential Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. LPG Kerosene Total Coal Electricity Total Percent Space Heating (2) 35.0 13.0 8.1 21.6 0.0 14.0 70.6 29.2% Space Cooling (3) 0.0 33.8 33.8 14.0% Water Heating 13.5 1.9 1.5 3.4 15.8 32.7 13.5% Lighting 17.6 17.6 7.3% Refrigeration (4) 15.0 15.0 6.2% Electronics (5) 10.9 10.9 4.5% Wet Cleaning (6) 0.6 10.8 11.4 4.7% Cooking 2.2 0.9 0.9 3.8 6.8 2.8% Computers 6.3 6.3 2.6% Other (7)

  6. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    7 2025 Residential Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. LPG Kerosene Total Coal Electricity Total Percent Space Heating (2) 39.7 11.5 7.8 19.9 0.0 15.0 74.5 28.6% Space Cooling (3) 0.0 36.2 36.2 13.9% Water Heating 16.0 1.4 1.3 2.7 17.1 35.9 13.8% Lighting 15.2 15.2 5.8% Refrigeration (4) 15.5 15.5 6.0% Electronics (5) 12.0 12.0 4.6% Wet Cleaning (6) 0.8 9.8 10.5 4.1% Cooking 2.7 0.8 0.8 4.3 7.8 3.0% Computers 7.7 7.7 2.9% Other (7)

  7. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    8 2035 Residential Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. LPG Kerosene Total Coal Electricity Total Percent Space Heating (2) 44.3 10.3 7.7 18.6 0.0 16.0 79.0 27.4% Space Cooling (3) 0.0 40.6 40.6 14.1% Water Heating 17.6 1.2 1.2 2.3 17.7 37.6 13.0% Lighting 15.5 15.5 5.4% Refrigeration (4) 17.0 17.0 5.9% Electronics (5) 14.2 14.2 4.9% Wet Cleaning (6) 0.9 10.4 11.3 3.9% Cooking 3.2 0.8 0.8 4.8 8.9 3.1% Computers 8.7 8.7 3.0% Other (7)

  8. Buildings Energy Data Book: 2.3 Residential Sector Expenditures

    Buildings Energy Data Book [EERE]

    9 Average Annual Energy Expenditures per Household, by Year ($2010) Year 1980 1,991 1981 1,981 1982 2,058 1983 2,082 1984 2,067 1985 2,012 1986 1,898 1987 1,846 1988 1,849 1989 1,848 1990 1,785 1991 1,784 1992 1,729 1993 1,797 1994 1,772 1995 1,727 1996 1,800 1997 1,761 1998 1,676 1999 1,659 2000 1,824 2001 1,900 2002 1,830 2003 1,978 2004 2,018 2005 2,175 2006 2,184 2007 2,230 2008 2,347 2009 2,173 2010 2,201 2011 2,185 2012 2,123 2013 2,056 2014 2,032 2015 2,030 2016 2,007 2017 1,992 2018

  9. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    4 2010 Commercial Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal (3) Electricity Total Percent Lighting 35.4 35.4 19.7% Space Heating 15.0 2.9 0.9 0.1 3.9 0.1 8.5 27.5 15.3% Space Cooling 0.4 25.0 25.3 14.1% Ventilation 15.9 15.9 8.9% Refrigeration 11.6 11.6 6.5% Water Heating 4.0 0.6 0.6 2.7 7.3 4.1% Electronics 7.8 7.8 4.3% Computers 6.3 6.3 3.5% Cooking 1.6 0.7 2.3 1.3% Other (4) 2.7 0.3 3.3 1.2 4.8 20.4 28.0

  10. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    5 2015 Commercial Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal (3) Electricity Total Percent Lighting 28.4 28.4 16.3% Space Heating 14.6 2.9 1.3 0.1 4.3 0.1 4.7 23.7 13.6% Ventilation 15.1 15.1 8.6% Space Cooling 0.3 14.2 14.5 8.3% Refrigeration 9.9 9.9 5.7% Electronics 8.8 8.8 5.1% Water Heating 4.1 0.7 0.7 2.5 7.3 4.2% Computers 5.3 5.3 3.0% Cooking 1.7 0.6 2.3 1.3% Other (4) 2.9 0.3 3.7 1.4 5.4 22.8 31.1 17.8%

  11. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    6 2025 Commercial Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal (3) Electricity Total Percent Lighting 30.1 30.1 15.2% Space Heating 17.1 2.8 1.5 0.1 4.4 0.2 4.5 26.1 13.3% Electronics 11.2 11.2 5.7% Space Cooling 0.3 14.3 14.6 7.4% Water Heating 5.2 0.8 0.8 2.5 8.5 4.3% Computers 5.5 5.5 2.8% Refrigeration 9.4 9.4 4.8% Ventilation 16.6 16.6 8.4% Cooking 2.1 0.6 2.7 1.4% Other (4) 4.8 0.3 4.3 1.7 6.3 31.2 42.3 21.5%

  12. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    7 2035 Commercial Energy End-Use Expenditure Splits, by Fuel Type ($2010 Billion) (1) Natural Petroleum Gas Distil. Resid. LPG Oth(2) Total Coal (3) Electricity Total Percent Lighting 32.3 32.3 14.4% Space Heating 19.0 2.7 1.6 0.2 4.5 0.2 4.6 28.2 12.5% Water Heating 6.3 1.0 1.0 18.1 25.4 11.3% Space Cooling 0.4 15.1 15.5 6.9% Electronics 13.0 13.0 5.8% Refrigeration 10.0 10.0 4.4% Computers 6.0 6.0 2.7% Cooking 2.6 0.6 3.2 1.4% Ventilation 2.4 2.4 1.1% Other (4) 9.3 0.4 4.9 2.0 7.2 40.9 57.5

  13. Buildings Energy Data Book: 3.3 Commercial Sector Expenditures

    Buildings Energy Data Book [EERE]

    8 Average Annual Energy Expenditures per Square Foot of Commercial Floorspace, by Year ($2010) Year $/SF 1980 (1) 2.12 1981 2.22 (2) 1982 2.24 1983 2.21 1984 2.25 1985 2.20 1986 2.06 1987 2.00 1988 1.99 1989 2.01 1990 1.98 1991 1.92 1992 1.86 1993 1.96 1994 2.05 1995 2.12 1996 2.10 1997 2.08 1998 1.97 1999 1.88 2000 2.06 2001 2.20 2002 2.04 2003 2.13 2004 2.16 2005 2.30 2006 2.36 2007 2.35 2008 1.71 2009 2.43 2010 2.44 2011 2.44 2012 2.35 2013 2.28 2014 2.27 2015 2.29 2016 2.29 2017 2.28 2018

  14. Lost Opportunities in the Buildings Sector: Energy-Efficiency Analysis and Results

    SciTech Connect (OSTI)

    Dirks, James A.; Anderson, David M.; Hostick, Donna J.; Belzer, David B.; Cort, Katherine A.

    2008-09-12

    This report summarizes the results and the assumptions used in an analysis of the potential “lost efficiency opportunities” in the buildings sector. These targets of opportunity are those end-uses, applications, practices, and portions of the buildings market which are not currently being addressed, or addressed fully, by the Building Technologies Program (BTP) due to lack of resources. The lost opportunities, while a significant increase in effort and impact in the buildings sector, still represent only a small portion of the full technical potential for energy efficiency in buildings.

  15. Executive Summary - Natural Gas and the Transformation of the U.S. Energy Sector: Electricity

    SciTech Connect (OSTI)

    Logan, J.; Heath, G.; Macknick, J.; Paranhos, E.; Boyd, W.; Carlson, K.

    2013-01-01

    In November 2012, the Joint Institute for Strategic Energy Analysis (JISEA) released a new report, 'Natural Gas and the Transformation of the U.S. Energy Sector: Electricity.' The study provides a new methodological approach to estimate natural gas related greenhouse gas (GHG) emissions, tracks trends in regulatory and voluntary industry practices, and explores various electricity futures. The Executive Summary provides key findings, insights, data, and figures from this major study.

  16. Energy in Europe and Central Asia: A sector strategy for the World Bank Group

    SciTech Connect (OSTI)

    1998-12-31

    Many countries in the Europe and Central Asia region have had an excess production capacity, lower quality supply, decreasing demand, and inefficient consumption in the energy sector since the late 1980s. This report outlines the four main objectives that form the World Bank Group`s strategy for reform: assisting governments to protect the public interest, supporting economic transition, facilitating private investments, and promoting regional initiatives to increase energy trade.

  17. Energy use and CO2 emissions of Chinas industrial sector from a global perspective

    SciTech Connect (OSTI)

    Zhou, Sheng; Kyle, G. Page; Yu, Sha; Clarke, Leon E.; Eom, Jiyong; Luckow, Patrick W.; Chaturvedi, Vaibhav; Zhang, Xiliang; Edmonds, James A.

    2013-07-10

    The industrial sector has accounted for more than 50% of Chinas final energy consumption in the past 30 years. Understanding the future emissions and emissions mitigation opportunities depends on proper characterization of the present-day industrial energy use, as well as industrial demand drivers and technological opportunities in the future. Traditionally, however, integrated assessment research has handled the industrial sector of China in a highly aggregate form. In this study, we develop a technologically detailed, service-oriented representation of 11 industrial subsectors in China, and analyze a suite of scenarios of future industrial demand growth. We find that, due to anticipated saturation of Chinas per-capita demands of basic industrial goods, industrial energy demand and CO2 emissions approach a plateau between 2030 and 2040, then decrease gradually. Still, without emissions mitigation policies, the industrial sector remains heavily reliant on coal, and therefore emissions-intensive. With carbon prices, we observe some degree of industrial sector electrification, deployment of CCS at large industrial point sources of CO2 emissions at low carbon prices, an increase in the share of CHP systems at industrial facilities. These technological responses amount to reductions of industrial emissions (including indirect emission from electricity) are of 24% in 2050 and 66% in 2095.

  18. Industry Partnerships for Cybersecurity of Energy Delivery Systems (CEDS) Research, Development and Demonstration for the Energy Sector Funding Opportunity Announcement

    Broader source: Energy.gov [DOE]

    Modernizing our electric power grid has long been a key priority for the Department of Energy, and this month the Department is moving forward on that front with a series of announcements related to our ongoing Grid Modernization Initiative. As part of that effort, the Office of Electricity Delivery and Energy Reliability announced approximately $23 million in funding for the research and development of advanced cybersecurity technologies to meet the unique requirements of the energy sector.

  19. Model documentation report: Commercial Sector Demand Module of the National Energy Modeling System

    SciTech Connect (OSTI)

    1998-01-01

    This report documents the objectives, analytical approach and development of the National Energy Modeling System (NEMS) Commercial Sector Demand Module. The report catalogues and describes the model assumptions, computational methodology, parameter estimation techniques, model source code, and forecast results generated through the synthesis and scenario development based on these components. The NEMS Commercial Sector Demand Module is a simulation tool based upon economic and engineering relationships that models commercial sector energy demands at the nine Census Division level of detail for eleven distinct categories of commercial buildings. Commercial equipment selections are performed for the major fuels of electricity, natural gas, and distillate fuel, for the major services of space heating, space cooling, water heating, ventilation, cooking, refrigeration, and lighting. The algorithm also models demand for the minor fuels of residual oil, liquefied petroleum gas, steam coal, motor gasoline, and kerosene, the renewable fuel sources of wood and municipal solid waste, and the minor services of office equipment. Section 2 of this report discusses the purpose of the model, detailing its objectives, primary input and output quantities, and the relationship of the Commercial Module to the other modules of the NEMS system. Section 3 of the report describes the rationale behind the model design, providing insights into further assumptions utilized in the model development process to this point. Section 3 also reviews alternative commercial sector modeling methodologies drawn from existing literature, providing a comparison to the chosen approach. Section 4 details the model structure, using graphics and text to illustrate model flows and key computations.

  20. Summary of Proposed Metrics - QER Technical Workshop on Energy Sector Resilience

    Broader source: Energy.gov (indexed) [DOE]

    Summary of Proposed Metrics - QER Technical Workshop on Energy Sector Resilience Metrics (4/29/2014) Theory - RAND presentation  Guidelines for measuring resilience o Resilience describes the state of service from a system in response to a disruption (e.g., % service provided/time) o Best metrics depend on who is measuring resilience and why (systems, disruptions, responses, timescales) o Resilience metrics are used for many purposes and at may levels (supporting both strategic and

  1. High Penetration of Renewable Energy in the Transportation Sector: Scenarios, Barriers, and Enablers; Preprint

    SciTech Connect (OSTI)

    Vimmerstedt, L.; Brown, A.; Heath, G.; Mai, T.; Ruth, M.; Melaina, M.; Simpkins, T.; Steward, D.; Warner, E.; Bertram, K.; Plotkin, S.; Patel, D.; Stephens, T.; Vyas, A.

    2012-06-01

    Transportation accounts for 71% of U.S. petroleum use and 33% of its greenhouse gases emissions. Pathways toward reduced greenhouse gas emissions and petroleum dependence in the transportation sector have been analyzed in considerable detail, but with some limitations. To add to this knowledge, the U.S. Department of Energy has launched a study focused on underexplored greenhouse-gas-abatement and oil-savings opportunities related to transportation. This Transportation Energy Futures study analyzes specific issues and associated key questions to strengthen the existing knowledge base and help cultivate partnerships among federal agencies, state and local governments, and industry.

  2. Model documentation report: Residential sector demand module of the National Energy Modeling System

    SciTech Connect (OSTI)

    1997-01-01

    This report documents the objectives, analytical approach, and development of the National Energy Modeling System (NEMS) Residential Sector Demand Module. The report catalogues and describes the model assumptions, computational methodology, parameter estimation techniques, and FORTRAN source code. This document serves three purposes. First, it is a reference document that provides a detailed description for energy analysts, other users, and the public. Second, this report meets the legal requirement of the Energy Information Administration (EIA) to provide adequate documentation in support of its statistical and forecast reports according to Public Law 93-275, section 57(b)(1). Third, it facilitates continuity in model development by providing documentation from which energy analysts can undertake model enhancements, data updates, and parameter refinements.

  3. Improving the Usability of Integrated Assessment for Adaptation Practice: Insights from the U.S. Southeast Energy Sector

    SciTech Connect (OSTI)

    de Bremond, Ariane; Preston, Benjamin; Rice, Jennie S.

    2014-10-01

    Energy systems comprise a key sector of the U.S. economy, and one that has been identified as potentially vulnerable to the effects of climate variability and change. However, understanding of adaptation processes in energy companies and private entities more broadly is limited. It is unclear, for example, the extent to which energy companies are well-served by existing knowledge and tools emerging from the impacts, adaptation and vulnerability (IAV) and integrated assessment modeling (IAM) communities and/or what experiments, analyses, and model results have practical utility for informing adaptation in the energy sector. As part of a regional IAM development project, we investigated available evidence of adaptation processes in the energy sector, with a particular emphasis on the U.S. Southeast and Gulf Coast region. A mixed methods approach of literature review and semi-structured interviews with key informants from energy utilities was used to compare existing knowledge from the IAV community with that of regional stakeholders. That comparison revealed that much of the IAV literature on the energy sector is climate-centric and therefore disconnected from the more integrated decision-making processes and institutional perspectives of energy utilities. Increasing the relevance of research and assessment for the energy sector will necessitate a greater investment in integrated assessment and modeling efforts that respond to practical decision-making needs as well as greater collaboration between energy utilities and researchers in the design, execution, and communication of those efforts.

  4. Buildings Energy Data Book: 8.1 Buildings Sector Water Consumption

    Buildings Energy Data Book [EERE]

    1 Buildings Sector Water Consumption March 2012 8.1.2 Average Energy Intensity of Public Water Supplies by Location (kWh per Million Gallons) Location United States (2) 627 437 1,363 United States (3) 65 (6) 1,649 Northern California Indoor 111 1,272 1,911 Northern California Outdoor 111 1,272 0 Southern California Indoor (5) 111 1,272 1,911 Southern California Outdoor 111 1,272 0 Iowa (6) 380 1,570 Massachusetts (6) (6) 1,750 Wisconsin Class AB (4) - - Wisconsin Class C (4) - - Wisconsin Class

  5. Detection and Analysis of Threatsto the Energy Sector (DATES) May 2008

    Broader source: Energy.gov [DOE]

    A groundbreaking integrated capability in intrusion detection, security event management, and sector-wide threat analysis.

  6. Energy Demand: Limits on the Response to Higher Energy Prices in the End-Use Sectors (released in AEO2007)

    Reports and Publications (EIA)

    2007-01-01

    Energy consumption in the end-use demand sectorsresidential, commercial, industrial, and transportationgenerally shows only limited change when energy prices increase. Several factors that limit the sensitivity of end-use energy demand to price signals are common across the end-use sectors. For example, because energy generally is consumed in long-lived capital equipment, short-run consumer responses to changes in energy prices are limited to reductions in the use of energy services or, in a few cases, fuel switching; and because energy services affect such critical lifestyle areas as personal comfort, medical services, and travel, end-use consumers often are willing to absorb price increases rather than cut back on energy use, especially when they are uncertain whether price increases will be long-lasting. Manufacturers, on the other hand, often are able to pass along higher energy costs, especially in cases where energy inputs are a relatively minor component of production costs. In economic terms, short-run energy demand typically is inelastic, and long-run energy demand is less inelastic or moderately elastic at best.

  7. Public Interest Energy Research (PIER) Program. Final Project Report. California Energy Balance Update and Decomposition Analysis for the Industry and Building Sectors

    SciTech Connect (OSTI)

    de la Rue du Can, Stephane; Hasanbeigi, Ali; Sathaye, Jayant

    2010-12-01

    This report on the California Energy Balance version 2 (CALEB v2) database documents the latest update and improvements to CALEB version 1 (CALEB v1) and provides a complete picture of how energy is supplied and consumed in the State of California. The CALEB research team at Lawrence Berkeley National Laboratory (LBNL) performed the research and analysis described in this report. CALEB manages highly disaggregated data on energy supply, transformation, and end-use consumption for about 40 different energy commodities, from 1990 to 2008. This report describes in detail California's energy use from supply through end-use consumption as well as the data sources used. The report also analyzes trends in energy demand for the "Manufacturing" and "Building" sectors. Decomposition analysis of energy consumption combined with measures of the activity driving that consumption quantifies the effects of factors that shape energy consumption trends. The study finds that a decrease in energy intensity has had a very significant impact on reducing energy demand over the past 20 years. The largest impact can be observed in the industry sector where energy demand would have had increased by 358 trillion British thermal units (TBtu) if subsectoral energy intensities had remained at 1997 levels. Instead, energy demand actually decreased by 70 TBtu. In the "Building" sector, combined results from the "Service" and "Residential" subsectors suggest that energy demand would have increased by 264 TBtu (121 TBtu in the "Services" sector and 143 TBtu in the "Residential" sector) during the same period, 1997 to 2008. However, energy demand increased at a lesser rate, by only 162 TBtu (92 TBtu in the "Services" sector and 70 TBtu in the "Residential" sector). These energy intensity reductions can be indicative of energyefficiency improvements during the past 10 years. The research presented in this report provides a basis for developing an energy-efficiency performance index to measure progress over time in the State of California.

  8. SEADS 3.0 Sectoral Energy/Employment Analysis and Data System

    SciTech Connect (OSTI)

    Roop, Joseph M.; Anderson, David A.; Schultz, Robert W.; Elliott, Douglas B.

    2007-12-17

    SEADS 3.0, the Sectoral Energy/Employment Analysis and Data System, is a revision and upgrading of SEADS--PC, a software package designed for the analysis of policy that could be described by modifying final demands of consumer, businesses, or governments (Roop, et al., 1995). If a question can be formulated so that implications can be translated into changes in final demands for goods and services, then SEADS 3.0 provides a quick and easy tool to assess preliminary impacts. And SEADS 3.0 should be considered just that: a quick and easy way to get preliminary results. Often a thorough answer, even to such a simple question as, What would be the effect on U. S. energy use and employment if the Federal Government doubled R&D expenditures? requires a more sophisticated analytical framework than the input-output structure embedded in SEADS 3.0. This tool uses a static, input-output model to assess the impacts of changes in final demands on first industry output, then employment and energy use. The employment and energy impacts are derived by multiplying the industry outputs (derived from the changed final demands) by industry-specific energy and employment coefficients. The tool also allows for the specification of regional or state employment impacts, though this option is not available for energy impacts.

  9. Sector-specific issues and reporting methodologies supporting the General Guidelines for the voluntary reporting of greenhouse gases under Section 1605(b) of the Energy Policy Act of 1992. Volume 2: Part 4, Transportation sector; Part 5, Forestry sector; Part 6, Agricultural sector

    SciTech Connect (OSTI)

    Not Available

    1994-10-01

    This volume, the second of two such volumes, contains sector-specific guidance in support of the General Guidelines for the voluntary reporting of greenhouse gas emissions and carbon sequestration. This voluntary reporting program was authorized by Congress in Section 1605(b) of the Energy Policy Act of 1992. The General Guidelines, bound separately from this volume, provide the overall rationale for the program, discuss in general how to analyze emissions and emission reduction/carbon sequestration projects, and address programmatic issues such as minimum reporting requirements, time parameters, international projects, confidentiality, and certification. Together, the General Guidelines and the guidance in these supporting documents will provide concepts and approaches needed to prepare the reporting forms. This second volume of sector-specific guidance covers the transportation sector, the forestry sector, and the agricultural sector.

  10. Issues in Energy Economics Led by Emerging Linkages between the Natural Gas and Power Sectors

    SciTech Connect (OSTI)

    Platt, Jeremy B.

    2007-09-15

    Fuel prices in 2006 continued at record levels, with uranium continuing upward unabated and coal, SO{sub 2} emission allowances, and natural gas all softening. This softening did not continue for natural gas, however, whose prices rose, fell and rose again, first following weather influences and, by the second quarter of 2007, continuing at high levels without any support from fundamentals. This article reviews these trends and describes the remarkable increases in fuel expenses for power generation. By the end of 2005, natural gas claimed 55% of annual power sector fuel expenses, even though it was used for only 19% of electric generation. Although natural gas is enormously important to the power sector, the sector also is an important driver of the natural gas market-growing to over 28% of the market even as total use has declined. The article proceeds to discuss globalization, natural gas price risk, and technology developments. Forces of globalization are poised to affect the energy markets in new ways-new in not being only about oil. Of particular interest in the growth of intermodal traffic and its a little-understood impacts on rail traffic patterns and transportation costs, and expected rapidly expanding LNG imports toward the end of the decade. Two aspects of natural gas price risk are discussed: how understanding the use of gas in the power sector helps define price ceilings and floors for natural gas, and how the recent increase in the natural gas production after years of record drilling could alter the supply-demand balance for the better. The article cautions, however, that escalation in natural gas finding and development costs is countering the more positive developments that emerged during 2006. Regarding technology, the exploitation of unconventional natural gas was one highlight. So too was the queuing up of coal-fired power plants for the post-2010 period, a phenomenon that has come under great pressure with many consequences including increased pressures in the natural gas market. The most significant illustration of these forces was the early 2007 suspension of development plans by a large power company, well before the Supreme Court's ruling on CO{sub 2} as a tailpipe pollutant and President Bush's call for global goals on CO{sub 2} emissions.

  11. Mexico-EC-LEDS in the Agriculture Sector | Open Energy Information

    Open Energy Info (EERE)

    EC-LEDS in the Agriculture Sector Jump to: navigation, search Name Mexico-EC-LEDS in the Agriculture Sector AgencyCompany Organization United States Department of Agriculture,...

  12. Vietnam-EC-LEDS in the Agriculture Sector | Open Energy Information

    Open Energy Info (EERE)

    Sector Climate, Land Focus Area Agriculture, Economic Development, Greenhouse Gas, Land Use Topics Adaptation, Implementation, Low emission development planning, -LEDS,...

  13. Costa Rica-EC-LEDS in the Agriculture Sector | Open Energy Information

    Open Energy Info (EERE)

    Sector Climate, Land Focus Area Agriculture, Economic Development, Greenhouse Gas, Land Use Topics Adaptation, Implementation, Low emission development planning, -LEDS,...

  14. Kenya-EC-LEDS in the Agriculture Sector | Open Energy Information

    Open Energy Info (EERE)

    Sector Climate, Land Focus Area Agriculture, Economic Development, Greenhouse Gas, Land Use Topics Adaptation, Implementation, Low emission development planning, -LEDS,...

  15. Chemicals Sector (NAICS 325) Energy and GHG Combustion Emissions Profile, November 2012

    Office of Environmental Management (EM)

    39 2.2 CHEMICALS SECTOR (NAICS 325) 2.2.1. Overview of the Chemicals Manufacturing Sector The chemicals manufacturing sector is an integral component of the U.S. economy, converting raw materials such as petroleum, natural gas, minerals, coal, air, and water into more than 70,000 diverse products. Chemical products are critical components of consumer goods and are found in everything from automobiles to plastics to electronics. This sector creates its diverse output from raw materials of two

  16. Natural Gas and the Transformation of the U.S. Energy Sector: Electricity

    SciTech Connect (OSTI)

    Logan, J.; Heath, G.; Macknick, J.; Paranhos, E.; Boyd, W.; Carlson, K.

    2012-11-01

    The Joint Institute for Strategic Energy Analysis (JISEA) designed this study to address four related key questions, which are a subset of the wider dialogue on natural gas: 1. What are the life cycle greenhouse gas (GHG) emissions associated with shale gas compared to conventional natural gas and other fuels used to generate electricity?; 2. What are the existing legal and regulatory frameworks governing unconventional gas development at federal, state, and local levels, and how are they changing in response to the rapid industry growth and public concerns?; 3. How are natural gas production companies changing their water-related practices?; and 4. How might demand for natural gas in the electric sector respond to a variety of policy and technology developments over the next 20 to 40 years?

  17. Iron and Steel Sector (NAICS 3311 and 3312) Energy and GHG Combustion Emissions Profile, November 2012

    Office of Environmental Management (EM)

    99 2.6 IRON AND STEEL SECTOR (NAICS 3311, 3312) 2.6.1. Overview of the Iron and Steel Manufacturing Sector The iron and steel sector is an essential part of the U.S. manufacturing sector, providing the necessary raw material for the extensive industrial supply chain. U.S. infrastructure is heavily reliant on the U.S. iron and steel sector, as it provides the foundation for construction (bridges, buildings), transportation systems (railroads, cars, trucks), utility systems (municipal water

  18. Nuclear Energy R&D Imperative 3: Enable a Transition Away from Fossil Fuel in the Transportation and Industrial Sectors

    SciTech Connect (OSTI)

    David Petti; J. Stephen Herring

    2010-03-01

    As described in the Department of Energy Office of Nuclear Energys Nuclear Energy R&D Roadmap, nuclear energy can play a significant role in supplying energy for a growing economy while reducing both our dependence on foreign energy supplies and emissions from the burning of fossil fuels. The industrial and transportation sectors are responsible for more than half of the greenhouse gas emissions in the U.S., and imported oil supplies 70% of the energy used in the transportation sector. It is therefore important to examine the various ways nuclear energy can facilitate a transition away from fossil fuels to secure environmentally sustainable production and use of energy in the transportation and manufacturing industry sectors. Imperative 3 of the Nuclear Energy R&D Roadmap, entitled Enable a Transition Away from Fossil Fuels by Producing Process Heat for use in the Transportation and Industrial Sectors, addresses this need. This document presents an Implementation Plan for R&D efforts related to this imperative. The expanded use of nuclear energy beyond the electrical grid will contribute significantly to overcoming the three inter-linked energy challenges facing U.S. industry: the rising and volatile prices for premium fossil fuels such as oil and natural gas, dependence on foreign sources for these fuels, and the risks of climate change resulting from carbon emissions. Nuclear energy could be used in the industrial and transportation sectors to: Generate high temperature process heat and electricity to serve industrial needs including the production of chemical feedstocks for use in manufacturing premium fuels and fertilizer products, Produce hydrogen for industrial processes and transportation fuels, and Provide clean water for human consumption by desalination and promote wastewater treatment using low-grade nuclear heat as a useful additional benefit. Opening new avenues for nuclear energy will significantly enhance our nations energy security through more effective utilization of our countrys resources while simultaneously providing economic stability and growth (through predictable energy prices and high value jobs), in an environmentally sustainable and secure manner (through lower land and water use, and decreased byproduct emissions). The reduction in imported oil will also increase the retention of wealth within the U.S. economy while still supporting economic growth. Nuclear energy is the only non-fossil fuel that has been demonstrated to reliably supply energy for a growing industrial economy.

  19. Transportation Energy Futures Series: Potential for Energy Efficiency Improvement Beyond the Light-Duty-Vehicle Sector

    SciTech Connect (OSTI)

    Vyas, A. D.; Patel, D. M.; Bertram, K. M.

    2013-03-01

    Considerable research has focused on energy efficiency and fuel substitution options for light-duty vehicles, while much less attention has been given to medium- and heavy-duty trucks, buses, aircraft, marine vessels, trains, pipeline, and off-road equipment. This report brings together the salient findings from an extensive review of literature on future energy efficiency options for these non-light-duty modes. Projected activity increases to 2050 are combined with forecasts of overall fuel efficiency improvement potential to estimate the future total petroleum and greenhouse gas (GHG) emissions relative to current levels. This is one of a series of reports produced as a result of the Transportation Energy Futures (TEF) project, a Department of Energy-sponsored multi-agency project initiated to pinpoint underexplored strategies for abating GHGs and reducing petroleum dependence related to transportation.

  20. Transportation Energy Futures Series. Potential for Energy Efficiency Improvement Beyond the Light-Duty-Vehicle Sector

    SciTech Connect (OSTI)

    Vyas, A. D.; Patel, D. M.; Bertram, K. M.

    2013-02-01

    Considerable research has focused on energy efficiency and fuel substitution options for light-duty vehicles, while much less attention has been given to medium- and heavy-duty trucks, buses, aircraft, marine vessels, trains, pipeline, and off-road equipment. This report brings together the salient findings from an extensive review of literature on future energy efficiency options for these non-light-duty modes. Projected activity increases to 2050 are combined with forecasts of overall fuel efficiency improvement potential to estimate the future total petroleum and greenhouse gas (GHG) emissions relative to current levels. This is one of a series of reports produced as a result of the Transportation Energy Futures (TEF) project, a Department of Energy-sponsored multi-agency project initiated to pinpoint underexplored strategies for abating GHGs and reducing petroleum dependence related to transportation.

  1. Transportation Sector Model of the National Energy Modeling System. Volume 1

    SciTech Connect (OSTI)

    1998-01-01

    This report documents the objectives, analytical approach and development of the National Energy Modeling System (NEMS) Transportation Model (TRAN). The report catalogues and describes the model assumptions, computational methodology, parameter estimation techniques, model source code, and forecast results generated by the model. The NEMS Transportation Model comprises a series of semi-independent models which address different aspects of the transportation sector. The primary purpose of this model is to provide mid-term forecasts of transportation energy demand by fuel type including, but not limited to, motor gasoline, distillate, jet fuel, and alternative fuels (such as CNG) not commonly associated with transportation. The current NEMS forecast horizon extends to the year 2010 and uses 1990 as the base year. Forecasts are generated through the separate consideration of energy consumption within the various modes of transport, including: private and fleet light-duty vehicles; aircraft; marine, rail, and truck freight; and various modes with minor overall impacts, such as mass transit and recreational boating. This approach is useful in assessing the impacts of policy initiatives, legislative mandates which affect individual modes of travel, and technological developments. The model also provides forecasts of selected intermediate values which are generated in order to determine energy consumption. These elements include estimates of passenger travel demand by automobile, air, or mass transit; estimates of the efficiency with which that demand is met; projections of vehicle stocks and the penetration of new technologies; and estimates of the demand for freight transport which are linked to forecasts of industrial output. Following the estimation of energy demand, TRAN produces forecasts of vehicular emissions of the following pollutants by source: oxides of sulfur, oxides of nitrogen, total carbon, carbon dioxide, carbon monoxide, and volatile organic compounds.

  2. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    3 Commercial Delivered and Primary Energy Consumption Intensities, by Year Percent Delivered Energy Consumption Primary Energy Consumption Floorspace Post-2000 Total Consumption per Total Consumption per (million SF) Floorspace (1) (10^15 Btu) SF (thousand Btu/SF) (10^15 Btu) SF (thousand Btu/SF) 1980 50.9 N.A. 5.99 117.7 10.57 207.7 1990 64.3 N.A. 6.74 104.8 13.30 207.0 2000 (2) 68.5 N.A. 8.20 119.7 17.15 250.3 2010 81.1 26% 8.74 107.7 18.22 224.6 2015 84.1 34% 8.88 105.5 18.19 216.2 2020 89.1

  3. ImSET 3.1: Impact of Sector Energy Technologies Model Description and User's Guide

    SciTech Connect (OSTI)

    Scott, Michael J.; Livingston, Olga V.; Balducci, Patrick J.; Roop, Joseph M.; Schultz, Robert W.

    2009-05-22

    This 3.1 version of the Impact of Sector Energy Technologies (ImSET) model represents the next generation of the previously-built ImSET model (ImSET 2.0) that was developed in 2005 to estimate the macroeconomic impacts of energy-efficient technology in buildings. In particular, a special-purpose version of the Benchmark National Input-Output (I-O) model was designed specifically to estimate the national employment and income effects of the deployment of Office of Energy Efficiency and Renewable Energy (EERE)developed energy-saving technologies. In comparison with the previous versions of the model, this version features the use of the U.S. Bureau of Economic Analysis 2002 national input-output table and the central processing code has been moved from the FORTRAN legacy operating environment to a modern C++ code. ImSET is also easier to use than extant macroeconomic simulation models and incorporates information developed by each of the EERE offices as part of the requirements of the Government Performance and Results Act. While it does not include the ability to model certain dynamic features of markets for labor and other factors of production featured in the more complex models, for most purposes these excluded features are not critical. The analysis is credible as long as the assumption is made that relative prices in the economy would not be substantially affected by energy efficiency investments. In most cases, the expected scale of these investments is small enough that neither labor markets nor production cost relationships should seriously affect national prices as the investments are made. The exact timing of impacts on gross product, employment, and national wage income from energy efficiency investments is not well-enough understood that much special insight can be gained from the additional dynamic sophistication of a macroeconomic simulation model. Thus, we believe that this version of ImSET is a cost-effective solution to estimating the economic impacts of the development of energy-efficient technologies.

  4. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    4 Ownership (1) Owned 54.9 104.5 40.3 78% Rented 77.4 71.7 28.4 22% Public Housing 75.7 62.7 28.7 2% Not Public Housing 77.7 73.0 28.4 19% 100% Note(s): Source(s): 1) Energy consumption per square foot was calculated using estimates of average heated floor space per household. According to the 2005 Residential Energy Consumption Survey (RECS), the average heated floor space per household in the U.S. was 1,618 square feet. Average total floor space, which includes garages, attics and unfinished

  5. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    1 2003 Commercial Delivered Energy Consumption Intensities, by Ownership of Unit (1) Ownership Nongovernment Owned 85.1 72% Owner-Occupied 87.3 35% Nonowner-Occupied 88.4 36% Government Owned 105.3 28% 100% Note(s): Source(s): Consumption (thousand Btu/SF) 1) Mall buildings are no longer included in most CBECs tables; therefore, some data is not directly comparable to past CBECs. EIA, 2003 Commercial Buildings Energy Consumption and Expenditures: Consumption and Expenditures Tables, June 2006,

  6. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    8 Commercial Delivered Energy Consumption Intensities, by Vintage Consumption per Year Constructed Square Foot (thousand Btu/SF) Prior to 1960 84.4 23% 1960 to 1969 91.5 12% 1970 to 1979 97.0 18% 1980 to 1989 100.0 19% 1990 to 1999 90.3 19% 2000 to 2003 81.6 8% Average 91.0 Source(s): EIA, 2003 Commercial Buildings Energy Consumption and Expenditures: Consumption and Expenditures Tables, Oct. 2006, Table C1a

  7. Fact #561: March 9, 2009 All Sectors' Petroleum Gap | Department of Energy

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

    1: March 9, 2009 All Sectors' Petroleum Gap Fact #561: March 9, 2009 All Sectors' Petroleum Gap Before 1989 the U.S. produced enough petroleum to meet the needs of the transportation sector, but was still short of meeting the petroleum needs of all the sectors, including industrial, residential and commercial, and electric utilities. In 1973 the gap between what the U.S. produced and what was consumed was 5.6 million barrels per day. By 2030, the gap is expected to be at least 9.2 million

  8. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    1 Type (1) Single-Family: 55.4 106.6 39.4 80.5% Detached 55.0 108.4 39.8 73.9% Attached 60.5 89.3 36.1 6.6% Multi-Family: 78.3 64.1 29.7 14.9% 2 to 4 units 94.3 85.0 35.2 6.3% 5 or more units 69.8 54.4 26.7 8.6% Mobile Homes 74.6 70.4 28.5 4.6% All Housing Types 58.7 95.0 37.0 100% Note(s): Source(s): 1) Energy consumption per square foot was calculated using estimates of average heated floor space per household. According to the 2005 Residential Energy Consumption Survey (RECS), the average

  9. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    2 Year Built (1) Prior to 1950 74.5 114.9 46.8 24% 1950 to 1969 66.0 96.6 38.1 23% 1970 to 1979 59.4 83.4 33.5 15% 1980 to 1989 51.9 81.4 32.3 14% 1990 to 1999 48.2 94.4 33.7 16% 2000 to 2005 44.7 94.7 34.3 8% Average 58.7 95.0 40.0 Note(s): Source(s): 1) Energy consumption per square foot was calculated using estimates of average heated floor space per household. According to the 2005 Residential Energy Consumption Survey (RECS), the average heated floor space per household in the U.S. was

  10. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    9 Northeast Midwest South West National Space Heating 70.3 56.6 20.4 23.8 38.7 Space Cooling 3.6 5.6 13.9 4.0 7.9 Water Heating 21.1 20.4 15.8 21.2 19.0 Refrigerator 5.4 7.0 6.6 5.7 6.3 Other Appliances & Lighting 23.0 25.9 25.0 24.1 24.7 Total (1) 79.9 77.4 95.0 Note(s): Source(s): 2005 Delivered Energy End-Uses for an Average Household, by Region (Million Btu per Household) 122.2 113.5 1) Due to rounding, sums do not add up to totals. EIA, 2005 Residential Energy Consumption Survey, Oct.

  11. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    3 2003 Commercial Buildings Delivered Energy End-Use Intensities, by Building Activity (Thousand Btu per SF) (1) Space Heating Cooling Ventilation Water Heating Lighting Cooking Refrigeration Office Equipment Computers Other Total Space Heating Cooling Ventilation Water Heating Lighting Cooking Refrigeration Office Equipment Computers Other Total Space Heating Cooling Ventilation Water Heating Lighting Cooking Refrigeration Office Equipment Computers Other Total Note(s): Source(s): 43.5 45.2

  12. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    3 World Primary Energy Consumption and Population, by Country/Region 1990-2000 2000-2010 Region/Country 1990 2000 2010 1990 2000 2010 Energy Pop. Energy Pop. United States 85.0 99.8 97.8 18.7% 250 282 311 4.6% 1.6% 1.2% -0.2% 1.0% China 27.0 36.4 104.6 20.0% 1,148 1,264 1,343 20.0% 3.0% 1.0% 11.1% 0.6% OECD Europe 69.9 76.8 79.6 15.2% 402 522 550 8.2% 0.9% 2.6% 0.4% 0.5% Other Non-OECD Asia 12.5 20.6 31.3 6.0% 781 1,014 1,086 16.2% 5.1% 2.6% 4.2% 0.7% Russia (1) 61.0 27.2 29.9 5.7% 288 147 140

  13. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    1 Delivered Energy Consumption Intensities of Public Multi-Family Buildings, by Fuel and Region (Thousand Btu/SF) Region Electricity Natural Gas Fuel Oil Total Northeast 27.7 45.9 39.9 71.5 Midwest 22.5 49.9 N.A. 70.3 South 53.5 27.9 N.A. 65.9 West 22.0 25.3 N.A. 46.2 National Average 33.0 43.4 68.3

  14. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    2 Delivered Energy Consumption Intensities of Public Multi-Family Buildings, by Fuel and Region (Million Btu/Household) Region Electricity Natural Gas Fuel Oil Total Northeast 21.2 34.9 36.2 54.7 Midwest 16.6 36.6 N.A. 51.8 South 39.4 20.0 N.A. 48.5 West 16.6 19.3 N.A. 34.8 National Average 24.6 32.2 51.0

  15. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    0 2003 Commercial Primary Energy Consumption Intensities, by Principal Building Type Consumption Percent of Total | Consumption Percent of Total Building Type (thousand Btu/SF) Consumption | Building Type (thousand Btu/SF) Consumption Health Care 345.9 8% | Education 159.0 11% Inpatient 438.8 6% | Service 151.6 4% Outpatient 205.9 2% | Food Service 522.4 6% Food Sales 535.5 5% | Religious Worship 77.0 2% Lodging 193.1 7% | Public Order and Safety 221.1 2% Office 211.7 19% | Warehouse and Storage

  16. Energy investment advisory series No. 3: Investment opportunities in the Persian Gulf energy sector

    SciTech Connect (OSTI)

    Hadgen, R.E.

    1994-12-01

    Sometimes the greatest investment opportunities are in those areas where the least progress seems to be taking place. This report describes energy-based developments taking place in the Persian/Arabian Gulf. The 8 Gulf states are building their nations; each has large minority groups and swelling populations; their economies are built on one product (hydrocarbons). Large expatriate populations, being integrated into local societies and economies, have led to hostility and guarded access to contacts with the outside world. Gulf nations cannot benefit from any oil price rise as they did in the past, as their populations have grown too rapidly. Policies change daily and can be changed back to original ones as well as into new ones. Since the oil and gas industries are the primary source of government revenue, oil and gas are likely to remain longest under government control. A breakdown of energy-base investment potentials in the Middle East is tabulated: upstream oil, refining, domestic oil marketing, upstream gas, LNG, electricity, petrochemical.

  17. Natural Gas and the Transformation of the U.S. Energy Sector: Electricity

    Broader source: Energy.gov [DOE]

    Domestic natural gas production was largely stagnant from the mid-1970s until about 2005. However, beginning in the late 1990s, advances linking horizontal drilling techniques with hydraulic fracturing allowed drilling to proceed in shale and other formations at much lower cost. The result was a slow, steady increase in unconventional gas production. The Joint Institute for Strategic Energy Analysis (JISEA) designed this study to address four related key questions, which are a subset from the wider dialogue on natural gas; regarding the life cycle greenhouse gas (GHG) emissions associated with shale gas compared to conventional natural gas and other fuels used to generate electricity; existing legal and regulatory frameworks governing unconventional gas development at federal, state, and local levels, and changes in response to the rapid industry growth and public concerns; natural gas production companies changing their water-related practices; and demand for natural gas in the electric sector respond to a variety of policy and technology developments over the next 20 to 40 years.

  18. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    5 Load (quads) and Percent of Total Load Component Heating Cooling Roof -0.65 12% 0.16 14% Walls -1.00 19% 0.11 10% Foundation -0.76 15% -0.07 - Infiltration -1.47 28% 0.19 16% Windows (conduction) -1.34 26% 0.01 1% Windows (solar gain) 0.43 - 0.37 32% Internal Gains 0.79 - 0.31 27% Net Load -3.99 100% 1.08 100% Note(s): Source(s): Aggregate Residential Building Component Loads as of 1998 (1) 1) "Load" represents the thermal energy losses/gains that when combined will be offset by a

  19. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    2 Commercial Site Renewable Energy Consumption (Quadrillion Btu) (1) Growth Rate Wood (2) Solar Thermal (3) Solar PV (3) GHP Total 2010-Year 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 0.110 0.035 0.010 N.A. 0.155 0.4% 0.110 0.035 0.009 N.A. 0.154 0.4% 0.110 0.035 0.009 N.A. 0.153 0.4% 0.110

  20. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    9 2003 Commercial Delivered Energy Consumption Intensities, by Principal Building Type and Vintage (1) | Building Type Pre-1959 1960-1989 1990-2003 | Building Type Pre-1959 1960-1989 1990-2003 Health Care 178.1 216.0 135.7 | Education 77.7 88.3 80.6 Inpatient 230.3 255.3 253.8 | Service 62.4 86.0 74.8 Outpatient 91.6 110.4 84.4 | Food Service 145.2 290.1 361.2 Food Sales 205.8 197.6 198.3 | Religious Worship 46.6 39.9 43.3 Lodging 88.2 111.5 88.1 | Public Order & Safety N.A. 101.3 110.6

  1. Commercial Sector Demand Module

    Gasoline and Diesel Fuel Update (EIA)

    the State Energy Data System (SEDS) historical commercial sector consumption, applying an additive correction term to ensure that simulated model results correspond to published...

  2. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    U.S. Residential and Commercial Buildings Total Primary Energy Consumption (Quadrillion Btu and Percent of Total) Electricity Growth Rate Natural Gas Petroleum (1) Coal Renewable(2) Sales Losses Total TOTAL (2) 2010-Year 1980 7.42 28.2% 3.04 11.5% 0.15 0.6% 0.87 3.3% 4.35 10.47 14.82 56.4% 26.29 100% - 1981 7.11 27.5% 2.63 10.2% 0.17 0.6% 0.89 3.5% 4.50 10.54 15.03 58.2% 25.84 100% - 1982 7.32 27.8% 2.45 9.3% 0.19 0.7% 0.99 3.8% 4.57 10.80 15.37 58.4% 26.31 100% - 1983 6.93 26.4% 2.50 9.5% 0.19

  3. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    3 Buildings Share of U.S. Primary Energy Consumption (Percent) Total Consumption Total Industry Transportation Total (quads) 1980(1) 20.1% 13.5% | 33.7% 41.1% 25.2% 100% | 78.1 1981 20.0% 13.9% | 33.9% 40.4% 25.6% 100% | 76.1 1982 21.2% 14.8% | 36.0% 37.9% 26.1% 100% | 73.1 1983 21.1% 15.0% | 36.1% 37.7% 26.3% 100% | 72.9 1984 20.8% 14.9% | 35.7% 38.7% 25.7% 100% | 76.6 1985 21.0% 15.0% | 35.9% 37.8% 26.3% 100% | 76.5 1986 20.8% 15.1% | 35.9% 37.0% 27.1% 100% | 76.6 1987 20.5% 15.1% | 35.6%

  4. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    Commercial Primary Energy Consumption, by Year and Fuel Type (Quadrillion Btu and Percent of Total) Electricity Growth Rate Natural Gas Petroleum (1) Coal Renewable(2) Sales Losses Total Total(3) 2010-Year 1980 2.63 24.9% 1.31 12.4% 0.12 1.1% 0.02 0.2% 1.91 4.58 6.49 61.4% 1981 2.54 23.9% 1.12 10.5% 0.14 1.3% 0.02 0.2% 2.03 4.76 6.80 64.1% 1982 2.64 24.3% 1.03 9.5% 0.16 1.4% 0.02 0.2% 2.08 4.91 6.99 64.5% 1983 2.48 22.7% 1.16 10.7% 0.16 1.5% 0.02 0.2% 2.12 4.98 7.09 65.0% 1984 2.57 22.5% 1.22

  5. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    4 2010 Commercial Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Lighting 1.19 1.19 13.6% | 3.69 3.69 20.2% Space Heating 1.65 0.22 0.06 0.11 0.28 2.33 26.6% | 0.88 2.93 16.0% Space Cooling 0.04 0.84 0.88 10.1% | 2.60 2.64 14.5% Ventilation 0.54 0.54 6.1% | 1.66 1.66 9.1% Refrigeration 0.39 0.39 4.5% | 1.21 1.21 6.6% Water Heating 0.44 0.03 0.03 0.09 0.58

  6. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    2 U.S. Buildings Site Renewable Energy Consumption (Quadrillion Btu) (1) Growth Rate Wood (2) Solar Thermal (3) Solar PV (3) GSHP (4) Total 2010-Year 1980 0.867 0.000 N.A. 0.000 0.867 - 1981 0.894 0.000 N.A. 0.000 0.894 - 1982 0.993 0.000 N.A. 0.000 0.993 - 1983 0.992 0.000 N.A. 0.000 0.992 - 1984 1.002 0.000 N.A. 0.000 1.002 - 1985 1.034 0.000 N.A. 0.000 1.034 - 1986 0.947 0.000 N.A. 0.000 0.947 - 1987 0.882 0.000 N.A. 0.000 0.882 - 1988 0.942 0.000 N.A. 0.000 0.942 - 1989 1.018 0.052 N.A.

  7. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    4 2010 U.S. Buildings Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Fuel Other Renw. Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Space Heating (5) 5.14 0.76 0.30 0.10 0.54 0.72 7.56 37.0% | 2.24 9.07 22.5% Space Cooling 0.04 1.92 1.96 9.6% | 5.94 5.98 14.8% Lighting 1.88 1.88 9.2% | 5.82 5.82 14.4% Water Heating 1.73 0.13 0.07 0.04 0.54 2.51 12.3% | 1.67 3.63 9.0% Refrigeration (6) 0.84 0.84 4.1% | 2.62 2.62 6.5% Electronics (7)

  8. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    5 2015 U.S. Buildings Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Space Heating (5) 5.10 0.68 0.26 0.09 0.55 0.59 7.27 35.9% | 1.77 8.45 21.5% Lighting 1.52 1.52 7.5% | 4.65 4.65 11.8% Space Cooling 0.04 0.54 0.57 2.8% | 4.60 4.63 11.8% Water Heating 1.79 0.10 0.05 0.05 0.57 2.55 12.6% | 1.71 3.70 9.4% Refrigeration (6) 0.81 0.81 4.0% | 2.43 2.43 6.2%

  9. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    6 2025 U.S. Buildings Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Space Heating (5) 4.96 0.57 0.24 0.09 0.57 0.63 7.05 33.2% | 1.89 8.31 19.6% Space Cooling 0.03 1.64 1.67 7.9% | 4.94 4.97 11.7% Lighting 1.55 1.55 7.3% | 4.68 4.68 11.0% Water Heating 1.84 0.08 0.04 0.05 0.62 2.63 12.4% | 1.86 3.88 9.1% Refrigeration (6) 0.82 0.82 3.9% | 2.47 2.47 5.8%

  10. Buildings Energy Data Book: 1.1 Buildings Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    7 2035 U.S. Buildings Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Space Heating (5) 4.84 0.49 0.22 0.09 0.57 0.66 6.87 30.5% | 1.93 8.15 17.9% Space Cooling 0.03 1.79 1.82 8.1% | 5.27 5.30 11.7% Lighting 1.63 1.63 7.3% | 4.81 4.81 10.6% Water Heating 1.81 0.07 0.03 0.06 0.63 2.60 11.6% | 1.86 3.83 8.4% Electronics (6) 0.90 0.90 4.0% | 2.66 2.66 5.8%

  11. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    0 Region (1) Northeast 73.5 122.2 47.7 24% New England 77.0 129.4 55.3 7% Middle Atlantic 72.2 119.7 45.3 17% Midwest 58.9 113.5 46.0 28% East North Central 61.1 117.7 47.3 20% West North Central 54.0 104.1 42.9 8% South 51.5 79.8 31.6 31% South Atlantic 47.4 76.1 30.4 16% East South Central 56.6 87.3 36.1 6% West South Central 56.6 82.4 31.4 9% West 56.6 77.4 28.1 18% Mountain 54.4 89.8 33.7 6% Pacific 58.0 71.8 25.7 11% U.S. Average 58.7 94.9 37.0 100% Note(s): Source(s): 1) Energy consumption

  12. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    3 Building Type Pre-1995 1995-2005 Pre-1995 1995-2005 Pre-1995 1995-2005 Single-Family 38.4 44.9 102.7 106.2 38.5 35.5 Detached 37.9 44.7 104.5 107.8 38.8 35.4 Attached 43.8 55.5 86.9 85.1 34.2 37.6 Multi-Family 63.8 58.7 58.3 49.2 27.2 24.3 2 to 4 units 69.0 55.1 70.7 59.4 29.5 25.0 5 or more units 61.5 59.6 53.6 47.2 26.3 24.2 Mobile Homes 82.4 57.1 69.6 74.5 29.7 25.2 Note(s): Source(s): 2005 Residential Delivered Energy Consumption Intensities, by Principal Building Type and Vintage Per

  13. Buildings Energy Data Book: 2.1 Residential Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    4 Primary Energy Consumption Total Per Household 1980 79.6 N.A. 123.5 15.72 197.4 1981 82.8 N.A. 114.2 15.23 184.0 1982 83.7 N.A. 114.6 15.48 184.9 1983 84.6 N.A. 110.6 15.38 181.9 1984 86.3 N.A. 113.9 15.90 184.2 1985 87.9 N.A. 111.7 16.02 182.3 1986 89.1 N.A. 108.4 15.94 178.8 1987 90.5 N.A. 108.2 16.21 179.1 1988 92.0 N.A. 112.7 17.12 186.0 1989 93.5 N.A. 113.7 17.76 190.0 1990 94.2 N.A. 102.7 16.92 179.5 1991 95.3 N.A. 104.6 17.38 182.4 1992 96.4 N.A. 104.7 17.31 179.6 1993 97.7 N.A. 107.5

  14. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    5 2015 Commercial Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Lighting 1.01 1.01 11.4% | 3.05 3.05 16.7% Space Heating 1.69 0.20 0.06 0.11 0.17 2.23 25.2% | 0.50 2.57 14.1% Space Cooling 0.04 0.51 0.54 6.1% | 1.52 1.56 8.6% Ventilation 0.54 0.54 6.1% | 1.62 1.62 8.9% Refrigeration 0.35 0.35 4.0% | 1.06 1.06 5.8% Electronics 0.32 0.32 3.6% | 0.95 0.95 5.2%

  15. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    6 2025 Commercial Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Lighting 1.08 1.08 11.3% | 3.27 3.27 16.3% Space Heating 1.68 0.18 0.06 0.11 0.16 2.20 23.1% | 0.49 2.53 12.6% Ventilation 0.60 0.60 6.2% | 1.80 1.80 9.0% Space Cooling 0.03 0.52 0.55 5.7% | 1.56 1.59 7.9% Electronics 0.40 0.40 4.2% | 1.22 1.22 6.1% Refrigeration 0.34 0.34 3.6% | 1.02 1.02 5.1%

  16. Buildings Energy Data Book: 3.1 Commercial Sector Energy Consumption

    Buildings Energy Data Book [EERE]

    7 2035 Commercial Energy End-Use Splits, by Fuel Type (Quadrillion Btu) Natural Fuel Other Renw. Site Site Primary Primary Gas Oil (1) LPG Fuel(2) En.(3) Electric Total Percent Electric (4) Total Percent Lighting 1.15 1.15 11.1% | 3.40 3.40 15.6% Space Heating 1.65 0.18 0.06 0.11 0.16 2.16 20.8% | 0.48 2.48 11.3% Ventilation 0.65 0.65 6.2% | 1.91 1.91 8.7% Space Cooling 0.03 0.54 0.57 5.5% | 1.59 1.62 7.4% Electronics 0.46 0.46 4.5% | 1.37 1.37 6.3% Refrigeration 0.36 0.36 3.4% | 1.05 1.05 4.8%

  17. Buildings Energy Data Book: 8.1 Buildings Sector Water Consumption

    Buildings Energy Data Book [EERE]

    1 Total Use of Water by Buildings (Million Gallons per Day) (1) Year 1985 1990 1995 2000 (2) 2005 (3) Note(s): Source(s): 1) Includes water from the public supply and self-supplied sources (e.g., wells) for residential and commercial sectors. 2) USGS did not estimate water use in the commercial and residential sectors for 2000. Estimates are based on available data and 1995 splits between domestic and commercial use. 3) USGS did not estimate commercial sector use for 2005. Estimated based on

  18. Models for residential- and commercial-sector energy-conservation analysis: applications, limitations, and future potential. Final report

    SciTech Connect (OSTI)

    Cole, Henry E.; Fullen, Robert E.

    1980-09-01

    This report reviews four of the major models used by the Department of Energy (DOE) for energy conservation analyses in the residential- and commercial-building sectors. The objective is to provide a critical analysis of how these models can serve as tools for DOE and its Conservation Policy Office in evaluating and quantifying their policy and program requirements. For this, the study brings together information on the models' analytical structure and their strengths and limitations in policy applications these are then employed to assess the most-effective role for each model in addressing future issues of buildings energy-conservation policy and analysis. The four models covered are: Oak Ridge Residential Energy Model; Micro Analysis of Transfers to Households/Comprehensive Human Resources Data System (MATH/CHRDS) Model; Oak Ridge Commercial Energy Model; and Brookhaven Buildings Energy Conservation Optimization Model (BECOM).

  19. The Rise and Decline of U.S. Private Sector Investments in Energy R&D since the Arab Oil Embargo of 1973

    SciTech Connect (OSTI)

    Dooley, James J.

    2010-11-01

    This paper presents two distinct datasets that describe investments in energy research and development (R&D) by the US private sector since the mid1970s, which is when the US government began to systematically collect these data. The first dataset is based upon a broad survey of more than 20,000 firms industrial R&D activities. This broad survey of US industry is coordinated by the US National Science Foundation. The second dataset discussed here is a much narrower accounting of the energy R&D activities of the approximately two dozen largest US oil and gas companies conducted by the US Department of Energys Energy Information Agency. Even given the large disparity in the breadth and scope of these two surveys of the private sectors support for energy R&D, both datasets tell the same story in terms of the broad outlines of the private sectors investments in energy R&D since the mid 1970s. The broad outlines of the US private sectors support for energy R&D since the mid 1970s is: (1) In the immediate aftermath of the Arab Oil Embargo of 1973, there is a large surge in US private sector investments in energy R&D that peaked in the period between 1980 and 1982 at approximately $3.7 billion to $6.7 billion per year (in inflation adjusted 2010 US dollars) depending upon which survey is used (2) Private sector investments in energy R&D declined from this peak until bottoming out at approximately $1.8 billion to $1 billion per year in 1999; (3) US private sector support for energy R&D has recovered somewhat over the past decade and stands at $2.2 billion to $3.4 billion. Both data sets indicate that the US private sectors support for energy R&D has been and remains dominated by fossil energy R&D and in particular R&D related to the needs of the oil and gas industry.

  20. "Modeling the Integrated Expansion of the Canadian and U.S. Power Sectors with the Regional Energy Deployment System" Study Now Available

    Broader source: Energy.gov [DOE]

    The National Renewable Energy Laboratory (NREL) has released a study entitled "Modeling the Integrated Expansion of the Canadian and U.S. Power Sectors with the Regional Energy Deployment System (ReEDS)”. Funded by OE, this study documents a development effort that created a robust representation of the combined capacity expansion of the U.S. and Canadian electric sectors in the NREL Regional Energy Deployment System model.

  1. Changes in energy intensity in the manufacturing sector 1985--1991

    SciTech Connect (OSTI)

    1995-09-15

    In this report, energy intensity is defined as the ratio of energy consumption per unit of output. Output is measured as the constant dollar of value of shipments and receipts, and two measures of energy consumption are presented in British thermal units (Btu): Offsite-Produced Energy and Total Inputs of Energy. A decrease in energy intensity from one period to another suggests an increase in energy efficiency, and vice versa. Energy efficiency can be defined and measured in various ways. Certain concepts of energy efficiency, especially those limited to equipment efficiencies, cannot be measured over time using changes in energy-intensity ratios. While improved energy efficiency will tend to reduce energy intensity, it is also true that a change in energy intensity can be due to factors unrelated to energy efficiency. For this report, energy intensity is used as a surrogate measure for energy efficiency, based on industry knowledge and current methodological analyses.

  2. Energy Sector Security Appliances in a System for Intelligent Learning Network Configuration Management and Monitoring (Essence)

    Office of Environmental Management (EM)

    Sector Security Appliances in a System for Intelligent Learning Network Configuration Management and Monitoring (Essence) Software defined network to assist small electric cooperatives with limited resources for securing utility operational networks Background Utilities of all sizes are faced with the challenge of configuring, managing, monitoring, and securing their information technology and operational technology (IT and OT) networks; but the challenge is more acute for small utilities and

  3. Assessing National Employment Impacts of Investment in Residential and Commercial Sector Energy Efficiency: Review and Example Analysis

    SciTech Connect (OSTI)

    Anderson, David M.; Belzer, David B.; Livingston, Olga V.; Scott, Michael J.

    2014-06-18

    Pacific Northwest National Laboratory (PNNL) modeled the employment impacts of a major national initiative to accelerate energy efficiency trends at one of two levels: • 15 percent savings by 2030. In this scenario, efficiency activities save about 15 percent of the Annual Energy Outlook (AEO) Reference Case electricity consumption by 2030. It is assumed that additional energy savings in both the residential and commercial sectors begin in 2015 at zero, and then increase in an S-shaped market penetration curve, with the level of savings equal to about 7.0 percent of the AEO 2014 U.S. national residential and commercial electricity consumption saved by 2020, 14.8 percent by 2025, and 15 percent by 2030. • 10 percent savings by 2030. In this scenario, additional savings begin at zero in 2015, increase to 3.8 percent in 2020, 9.8 percent by 2025, and 10 percent of the AEO reference case value by 2030. The analysis of the 15 percent case indicates that by 2030 more than 300,000 new jobs would likely result from such policies, including an annual average of more than 60,000 jobs directly supporting the installation and maintenance of energy efficiency measures and practices. These are new jobs resulting initially from the investment associated with the construction of more energy-efficient new buildings or the retrofit of existing buildings and would be sustained for as long as the investment continues. Based on what is known about the current level of building-sector energy efficiency jobs, this would represent an increase of more than 10 percent from the current estimated level of over 450,000 such jobs. The more significant and longer-lasting effect comes from the redirection of energy bill savings toward the purchase of other goods and services in the general economy, with its attendant influence on increasing the total number of jobs. This example analysis utilized PNNL’s ImSET model, a modeling framework that PNNL has used over the past two decades to assess the economic impacts of the U.S. Department of Energy’s (DOE’s) energy efficiency programs in the buildings sector.

  4. Industrial Utility Webinar: Opportunities for Cost-Effective Energy Efficiency in the Industrial Sector

    SciTech Connect (OSTI)

    2010-01-13

    The Industrial Utility Webinars focus on providing utilities with information on how to develop sucessful energy efficeincy programs for industrial energy consumers.

  5. Industrial Energy Efficiency: Designing Effective State Programs for the Industrial Sector

    SciTech Connect (OSTI)

    Amelie Goldberg; Taylor, Robert P.; Hedman, Bruce

    2014-03-21

    This report provides state regulators, utilities, and other program administrators with an overview of U.S. industrial energy efficiency programs and assesses some of the key features of programs that have generated increased energy savings.

  6. Energy use in Poland, 1970--1991: Sectoral analysis and international comparison

    SciTech Connect (OSTI)

    Meyers, S.; Schipper, L.; Salay, J.

    1993-07-01

    This report provides an analysis of how and why energy use has changed in Poland since the 1970s, with particular emphasis on changes since the country began its transition from a centrally planned to a market economy in 1989. The most important factors behind the large decline in Polish energy use in 1990 were a sharp fall in industrial output and a huge drop in residential coal use driven by higher prices. The structural shift away from heavy industry was slight. Key factors that worked to increase energy use were the rise in energy intensity in many heavy industries and the shift toward more energy intensive modes of transport. The growth in private activities in 1991 was nearly sufficient to balance out continued decline in industrial energy use in that year. We compared energy use in Poland and the factors that shape it with similar elements in the West. We made a number of modifications to the Polish energy data to bring it closer to a Western energy accounting framework, and augmented these with a variety of estimates in order to construct a sufficiently detailed portrait of Polish energy use to allow comparison with Western data. Per capita energy use in Poland was not much below W. European levels despite Poland`s much lower GDP per capita. Poland has comparatively high energy intensities in manufacturing and residential space heating, and a large share of heavy industries in manufacturing output, all factors that contribute to higher energy use per capita. The structure of passenger and freight transportation and the energy intensity of automobiles contribute to lower energy use per capita in Poland than in Western Europe, but the patterns in Poland are moving closer to those that prevail in the West.

  7. Sector 9

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Sector 9 About Science and Research Beamlines Operations and Schedule Safety Search APS ... Search Argonne Home > Advanced Photon Source > Contacts Advisory Committee Beamlines...

  8. Examination of the factors and issues for an environmental technology utilization partnership between the private sector and the Department of Energy. Final report

    SciTech Connect (OSTI)

    Brouse, P.

    1997-05-01

    The Department of Energy (DOE) held a meeting on November 12, 1992 to evaluate the DOE relations with industry and university partners concerning environmental technology utilization. The goal of this meeting was to receive feedback from DOE industry and university partners for the identification of opportunities to improve the DOE cooperative work processes with the private sector. The meeting was designed to collect information and to turn that information into action to improve private sector partnerships with DOE.

  9. Analysis of energy use in building services of the industrial sector in California: A literature review and a preliminary characterization

    SciTech Connect (OSTI)

    Akbari, H.; Borgers, T.; Gadgil, A.; Sezgen, O.

    1991-04-01

    Energy use patterns in many of California's fastest-growing industries are not typical of those in the mix of industries elsewhere in the US. Many California firms operate small and medium-sized facilities, often in buildings used simultaneously or interchangeably for commercial (office, retail, warehouse) and industrial activities. In these industrial subsectors, the energy required for building services'' to provide occupant comfort and necessities (lighting, HVAC, office equipment, computers, etc.) may be at least as important as the more familiar process energy requirements -- especially for electricity and on-peak demand. In this report, published or unpublished information on energy use for building services in the industrial sector have been compiled and analyzed. Seven different sources of information and data relevant to California have been identified. Most of these are studies and/or projects sponsored by the Department of Energy, the California Energy Commission, and local utilities. The objectives of these studies were diverse: most focused on industrial energy use in general, and, in one case, the objective was to analyze energy use in commercial buildings. Only one of these studies focused directly on non-process energy use in industrial buildings. Our analysis of Northern California data for five selected industries shows that the contribution of total electricity consumption for lighting ranges from 9.5% in frozen fruits to 29.1% in instruments; for air-conditioning, it ranges from nonexistent in frozen fruits to 35% in instrument manufacturing. None of the five industries selected had significant electrical space heating. Gas space heating ranges from 5% in motor vehicles facilities to more than 58% in the instrument manufacturing industry. 15 refs., 15 figs., 9 tabs.

  10. Manufacturing Energy and Carbon Footprint - Sector: Alumina and Aluminum (NAICS 3313), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    5 Nonprocess Losses 603 134 Steam Distribution Losses 3 7 Nonprocess Energy 118 Electricity Generation Steam Generation 603 3 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 16 250 152 Generation and Transmission Losses Generation and Transmission Losses 1 329 Onsite Generation 265 255 18 273 481 4 13 0.3 29.0 29.3 1.0 1.0 5.0 33.0 1.6 36 6.3 35.6 0.3 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data source:

  11. Manufacturing Energy and Carbon Footprint - Sector: Cement (NAICS 327310), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    0 Nonprocess Losses 471 154 Steam Distribution Losses 4 5 Nonprocess Energy 341 Electricity Generation Steam Generation 471 0 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 14 353 41 Generation and Transmission Losses Generation and Transmission Losses 0 89 Onsite Generation 367 345 37 382 130 0 26 0.0 7.8 7.8 3.4 3.4 27.2 34.1 1.1 39 30.8 38.6 0.1 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data source: 2006

  12. Manufacturing Energy and Carbon Footprint - Sector: Fabricated Metals (NAICS 332), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    9 Nonprocess Losses 708 127 Steam Distribution Losses 8 38 Nonprocess Energy 248 Electricity Generation Steam Generation 708 6 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 88 293 143 Generation and Transmission Losses Generation and Transmission Losses 2 309 Onsite Generation 381 356 41 397 452 8 33 0.5 27.3 27.8 2.4 2.2 8.8 30.3 8.4 41 13.3 41.1 2.3 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data source:

  13. Manufacturing Energy and Carbon Footprint - Sector: Foundries (NAICS 3315), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    281 65 Steam Distribution Losses 1 11 Nonprocess Energy 101 Electricity Generation Steam Generation 281 0 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 26 130 57 Generation and Transmission Losses Generation and Transmission Losses 0 123 Onsite Generation 157 154 4 158 180 0 3 0.0 10.9 10.9 0.2 0.2 4.1 13.3 2.6 16 5.2 16.1 0.9 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data source: 2006 MECS (with

  14. Manufacturing Energy and Carbon Footprint - Sector: Machinery (NAICS 333), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    6 Nonprocess Losses 444 51 Steam Distribution Losses 4 39 Nonprocess Energy 92 Electricity Generation Steam Generation 444 1 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 91 103 111 Generation and Transmission Losses Generation and Transmission Losses 0 240 Onsite Generation 194 178 26 204 351 1 20 0.1 21.2 21.3 1.6 1.4 1.6 13.8 10.9 26 5.1 26.3 2.1 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data source:

  15. Manufacturing Energy and Carbon Footprint - Sector: Textiles (NAICS 313-316), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    21 Nonprocess Losses 472 107 Steam Distribution Losses 17 23 Nonprocess Energy 162 Electricity Generation Steam Generation 472 9 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 52 175 94 Generation and Transmission Losses Generation and Transmission Losses 3 203 Onsite Generation 227 167 98 265 297 12 77 0.8 18.0 18.7 6.7 6.5 2.9 16.8 5.2 29 10.0 28.7 0.7 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data

  16. Manufacturing Energy and Carbon Footprint - Sector: Transportation Equipment (NAICS 336), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    4 Nonprocess Losses 904 106 Steam Distribution Losses 11 82 Nonprocess Energy 278 Electricity Generation Steam Generation 904 7 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 196 258 195 Generation and Transmission Losses Generation and Transmission Losses 3 422 Onsite Generation 455 415 65 480 617 9 51 0.6 37.2 37.8 4.2 3.8 6.4 29.4 19.6 53 15.3 53.2 5.2 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e Energy use data

  17. TAP Webinar: Best Practices in Energy Data Collection and Tracking in the Public Sector

    Broader source: Energy.gov [DOE]

    Implementing a robust and comprehensive energy tracking and measurement process can be a challenge. This webinar will cover DOE's Weatherization and Intergovernmental Program Office's step-by-step...

  18. Department of Energy to Host Spectrum Policy Seminar for the Utility Sector on December 8, 2010

    Broader source: Energy.gov [DOE]

    On October 5, 2010, after an extensive public notice and comment process, the Department of Energy (DOE) issued a report entitled, "Communications Requirements of Smart Grid Technologies". The...

  19. Detection and Analysis of Threatsto the Energy Sector (DATES), March 2010

    Broader source: Energy.gov [DOE]

    A security monitoring capability featuring multiple detection algorithms and cross-domain event correlation for defense against cyber attacks on energy control systems.

  20. Manufacturing Energy and Carbon Footprint - Sector: Cement (NAICS 327310), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Cement (NAICS 327310) Process Energy Electricity and Steam Generation Losses Process Losses 1 Nonprocess Losses 307 101 Steam Distribution Losses 1 3 Nonprocess Energy 214 Electricity Generation Steam Generation 307 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 6 237 31 Generation and Transmission Losses Generation and Transmission Losses 0 62 243 240 5 245 93 0 4 0.0 5.4 5.4 18.5 23.5 0.6 25 19.1 24.6 0.2 Fuel Total Primary Energy, 2010

  1. Manufacturing Energy and Carbon Footprint - Sector: Foundries (NAICS 3315), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Foundries (NAICS 3315) Process Energy Electricity and Steam Generation Losses Process Losses 1 Nonprocess Losses 173 34 Steam Distribution Losses 0 8 Nonprocess Energy 59 Electricity Generation Steam Generation 173 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 19 77 38 Generation and Transmission Losses Generation and Transmission Losses 0 76 96 95 2 97 114 0 2 0.0 6.6 6.6 1.8 7.2 1.9 9 2.6 9.2 0.6 Fuel Total Primary Energy, 2010 Total

  2. Manufacturing Energy and Carbon Footprint - Sector: Machinery (NAICS 333), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Machinery (NAICS 333) Process Energy Electricity and Steam Generation Losses Process Losses 1 Nonprocess Losses 288 37 Steam Distribution Losses 1 27 Nonprocess Energy 77 Electricity Generation Steam Generation 288 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 67 78 70 Generation and Transmission Losses Generation and Transmission Losses 0 141 144 139 8 147 211 1 7 0.0 12.2 12.3 1.8 8.9 6.9 16 4.2 16.4 2.0 Fuel Total Primary Energy, 2010

  3. Manufacturing Energy and Carbon Footprint - Sector: Textiles (NAICS 313-316), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Textiles (NAICS 313-316) Process Energy Electricity and Steam Generation Losses Process Losses 6 Nonprocess Losses 242 47 Steam Distribution Losses 6 12 Nonprocess Energy 59 Electricity Generation Steam Generation 242 6 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 26 84 58 Generation and Transmission Losses Generation and Transmission Losses 2 117 111 91 32 123 175 8 27 0.5 10.1 10.7 1.4 9.1 3.1 14 3.7 14.3 0.3 Fuel Total Primary Energy,

  4. The Boom of Electricity Demand in the Residential Sector in the Developing World and the Potential for Energy Efficiency

    SciTech Connect (OSTI)

    Letschert, Virginie; McNeil, Michael A.

    2008-05-13

    With the emergence of China as the world's largest energy consumer, the awareness of developing country energy consumption has risen. According to common economic scenarios, the rest of the developing world will probably see an economic expansion as well. With this growth will surely come continued rapid growth in energy demand. This paper explores the dynamics of that demand growth for electricity in the residential sector and the realistic potential for coping with it through efficiency. In 2000, only 66% of developing world households had access to electricity. Appliance ownership rates remain low, but with better access to electricity and a higher income one can expect that households will see their electricity consumption rise significantly. This paper forecasts developing country appliance growth using econometric modeling. Products considered explicitly - refrigerators, air conditioners, lighting, washing machines, fans, televisions, stand-by power, water heating and space heating - represent the bulk of household electricity consumption in developing countries. The resulting diffusion model determines the trend and dynamics of demand growth at a level of detail not accessible by models of a more aggregate nature. In addition, the paper presents scenarios for reducing residential consumption through cost-effective and/or best practice efficiency measures defined at the product level. The research takes advantage of an analytical framework developed by LBNL (BUENAS) which integrates end use technology parameters into demand forecasting and stock accounting to produce detailed efficiency scenarios, which allows for a realistic assessment of efficiency opportunities at the national or regional level. The past decades have seen some of the developing world moving towards a standard of living previously reserved for industrialized countries. Rapid economic development, combined with large populations has led to first China and now India to emerging as 'energy giants', a phenomenon that is expected to continue, accelerate and spread to other countries. This paper explores the potential for slowing energy consumption and greenhouse gas emissions in the residential sector in developing countries and evaluates the potential of energy savings and emissions mitigation through market transformation programs such as, but not limited to Energy Efficiency Standards and Labeling (EES&L). The bottom-up methodology used allows one to identify which end uses and regions have the greatest potential for savings.

  5. Manufacturing Energy and Carbon Footprint - Sector: Food and Beverage (NAICS 311, 312), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    34 Nonprocess Losses 1,934 524 Steam Distribution Losses 111 63 Nonprocess Energy 928 Electricity Generation Steam Generation 1,934 86 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 166 884 281 Generation and Transmission Losses Generation and Transmission Losses 32 607 Onsite Generation 1,051 677 618 1,295 888 118 485 7.5 53.7 61.1 39.7 38.5 14.7 63.2 14.3 117 56.1 117.2 2.9 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT CO 2 e

  6. Manufacturing Energy and Carbon Footprint - Sector: Glass (NAICS 3272, 327993), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    (NAICS 3272, 327993) Process Energy Electricity and Steam Generation Losses Process Losses 5 Nonprocess Losses 466 162 Steam Distribution Losses 4 12 Nonprocess Energy 267 Electricity Generation Steam Generation 466 0 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 30 292 63 Generation and Transmission Losses Generation and Transmission Losses 0 136 Onsite Generation 321 306 24 330 199 0 19 0.0 12.0 12.0 1.5 1.5 12.1 22.8 2.0 26 14.3 26.3 0.6 Fuel Total Energy

  7. Manufacturing Energy and Carbon Footprint - Sector: Iron and Steel (NAICS 3311, 3312), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    3312) Process Energy Electricity and Steam Generation Losses Process Losses 57 Nonprocess Losses 1,481 431 Steam Distribution Losses 30 33 Nonprocess Energy 831 Electricity Generation Steam Generation 1,481 11 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 82 874 201 Generation and Transmission Losses Generation and Transmission Losses 4 435 Onsite Generation 956 836 206 1,043 636 15 150 1.0 38.4 39.4 2.8 2.8 18.9 55.2 4.2 62 22.9 62.2 1.2 Fuel Total Energy Total

  8. Manufacturing Energy and Carbon Footprint - Sector: Petroleum Refining (NAICS 324110), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    45 Nonprocess Losses 3,546 641 Steam Distribution Losses 145 20 Nonprocess Energy 2,994 Electricity Generation Steam Generation 3,546 110 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 62 2,779 127 Generation and Transmission Losses Generation and Transmission Losses 41 275 Onsite Generation 2,840 2,304 927 3,231 402 151 682 9.6 24.3 33.8 64.7 64.3 144.5 176.0 3.0 244 209.8 243.6 1.1 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu MMT

  9. Manufacturing Energy and Carbon Footprint - Sector: Plastics (NAICS 326), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    (NAICS 326) Process Energy Electricity and Steam Generation Losses Process Losses 16 Nonprocess Losses 729 89 Steam Distribution Losses 13 36 Nonprocess Energy 154 Electricity Generation Steam Generation 729 0 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 84 223 182 Generation and Transmission Losses Generation and Transmission Losses 0 393 Onsite Generation 307 255 81 336 575 0 65 0.0 34.8 34.8 5.1 4.9 2.3 28.9 9.7 44 8.9 43.7 1.7 Fuel Total Energy Total

  10. Manufacturing Energy and Carbon Footprint - Sector: Alumina and Aluminum (NAICS 3313), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Alumina and Aluminum (NAICS 3313) Process Energy Electricity and Steam Generation Losses Process Losses 3 Nonprocess Losses 456 105 Steam Distribution Losses 3 7 Nonprocess Energy 99 Electricity Generation Steam Generation 456 5 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 16 198 116 Generation and Transmission Losses Generation and Transmission Losses 2 234 214 207 13 220 351 7 10 0.4 20.3 20.8 4.2 24.0 1.3 26 5.3 26.1 0.4 Fuel Total

  11. Manufacturing Energy and Carbon Footprint - Sector: Chemicals (NAICS 325), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Chemicals (NAICS 325) Process Energy Electricity and Steam Generation Losses Process Losses 381 Nonprocess Losses 4,252 871 Steam Distribution Losses 247 86 Nonprocess Energy 2,447 Electricity Generation Steam Generation 4,252 324 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 229 2,364 450 Generation and Transmission Losses Generation and Transmission Losses 126 905 2,594 1,745 1,476 3,221 1,355 450 1,095 28.5 78.6 107.2 52.4 145.9 15.4 252

  12. Manufacturing Energy and Carbon Footprint - Sector: Fabricated Metals (NAICS 332), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Fabricated Metals (NAICS 332) Process Energy Electricity and Steam Generation Losses Process Losses 6 Nonprocess Losses 557 90 Steam Distribution Losses 4 35 Nonprocess Energy 174 Electricity Generation Steam Generation 557 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 80 211 127 Generation and Transmission Losses Generation and Transmission Losses 0 255 291 275 26 301 382 1 20 0.0 22.2 22.2 5.6 22.4 7.7 32 9.3 31.5 2.3 Fuel Total Primary

  13. Manufacturing Energy and Carbon Footprint - Sector: Food and Beverage (NAICS 311, 312), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Food and Beverage (NAICS 311, 312) Process Energy Electricity and Steam Generation Losses Process Losses 128 Nonprocess Losses 1,836 455 Steam Distribution Losses 104 72 Nonprocess Energy 919 Electricity Generation Steam Generation 1,836 41 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 178 835 285 Generation and Transmission Losses Generation and Transmission Losses 16 574 1,014 620 625 1,245 860 57 497 3.6 50.0 53.6 13.5 55.8 13.7 109 55.5

  14. Manufacturing Energy and Carbon Footprint - Sector: Forest Products (NAICS 321, 322), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Forest Products (NAICS 321, 322) Process Energy Electricity and Steam Generation Losses Process Losses 530 Nonprocess Losses 3,152 1,016 Steam Distribution Losses 287 87 Nonprocess Energy 2,135 Electricity Generation Steam Generation 3,152 186 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 224 1,538 252 Generation and Transmission Losses Generation and Transmission Losses 72 507 1,762 656 1,917 2,573 759 258 1,393 16.4 45.1 61.5 10.6 64.2 9.2

  15. Manufacturing Energy and Carbon Footprint - Sector: Glass (NAICS 3272, 327993), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Glass and Glass Products (NAICS 3272, 327993) Process Energy Electricity and Steam Generation Losses Process Losses 1 Nonprocess Losses 294 100 Steam Distribution Losses 0 7 Nonprocess Energy 149 Electricity Generation Steam Generation 294 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 16 180 48 Generation and Transmission Losses Generation and Transmission Losses 0 97 196 195 2 197 145 0 1 0.0 8.4 8.4 7.3 14.3 1.7 16 7.7 16.1 0.4 Fuel

  16. Manufacturing Energy and Carbon Footprint - Sector: Iron and Steel (NAICS 3311, 3312), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Iron and Steel (NAICS 3311, 3312) Process Energy Electricity and Steam Generation Losses Process Losses 49 Nonprocess Losses 1,463 404 Steam Distribution Losses 34 37 Nonprocess Energy 846 Electricity Generation Steam Generation 1,463 8 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 96 877 201 Generation and Transmission Losses Generation and Transmission Losses 3 404 973 830 226 1,056 605 12 177 0.7 35.1 35.9 17.7 50.1 4.8 58 22.0 57.9 1.4

  17. Manufacturing Energy and Carbon Footprint - Sector: Petroleum Refining (NAICS 324110), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Petroleum Refining (NAICS 324110) Process Energy Electricity and Steam Generation Losses Process Losses 234 Nonprocess Losses 3,542 689 Steam Distribution Losses 150 22 Nonprocess Energy 2,873 Electricity Generation Steam Generation 3,542 150 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 59 2,734 153 Generation and Transmission Losses Generation and Transmission Losses 58 308 2,793 2,285 891 3,176 461 208 657 13.2 26.7 40.0 139.2 176.3 3.2

  18. Manufacturing Energy and Carbon Footprint - Sector: Plastics (NAICS 326), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Plastics and Rubber Products (NAICS 326) Process Energy Electricity and Steam Generation Losses Process Losses 12 Nonprocess Losses 586 72 Steam Distribution Losses 8 28 Nonprocess Energy 115 Electricity Generation Steam Generation 586 1 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 64 187 156 Generation and Transmission Losses Generation and Transmission Losses 1 314 251 218 54 272 470 2 42 0.1 27.3 27.4 1.9 23.5 7.0 34 6.4 33.8 1.3 Fuel

  19. Manufacturing Energy and Carbon Footprint - Sector: Transportation Equipment (NAICS 336), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Transportation Equipment (NAICS 336) Process Energy Electricity and Steam Generation Losses Process Losses 10 Nonprocess Losses 541 68 Steam Distribution Losses 6 48 Nonprocess Energy 143 Electricity Generation Steam Generation 541 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 115 145 132 Generation and Transmission Losses Generation and Transmission Losses 0 266 259 234 41 275 398 0 32 0.0 23.1 23.1 3.0 16.6 11.9 31 7.9 31.0 2.6 Fuel

  20. Department of Energy Hosts Seminar on Spectrum Policy Seminar for Utility Sector

    Broader source: Energy.gov [DOE]

    On December 8, 2010, the Department of Energy General Counsels office hosted a seminar on the topic of spectrum policy, attended by approximately fifty representatives of the utility industry. At...

  1. National SCADA Test Bed- Enhancing control systems security in the energy sector (September 2009)

    Broader source: Energy.gov [DOE]

    Improving the security of energy control systems has become a national priority. Since the mid-1990s, security experts have become increasingly concerned about the threat of malicious cyber...

  2. Table 3.6 Consumer Expenditure Estimates for Energy by End-Use Sector, 1970-2010 (Million Dollars )

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

    Consumer Expenditure Estimates for Energy by End-Use Sector, 1970-2010 (Million Dollars 1) Year Residential Commercial Industrial Transportation Natural Gas 2 Petroleum Retail Electricity 3 Total 4 Natural Gas 2 Petroleum 5 Retail Electricity 3 Total 6,7 Coal Natural Gas 2 Petroleum 5 Biomass 8 Retail Electricity 3 Total 7,9 Petroleum 5 Total 7,10 1970 5,272 4,186 10,352 20,112 1,844 1,440 7,319 10,678 2,082 2,625 6,069 366 5,624 16,691 35,327 35,379 1971 5,702 4,367 11,589 21,934 2,060 1,574

  3. Model documentation report: Transportation sector model of the National Energy Modeling System

    SciTech Connect (OSTI)

    Not Available

    1994-03-01

    This report documents the objectives, analytical approach and development of the National Energy Modeling System (NEMS) Transportation Model (TRAN). The report catalogues and describes the model assumptions, computational methodology, parameter estimation techniques, model source code, and forecast results generated by the model. This document serves three purposes. First, it is a reference document providing a detailed description of TRAN for model analysts, users, and the public. Second, this report meets the legal requirements of the Energy Information Administration (EIA) to provide adequate documentation in support of its statistical and forecast reports (Public Law 93-275, 57(b)(1)). Third, it permits continuity in model development by providing documentation from which energy analysts can undertake model enhancements, data updates, and parameter refinements.

  4. Manufacturing Energy and Carbon Footprint - Sector: All Manufacturing (NAICS 31-33), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    582 Nonprocess Losses 21,972 4,807 Steam Distribution Losses 937 647 Nonprocess Energy 11,789 Electricity Generation Steam Generation 21,972 855 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 1,647 11,327 2,850 Generation and Transmission Losses Generation and Transmission Losses 318 6,161 Onsite Generation 12,974 9,639 5,855 15,494 9,011 1,173 4,276 74.3 544.3 618.6 330.7 322.9 290.6 788.0 142.6 1,261 642.8 1,261.3 29.3 Fuel Total Energy Total Primary Energy

  5. Manufacturing Energy and Carbon Footprint - Sector: Chemicals (NAICS 325), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    461 Nonprocess Losses 4,513 813 Steam Distribution Losses 282 89 Nonprocess Energy 2,138 Electricity Generation Steam Generation 4,513 540 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 253 2,198 517 Generation and Transmission Losses Generation and Transmission Losses 201 1,118 Onsite Generation 2,452 1,690 1,505 3,195 1,635 740 1,044 46.9 98.7 145.6 95.6 93.3 34.0 159.4 19.8 275 129.2 274.8 1.9 Fuel Total Energy Total Primary Energy Use: Total Combustion

  6. Manufacturing Energy and Carbon Footprint - Sector: Forest Products (NAICS 321, 322), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    04 Nonprocess Losses 3,559 1,079 Steam Distribution Losses 300 94 Nonprocess Energy 2,381 Electricity Generation Steam Generation 3,559 80 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 256 1,738 338 Generation and Transmission Losses Generation and Transmission Losses 30 731 Onsite Generation 1,994 717 2,082 2,799 1,069 110 1,581 7.0 64.6 71.5 52.1 49.8 15.4 76.5 11.3 140 68.4 139.9 3.1 Fuel Total Energy Total Primary Energy Use: Total Combustion Emissions: TBtu

  7. Profiles in renewable energy: Case studies of successful utility-sector projects

    SciTech Connect (OSTI)

    Anson, S.; Sinclair, K.; Swezey, B.

    1993-10-01

    As considerations of fuel diversity, environmental concerns, and market uncertainties are increasingly factored into electric utility resource planning, renewable energy technologies are beginning to find their place in the utility resource portfolio. This document profiles 10 renewable energy projects, utilizing six different renewable resources, that were built in the US throughout the 1980s. The resources include: biomass, geothermal, hydropower, photovoltaics, solar thermal, and wind. For each project, the factors that were key to its success and the development issues that it faced are discussed, as are the project`s cost, performance, and environmental impacts and benefits.

  8. Energy use and carbon dioxide emissions in the steel sector in key developing countries

    SciTech Connect (OSTI)

    Price, L.K.; Phylipsen, G.J.M.; Worrell, E.

    2001-04-01

    Iron and steel production consumes enormous quantities of energy, especially in developing countries where outdated, inefficient technologies are still used to produce iron and steel. Carbon dioxide emissions from steel production, which range between 5 and 15% of total country emissions in key developing countries (Brazil, China, India, Mexico, and South Africa), will continue to grow as these countries develop and as demand for steel products such as materials, automobiles, and appliances increases. In this report, we describe the key steel processes, discuss typical energy-intensity values for these processes, review historical trends in iron and steel production by process in five key developing countries, describe the steel industry in each of the five key developing countries, present international comparisons of energy use and carbon dioxide emissions among these countries, and provide our assessment of the technical potential to reduce these emissions based on best-practice benchmarking. Using a best practice benchmark, we find that significant savings, in the range of 33% to 49% of total primary energy used to produce steel, are technically possible in these countries. Similarly, we find that the technical potential for reducing intensities of carbon dioxide emissions ranges between 26% and 49% of total carbon dioxide emissions from steel production in these countries.

  9. TAP Webinar: Best Practices in Energy Data Collection and Tracking in the Public Sector

    Broader source: Energy.gov [DOE]

    This webinar, held on Dec. 18, 2014, covered DOE's Weatherization and Intergovernmental Program Office's step-by-step guide with best practices from state and local governments and school districts across the country demonstrating the value of an energy data tracking effort.

  10. Regional variations in US residential sector fuel prices: implications for development of building energy performance standards

    SciTech Connect (OSTI)

    Nieves, L.A.; Tawil, J.J.; Secrest, T.J.

    1981-03-01

    The Notice of Proposed Rulemaking for Energy Performance Standards for New Buildings presented life-cycle-cost based energy budgets for single-family detached residences. These energy budgets varied with regional climatic conditions but were all based on projections of national average prices for gas, oil and electricity. The Notice of Proposed Rulemaking indicated that further analysis of the appropriateness of various price measures for use in setting the Standards was under way. This part of that ongoing analysis addresses the availability of fuel price projections, the variation in fuel prices and escalation rates across the US and the effects of aggregating city price data to the state, Region, or national level. The study only provides a portion of the information required to identify the best price aggregation level for developing of the standards. The research addresses some of the economic efficiency considerations necessary for design of a standard that affects heterogeneous regions. The first section discusses the effects of price variation among and within regions on the efficiency of resource allocation when a standard is imposed. Some evidence of the extreme variability in fuel prices across the US is presented. In the second section, time series, cross-sectional fuel price data are statistically analyzed to determine the similarity in mean fuel prices and price escalation rates when the data are treated at increasing levels of aggregation. The findings of this analysis are reported in the third section, while the appendices contain price distributions details. The last section reports the availability of price projections and discusses some EIA projections compared with actual prices.

  11. Buildings Energy Data Book: 8.1 Buildings Sector Water Consumption

    Buildings Energy Data Book [EERE]

    3 Energy Use of Wastewater Treatment Plants by Capacity and Treatment Level (kWh per Million Gallons) 1 - 5 - 10 - 20 - 50 - 100 - Note(s): Source(s): 673 1,028 1,188 1,558 The level of treatment indicates the amount of processing involved before water is released from the treatment facility. Primary treatment removes solids and oils from wastewater. Secondary treatment uses biological processes to remove organic material from the water. Tertiary treatment includes additional processes to

  12. The Potential for Energy-Efficient Technologies to Reduce Carbon Emissions in the United States: Transport Sector

    SciTech Connect (OSTI)

    Greene, D.L.

    1997-07-01

    The world is searching for a meaningful answer to the likelihood that the continued build-up of greenhouse gases in the atmosphere will cause significant changes in the earth`s climate. If there is to be a solution, technology must play a central role. This paper presents the results of an assessment of the potential for cost-effective technological changes to reduce greenhouse gas emissions from the U.S. transportation sector by the year 2010. Other papers in this session address the same topic for buildings and industry. U.S.transportation energy use stood at 24.4 quadrillion Btu (Quads) in 1996, up 2 percent over 1995 (U.S. DOE/EIA, 1997, table 2.5). Transportation sector carbon dioxide emissions amounted to 457.2 million metric tons of carbon (MmtC) in 1995, almost one third of total U.S. greenhouse gas emissions (U.S. DOE/EIA,1996a, p. 12). Transport`s energy use and CO{sub 2} emissions are growing, apparently at accelerating rates as energy efficiency improvements appear to be slowing to a halt. Cost-effective and nearly cost-effective technologies have enormous potential to slow and even reverse the growth of transport`s CO{sub 2} emissions, but technological changes will take time and are not likely to occur without significant, new public policy initiatives. Absent new initiatives, we project that CO{sub 2} emissions from transport are likely to grow to 616 MmtC by 2010, and 646 MmtC by 2015. An aggressive effort to develop and implement cost-effective technologies that are more efficient and fuels that are lower in carbon could reduce emissions by about 12% in 2010 and 18% in 2015, versus the business-as- usual projection. With substantial luck, leading to breakthroughs in key areas, reductions over the BAU case of 17% in 2010 and 25% in 2015,might be possible. In none of these case are CO{sub 2} emissions reduced to 1990 levels by 2015.

  13. Natural Gas and the Transformation of the U.S. Energy Sector: A Program Studying Multi-sector Opportunities and Impacts

    SciTech Connect (OSTI)

    Gossett, S.

    2013-01-01

    In recognition of the major transitions occurring within the U.S. energy economy, the Joint Institute for Strategic Energy Analysis (JISEA) and Stanford University's Precourt Institute for Energy (PIE) engaged energy system stakeholders from government, industry, academia, and the environmental community in a discussion about the priority issues for a program of rigorous research relating to natural gas. Held December 10-11, 2012 on the Golden, CO campus of the National Renewable Energy Laboratory, the workshop provided invited experts opportunity to describe the state of current knowledge in defined topic areas, and to suggest analytic priorities for that topic area. Following discussion, all stakeholders then contributed potential research questions for each topic, and then determined priorities through an interactive voting process. This record of proceedings focuses on the outcomes of the discussion.

  14. Country Review of Energy-Efficiency Financial Incentives in the Residential Sector

    SciTech Connect (OSTI)

    Can, Stephane de la Rue du; Shah, Nihar; Phadke, Amol

    2011-07-13

    A large variety of energy-efficiency policy measures exist. Some are mandatory, some are informative, and some use financial incentives to promote diffusion of efficient equipment. From country to country, financial incentives vary considerably in scope and form, the type of framework used to implement them, and the actors that administer them. They range from rebate programs administered by utilities under an Energy-Efficiency Resource Standards (EERS) regulatory framework (California, USA) to the distribution of Eco-points rewarding customers for buying highly efficient appliances (Japan). All have the primary objective of transforming the current market to accelerate the diffusion of efficient technologies by addressing up-front cost barriers faced by consumers; in most instances, efficient technologies require a greater initial investment than conventional technologies. In this paper, we review the different market transformation measures involving the use of financial incentives in the countries belonging to the Major Economies Forum. We characterize the main types of measures, discuss their mechanisms, and provide information on program impacts to the extent that ex-ante or ex-post evaluations have been conducted. Finally, we identify best practices in financial incentive programs and opportunities for coordination between Major Economies Forum countries as envisioned under the Super Efficient Appliance Deployment (SEAD) initiative.

  15. Accelerating Investments in the Geothermal Sector, Indonesia...

    Open Energy Info (EERE)

    Accelerating Investments in the Geothermal Sector, Indonesia (Presentation) Author Paul Brophy Conference World Geothermal Energy Summit; Jakarta, Indonesia; 20120706...

  16. Model documentation report: Transportation sector model of the National Energy Modeling System

    SciTech Connect (OSTI)

    1997-02-01

    Over the past year, several modifications have been made to the NEMS Transportation Model, incorporating greater levels of detail and analysis in modules previously represented in the aggregate or under a profusion of simplifying assumptions. This document is intended to amend those sections of the Model Documentation Report (MDR) which describe these superseded modules. Significant changes have been implemented in the LDV Fuel Economy Model, the Alternative Fuel Vehicle Model, the LDV Fleet Module, and the Highway Freight Model. The relevant sections of the MDR have been extracted from the original document, amended, and are presented in the following pages. A brief summary of the modifications follows: In the Fuel Economy Model, modifications have been made which permit the user to employ more optimistic assumptions about the commercial viability and impact of selected technological improvements. This model also explicitly calculates the fuel economy of an array of alternative fuel vehicles (AFV`s) which are subsequently used in the estimation of vehicle sales. In the Alternative Fuel Vehicle Model, the results of the Fuel Economy Model have been incorporated, and the program flows have been modified to reflect that fact. In the Light Duty Vehicle Fleet Module, the sales of vehicles to fleets of various size are endogenously calculated in order to provide a more detailed estimate of the impacts of EPACT legislation on the sales of AFV`s to fleets. In the Highway Freight Model, the previous aggregate estimation has been replaced by a detailed Freight Truck Stock Model, where travel patterns, efficiencies, and energy intensities are estimated by industrial grouping. Several appendices are provided at the end of this document, containing data tables and supplementary descriptions of the model development process which are not integral to an understanding of the overall model structure.

  17. Sector Profiles of Significant Large CHP Markets, March 2004 | Department

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

    of Energy Sector Profiles of Significant Large CHP Markets, March 2004 Sector Profiles of Significant Large CHP Markets, March 2004 In this 2004 report, three sectors were identified as promising combined heat and power (CHP) sectors: chemicals, food, and pharmaceuticals. Sector profiles are based on a literature search, review of recent CHP activity in those sectors, and telephone interviews with customer representatives in each sector. PDF icon sector_profiles.pdf More Documents &

  18. Live Webinar on Better Buildings Challenge: Public-Sector Update

    Broader source: Energy.gov [DOE]

    The Energy Department will present a live webinar titled "Better Buildings Challenge: Public-Sector Update."

  19. Buildings Sector Working Group

    Gasoline and Diesel Fuel Update (EIA)

    July 22, 2013 AEO2014 Model Development For discussion purposes only Not for citation Overview Builldings Working Group Forrestal 2E-069 / July 22, 2013 2 * Residential projects - RECS update - Lighting model - Equipment, shell subsidies - ENERGY STAR benchmarking - Housing stock formation and decay * Commercial projects - Major end-use capacity factors - Hurdle rates - ENERGY STAR buildings * Both sectors - Consumer behavior workshop - Comparisons to STEO - AER  MER - Usual annual updates -

  20. Energy by State | Open Energy Information

    Open Energy Info (EERE)

    per ) Compare By: US States Sector End-Use Sectors Electric Power Sector Energy Source, Consumption Coal Geothermal Energy Hydroelectric Power Natural Gas Nuclear Energy...

  1. Greenhouse Gas Mitigation Options in ISEEM Global Energy Model: 2010-2050 Scenario Analysis for Least-Cost Carbon Reduction in Iron and Steel Sector

    SciTech Connect (OSTI)

    Karali, Nihan; Xu, Tengfang; Sathaye, Jayant

    2013-12-01

    The goal of the modeling work carried out in this project was to quantify long-term scenarios for the future emission reduction potentials in the iron and steel sector. The main focus of the project is to examine the impacts of carbon reduction options in the U.S. iron and steel sector under a set of selected scenarios. In order to advance the understanding of carbon emission reduction potential on the national and global scales, and to evaluate the regional impacts of potential U.S. mitigation strategies (e.g., commodity and carbon trading), we also included and examined the carbon reduction scenarios in Chinas and Indias iron and steel sectors in this project. For this purpose, a new bottom-up energy modeling framework, the Industrial Sector Energy Efficiency Modeling (ISEEM), (Karali et al. 2012) was used to provide detailed annual projections starting from 2010 through 2050. We used the ISEEM modeling framework to carry out detailed analysis, on a country-by-country basis, for the U.S., Chinas, and Indias iron and steel sectors. The ISEEM model applicable to iron and steel section, called ISEEM-IS, is developed to estimate and evaluate carbon emissions scenarios under several alternative mitigation options - including policies (e.g., carbon caps), commodity trading, and carbon trading. The projections will help us to better understand emission reduction potentials with technological and economic implications. The database for input of ISEEM-IS model consists of data and information compiled from various resources such as World Steel Association (WSA), the U.S. Geological Survey (USGS), China Steel Year Books, India Bureau of Mines (IBM), Energy Information Administration (EIA), and recent LBNL studies on bottom-up techno-economic analysis of energy efficiency measures in the iron and steel sector of the U.S., China, and India, including long-term steel production in China. In the ISEEM-IS model, production technology and manufacturing details are represented, in addition to the extensive data compiled from recent studies on bottom-up representation of efficiency measures for the sector. We also defined various mitigation scenarios including long-term production trends to project country-specific production, energy use, trading, carbon emissions, and costs of mitigation. Such analyses can provide useful information to assist policy-makers when considering and shaping future emissions mitigation strategies and policies. The technical objective is to analyze the costs of production and CO{sub 2} emission reduction in the U.S, China, and Indias iron and steel sectors under different emission reduction scenarios, using the ISEEM-IS as a cost optimization model. The scenarios included in this project correspond to various CO{sub 2} emission reduction targets for the iron and steel sector under different strategies such as simple CO{sub 2} emission caps (e.g., specific reduction goals), emission reduction via commodity trading, and emission reduction via carbon trading.

  2. Overcoming Multifamily Sector Barriers in Austin, Texas | Department...

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

    Overcoming Multifamily Sector Barriers in Austin, Texas Overcoming Multifamily Sector Barriers in Austin, Texas Presents techniques on overcoming the barriers of multifamily energy...

  3. Energy Exchange: Recruiting, Developing, and Retaining the Next Generation of Employees to Support Energy Efficiency, Renewable Energy and Sustainability in the Public Sector

    Broader source: Energy.gov [DOE]

    Location: Phoenix Convention Center, Phoenix, ArizonaWebsite: http://energy.gov/eere/femp/energy-exchangeContact: Recruitment@doe.gov

  4. Advanced Vehicle Electrification & Transportation Sector Electrification |

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

    Department of Energy & Transportation Sector Electrification Advanced Vehicle Electrification & Transportation Sector Electrification 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation PDF icon arravt071_vss_cesiel_2011_o.pdf More Documents & Publications Advanced Vehicle Electrification and Transportation Sector Electrification Advanced Vehicle Electrification and Transportation Sector Electrification Plug-in Hybrid

  5. Review of private sector and Department of Energy treatment, storage, and disposal capabilities for low-level and mixed low-level waste

    SciTech Connect (OSTI)

    Willson, R.A.; Ball, L.W.; Mousseau, J.D.; Piper, R.B.

    1996-03-01

    Private sector capacity for treatment, storage, and disposal (TSD) of various categories of radioactive waste has been researched and reviewed for the Idaho National Engineering Laboratory (INEL) by Lockheed Idaho Technologies Company, the primary contractor for the INEL. The purpose of this document is to provide assistance to the INEL and other US Department of Energy (DOE) sites in determining if private sector capabilities exist for those waste streams that currently cannot be handled either on site or within the DOE complex. The survey of private sector vendors was limited to vendors currently capable of, or expected within the next five years to be able to perform one or more of the following services: low-level waste (LLW) volume reduction, storage, or disposal; mixed LLW treatment, storage, or disposal; alpha-contaminated mixed LLW treatment; LLW decontamination for recycling, reclamation, or reuse; laundering of radioactively-contaminated laundry and/or respirators; mixed LLW treatability studies; mixed LLW treatment technology development. Section 2.0 of this report will identify the approach used to modify vendor information from previous revisions of this report. It will also illustrate the methodology used to identify any additional companies. Section 3.0 will identify, by service, specific vendor capabilities and capacities. Because this document will be used to identify private sector vendors that may be able to handle DOE LLW and mixed LLW streams, it was decided that current DOE capabilities should also be identified. This would encourage cooperation between DOE sites and the various states and, in some instances, may result in a more cost-effective alternative to privatization. The DOE complex has approximately 35 sites that generate the majority of both LLW and mixed LLW. Section 4.0 will identify these sites by Operations Office, and their associated LLW and mixed LLW TSD units.

  6. Table 11.2a Carbon Dioxide Emissions From Energy Consumption: Residential Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide )

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

    a Carbon Dioxide Emissions From Energy Consumption: Residential Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide 1) Year Coal Natural Gas 3 Petroleum Retail Electricity 5 Total 2 Biomass 2 Distillate Fuel Oil 4 Kerosene Liquefied Petroleum Gases Total Wood 6 Total 6 1949 121 55 51 21 7 80 66 321 99 99 1950 120 66 61 25 9 95 69 350 94 94 1951 111 81 68 27 10 105 78 374 90 90 1952 103 89 70 27 10 108 85 385 84 84 1953 92 93 71 26 11 108 94 387 78 78 1954 82 104 79 27 12 118 99 404 75 75

  7. Table 11.2c Carbon Dioxide Emissions From Energy Consumption: Industrial Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide )

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

    c Carbon Dioxide Emissions From Energy Consumption: Industrial Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide 1) Year Coal Coal Coke Net Imports Natural Gas 3 Petroleum Retail Elec- tricity 8 Total 2 Biomass 2 Distillate Fuel Oil 4 Kero- sene LPG 5 Lubri- cants Motor Gasoline 6 Petroleum Coke Residual Fuel Oil Other 7 Total Wood 9 Waste 10 Fuel Ethanol 11 Total 1949 500 -1 166 41 18 3 3 16 8 95 25 209 120 995 44 NA NA 44 1950 531 (s) 184 51 20 4 3 18 8 110 26 239 140 1,095 50 NA NA 50

  8. Table 11.2d Carbon Dioxide Emissions From Energy Consumption: Transportation Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide )

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

    d Carbon Dioxide Emissions From Energy Consumption: Transportation Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide 1) Year Coal Natural Gas 3 Petroleum Retail Elec- tricity 7 Total 2 Biomass 2 Aviation Gasoline Distillate Fuel Oil 4 Jet Fuel LPG 5 Lubricants Motor Gasoline 6 Residual Fuel Oil Total Fuel Ethanol 8 Biodiesel Total 1949 161 NA 12 30 NA (s) 4 306 91 443 6 611 NA NA NA 1950 146 7 14 35 NA (s) 5 332 95 481 6 640 NA NA NA 1951 129 11 18 42 NA (s) 6 360 102 529 7 675 NA NA NA

  9. Model Documentation Report: Commercial Sector Demand Module...

    Gasoline and Diesel Fuel Update (EIA)

    the State Energy Data System (SEDS) historical commercial sector consumption, applying an additive correction term to ensure that simulated model results correspond to published...

  10. Sector-specific issues and reporting methodologies supporting the General Guidelines for the voluntary reporting of greenhouse gases under Section 1605(b) of the Energy Policy Act of 1992. Volume 1: Part 1, Electricity supply sector; Part 2, Residential and commercial buildings sector; Part 3, Industrial sector

    SciTech Connect (OSTI)

    Not Available

    1994-10-01

    DOE encourages you to report your achievements in reducing greenhouse gas emissions and sequestering carbon under this program. Global climate change is increasingly being recognized as a threat that individuals and organizations can take action against. If you are among those taking action, reporting your projects may lead to recognition for you, motivation for others, and synergistic learning for the global community. This report discusses the reporting process for the voluntary detailed guidance in the sectoral supporting documents for electricity supply, residential and commercial buildings, industry, transportation, forestry, and agriculture. You may have reportable projects in several sectors; you may report them separately or capture and report the total effects on an entity-wide report.

  11. SLP Energy | Open Energy Information

    Open Energy Info (EERE)

    Sector: Renewable Energy, Services Product: Focused on the renewable energy sector, SLP Energy offers early to late stage project development services and capabilities....

  12. Manufacturing Energy and Carbon Footprint - Sector: Computer, Electronics and Appliances (NAICS 334, 335), October 2012 (MECS 2006)

    Broader source: Energy.gov (indexed) [DOE]

    335) Process Energy Electricity and Steam Generation Losses Process Losses 6 Nonprocess Losses 527 48 Steam Distribution Losses 5 43 Nonprocess Energy 89 Electricity Generation Steam Generation 527 1 Prepared for the Advanced Manufacturing Office (AMO) by Energetics Incorporated 103 114 138 Generation and Transmission Losses Generation and Transmission Losses 0 298 Onsite Generation 217 199 29 228 436 1 23 0.0 26.4 26.4 1.8 1.6 1.6 16.6 13.0 31 4.9 31.3 1.7 Fuel Total Energy Energy use data

  13. U.S. DOE TAP Webinar: Best Practices in Energy Data Collection and Tracking in the Public Sector

    Broader source: Energy.gov [DOE]

    Implementing a robust and comprehensive energy tracking and measurement process can be a challenge. This webinar will cover DOE's Weatherization and Intergovernmental Program Office's step-by-step...

  14. Energy Implications of Retrofitting Retail Sector Rooftop Units with Stepped-Speed and Variable-Speed Functionality

    SciTech Connect (OSTI)

    Studer, D.; Romero, R.; Herrmann, L.; Benne, K.

    2012-04-01

    Commercial retailers understand that retrofitting constant-speed RTU fan motors with stepped- or variable-speed alternatives could save significant energy in most U.S. climate zones. However, they lack supporting data, both real-world and simulation based, on the cost effectiveness and climate zone-specific energy savings associated with this measure. Thus, building managers and engineers have been unable to present a compelling business case for fan motor upgrades to upper management. This study uses whole-building energy simulation to estimate the energy impact of this type of measure so retailers can determine its economic feasibility.

  15. Carbon Market Opportunities for the Forestry Sector of Africa...

    Open Energy Info (EERE)

    of the United Nations, Winrock International Sector: Land Focus Area: Renewable Energy, Forestry Topics: Implementation, Policiesdeployment programs Resource Type:...

  16. Setting Whole-Building Absolute Energy Use Targets for the K-12 School, Retail, and Healthcare Sectors: Preprint

    SciTech Connect (OSTI)

    Leach, M.; Bonnema, E.; Pless, S.; Torcellini, P.

    2012-08-01

    This paper helps owners' efficiency representatives to inform executive management, contract development, and project management staff as to how specifying and applying whole-building absolute energy use targets for new construction or renovation projects can improve the operational energy performance of commercial buildings.

  17. Assessment of Historic Trend in Mobility and Energy Use in India Transportation Sector Using Bottom-up Approach

    SciTech Connect (OSTI)

    Zhou, Nan; McNeil, Michael A.

    2009-05-01

    Transportation mobility in India has increased significantly in the past decades. From 1970 to 2000, motorized mobility (passenger-km) has risen by 888%, compared with an 88% population growth (Singh,2006). This contributed to many energy and environmental issues, and an energy strategy incorporates efficiency improvement and other measures needs to be designed. Unfortunately, existing energy data do not provide information on driving forces behind energy use and sometime show large inconsistencies. Many previous studies address only a single transportation mode such as passenger road travel; did not include comprehensive data collection or analysis has yet been done, or lack detail on energy demand by each mode and fuel mix. The current study will fill a considerable gap in current efforts, develop a data base on all transport modes including passenger air and water, and freight in order to facilitate the development of energy scenarios and assess significance of technology potential in a global climate change model. An extensive literature review and data collection has been done to establish the database with breakdown of mobility, intensity, distance, and fuel mix of all transportation modes. Energy consumption was estimated and compared with aggregated transport consumption reported in IEA India transportation energy data. Different scenarios were estimated based on different assumptions on freight road mobility. Based on the bottom-up analysis, we estimated that the energy consumption from 1990 to 2000 increased at an annual growth rate of 7% for the mid-range road freight growth case and 12% for the high road freight growth case corresponding to the scenarios in mobility, while the IEA data only shows a 1.7% growth rate in those years.

  18. Manufacturing Energy and Carbon Footprint - Sector: Computer, Electronics and Appliances (NAICS 334, 335), January 2014 (MECS 2010)

    Office of Environmental Management (EM)

    Computers, Electronics and Electrical Equipment (NAICS 334, 335) Process Energy Electricity and Steam Generation Losses Process Losses 5 Nonprocess Losses 493 46 Steam Distribution Losses 4 41 Nonprocess Energy 80 Electricity Generation Steam Generation 493 0 Prepared for the U.S. Department of Energy, Advanced Manufacturing Office by Energetics Incorporated 103 105 137 Generation and Transmission Losses Generation and Transmission Losses 0 276 208 193 24 217 413 0 19 0.0 23.9 23.9 1.4 14.4 12.4

  19. Market Report for the Industrial Sector, 2009

    SciTech Connect (OSTI)

    Sastri, Bhima; Brueske, Sabine; de los Reyes, Pamela; Jamison, Keith; Justiniano, Mauricio; Margolis, Nancy; Monfort, Joe; Raghunathan, Anand; Sabouni, Ridah

    2009-07-01

    This report provides an overview of trends in industrial-sector energy use. It focuses on some of the largest and most energy-intensive industrial subsectors and several emerging technologies that could transform key segments of industry.

  20. Table 11.2b Carbon Dioxide Emissions From Energy Consumption: Commercial Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide )

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

    b Carbon Dioxide Emissions From Energy Consumption: Commercial Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide 1) Year Coal Natural Gas 3 Petroleum Retail Electricity 7 Total 2 Biomass 2 Distillate Fuel Oil 4 Kerosene LPG 5 Motor Gasoline 6 Petroleum Coke Residual Fuel Oil Total Wood 8 Waste 9 Fuel Ethanol 10 Total 1949 148 19 16 3 2 7 NA 28 55 58 280 2 NA NA 2 1950 147 21 19 3 2 7 NA 33 66 63 297 2 NA NA 2 1951 125 25 21 4 3 8 NA 34 70 69 289 2 NA NA 2 1952 112 28 22 4 3 8 NA 35 71 73

  1. Table 11.2e Carbon Dioxide Emissions From Energy Consumption: Electric Power Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide )

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

    e Carbon Dioxide Emissions From Energy Consumption: Electric Power Sector, 1949-2011 (Million Metric Tons of Carbon Dioxide 1) Year Coal Natural Gas 3 Petroleum Geo- thermal Non- Biomass Waste 5 Total 2 Biomass 2 Distillate Fuel Oil 4 Petroleum Coke Residual Fuel Oil Total Wood 6 Waste 7 Total 1949 187 30 2 NA 30 33 NA NA 250 1 NA 1 1950 206 35 2 NA 35 37 NA NA 278 1 NA 1 1951 235 42 2 NA 29 31 NA NA 308 1 NA 1 1952 240 50 2 NA 31 33 NA NA 323 1 NA 1 1953 260 57 3 NA 38 40 NA NA 358 (s) NA (s)

  2. Table 3.4 Consumer Price Estimates for Energy by End-Use Sector, 1970-2010 (Dollars per Million Btu)

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

    Consumer Price Estimates for Energy by End-Use Sector, 1970-2010 (Dollars 1 per Million Btu) Year Residential Commercial Industrial Transportation Natural Gas 2 Petroleum Retail Electricity 3 Total 4 Natural Gas 2 Petroleum 5 Retail Electricity 3 Total 6,7 Coal Natural Gas 2 Petroleum 5 Biomass 8 Retail Electricity 3 Total 7,9 Petroleum 5 Total 7,10 1970 1.06 1.54 6.51 2.10 0.75 0.90 [R] 6.09 1.97 0.45 0.38 0.98 1.59 2.99 0.84 2.31 2.31 1971 1.12 1.59 6.80 2.24 .80 1.02 6.44 2.15 .50 .41 1.05

  3. Modeling distributed generation in the buildings sectors

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Modeling distributed generation in the buildings sectors August 2013 Independent Statistics & Analysis www.eia.gov U.S. Department of Energy Washington, DC 20585 U.S. Energy Information Administration | Modeling distributed generation in the buildings sectors i This report was prepared by the U.S. Energy Information Administration (EIA), the statistical and analytical agency within the U.S. Department of Energy. By law, EIA's data, analyses, and forecasts are independent of approval by any

  4. Bottom-up Representation of Industrial Energy Efficiency Technologies in Integrated Assessment Models for the Cement Sector

    SciTech Connect (OSTI)

    Sathaye, J.; Xu, T.; Galitsky, C.

    2010-08-15

    Adoption of efficient end-use technologies is one of the key measures for reducing greenhouse gas (GHG) emissions. How to effectively analyze and manage the costs associated with GHG reductions becomes extremely important for the industry and policy makers around the world. Energy-climate (EC) models are often used for analyzing the costs of reducing GHG emissions for various emission-reduction measures, because an accurate estimation of these costs is critical for identifying and choosing optimal emission reduction measures, and for developing related policy options to accelerate market adoption and technology implementation. However, accuracies of assessing of GHG-emission reduction costs by taking into account the adoption of energy efficiency technologies will depend on how well these end-use technologies are represented in integrated assessment models (IAM) and other energy-climate models.

  5. Development of Bottom-up Representation of Industrial Energy Efficiency Technologies in Integrated Assessment Models for the Iron and Steel Sector

    SciTech Connect (OSTI)

    Xu, T.T.; Sathaye, J.; Galitsky, C.

    2010-09-30

    Adoption of efficient end-use technologies is one of the key measures for reducing greenhouse gas (GHG) emissions. With the working of energy programs and policies on carbon regulation, how to effectively analyze and manage the costs associated with GHG reductions become extremely important for the industry and policy makers around the world. Energy-climate (EC) models are often used for analyzing the costs of reducing GHG emissions (e.g., carbon emission) for various emission-reduction measures, because an accurate estimation of these costs is critical for identifying and choosing optimal emission reduction measures, and for developing related policy options to accelerate market adoption and technology implementation. However, accuracies of assessing of GHG-emission reduction costs by taking into account the adoption of energy efficiency technologies will depend on how well these end-use technologies are represented in integrated assessment models (IAM) and other energy-climate models. In this report, we first conduct brief overview on different representations of end-use technologies (mitigation measures) in various energy-climate models, followed by problem statements, and a description of the basic concepts of quantifying the cost of conserved energy including integrating non-regrets options. A non-regrets option is defined as a GHG reduction option that is cost effective, without considering their additional benefits related to reducing GHG emissions. Based upon these, we develop information on costs of mitigation measures and technological change. These serve as the basis for collating the data on energy savings and costs for their future use in integrated assessment models. In addition to descriptions of the iron and steel making processes, and the mitigation measures identified in this study, the report includes tabulated databases on costs of measure implementation, energy savings, carbon-emission reduction, and lifetimes. The cost curve data on mitigation measures are available over time, which allows an estimation of technological change over a decade-long historical period. In particular, the report will describe new treatment of technological change in energy-climate modeling for this industry sector, i.e., assessing the changes in costs and energy-savings potentials via comparing 1994 and 2002 conservation supply curves. In this study, we compared the same set of mitigation measures for both 1994 and 2002 -- no additional mitigation measure for year 2002 was included due to unavailability of such data. Therefore, the estimated potentials in total energy savings and carbon reduction would most likely be more conservative for year 2002 in this study. Based upon the cost curves, the rate of change in the savings potential at a given cost can be evaluated and be used to estimate future rates of change that can be the input for energy-climate models. Through characterizing energy-efficiency technology costs and improvement potentials, we have developed and presented energy cost curves for energy efficiency measures applicable to the U.S. iron and steel industry for the years 1994 and 2002. The cost curves can change significantly under various scenarios: the baseline year, discount rate, energy intensity, production, industry structure (e.g., integrated versus secondary steel making and number of plants), efficiency (or mitigation) measures, share of iron and steel production to which the individual measures can be applied, and inclusion of other non-energy benefits. Inclusion of other non-energy benefits from implementing mitigation measures can reduce the costs of conserved energy significantly. In addition, costs of conserved energy (CCE) for individual mitigation measures increase with the increases in discount rates, resulting in a general increase in total cost of mitigation measures for implementation and operation with a higher discount rate. In 1994, integrated steel mills in the U.S. produced 55.

  6. Large-Scale Utilization of Biomass Energy and Carbon Dioxide Capture and Storage in the Transport and Electricity Sectors under Stringent CO2 Concentration Limit Scenarios

    SciTech Connect (OSTI)

    Luckow, Patrick; Wise, Marshall A.; Dooley, James J.; Kim, Son H.

    2010-08-05

    This paper examines the potential role of large scale, dedicated commercial biomass energy systems under global climate policies designed to meet atmospheric concentrations of CO2 at 400ppm and 450ppm by the end of the century. We use an integrated assessment model of energy and agriculture systems to show that, given a climate policy in which terrestrial carbon is appropriately valued equally with carbon emitted from the energy system, biomass energy has the potential to be a major component of achieving these low concentration targets. A key aspect of the research presented here is that the costs of processing and transporting biomass energy at much larger scales than current experience are explicitly incorporated into the modeling. From the scenario results, 120-160 EJ/year of biomass energy is produced globally by midcentury and 200-250 EJ/year by the end of this century. In the first half of the century, much of this biomass is from agricultural and forest residues, but after 2050 dedicated cellulosic biomass crops become the majority source, along with growing utilization of waste-to-energy. The ability to draw on a diverse set of biomass based feedstocks helps to reduce the pressure for drastic large-scale changes in land use and the attendant environmental, ecological, and economic consequences those changes would unleash. In terms of the conversion of bioenergy feedstocks into value added energy, this paper demonstrates that biomass is and will continue to be used to generate electricity as well as liquid transportation fuels. A particular focus of this paper is to show how climate policies and technology assumptions - especially the availability of carbon dioxide capture and storage (CCS) technologies - affect the decisions made about where the biomass is used in the energy system. The potential for net-negative electric sector emissions through the use of CCS with biomass feedstocks provides an attractive part of the solution for meeting stringent emissions constraints; we find that at carbon prices above 150$/tCO2, over 90% of biomass in the energy system is used in combination with CCS. Despite the higher technology costs of CCS, it is a very important tool in controlling the cost of meeting a target, offsetting the venting of CO2 from sectors of the energy system that may be more expensive to mitigate, such as oil use in transportation. CCS is also used heavily with other fuels such as coal and natural gas, and by 2095 a total of 1530 GtCO2 has been stored in deep geologic reservoirs. The paper also discusses the role of cellulosic ethanol and Fischer-Tropsch biomass derived transportation fuels as two representative conversion processes and shows that both technologies may be important contributors to liquid fuels production, with unique costs and emissions characteristics.

  7. Text-Alternative Version of TAP Webinar: Best Practices in Energy Data Collection and Tracking in the Public Sector

    Broader source: Energy.gov [DOE]

    This webinar, held on Dec. 18, 2014, covered DOE's Weatherization and Intergovernmental Program Office's step-by-step guide with best practices from state and local governments and school districts across the country demonstrating the value of an energy data tracking effort.

  8. Vehicle Technologies Office: Transitioning the Transportation Sector -

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

    Exploring the Intersection of H2 Fuel Cell and Natural Gas Vehicles | Department of Energy Transitioning the Transportation Sector - Exploring the Intersection of H2 Fuel Cell and Natural Gas Vehicles Vehicle Technologies Office: Transitioning the Transportation Sector - Exploring the Intersection of H2 Fuel Cell and Natural Gas Vehicles This report, titled "Transitioning the Transportation Sector: Exploring the Intersection of Hydrogen Fuel Cell and Natural Gas Vehicles" is based

  9. Analysis of the research and development effort in the private sector to reduce energy consumption in irrigated agriculture

    SciTech Connect (OSTI)

    Rogers, E.A.; Cone, B.W.

    1980-09-01

    Manufacturers of irrigation equipment perform research and development in an effort to improve or maintain their position in a very competitive market. The market forces and conditions that create the intense competition and provide incentive for invention are described. Particular emphasis is placed on the market force of increased energy costs, but the analysis is developed from the perspective that energy is but one of many inputs to agricultural production. The analysis is based upon published literature, patent activity profiles, microeconomic theory, and conversations with many representatives of the irrigation industry. The published literature provides an understanding of the historical development of irrigation technology, a description of the industry's structure, and various data, which were important for the quantitative analyses. The patent activity profiles, obtained from the US Patent Office, provided details of patent activity within the irrigation industry over the past decade. Microeconomic theory was used to estimate industry-wide research and development expenditures on energy-conserving products. The results of these analyses were then compared with the insights gained from conversations with the industry representatives.

  10. National Electric Sector Cybersecurity Organization Resource (NESCOR)

    SciTech Connect (OSTI)

    None, None

    2014-06-30

    The goal of the National Electric Sector Cybersecurity Organization Resource (NESCOR) project was to address cyber security issues for the electric sector, particularly in the near and mid-term. The following table identifies the strategies from the DOE Roadmap to Achieve Energy Delivery Systems Cybersecurity published in September 2011 that are applicable to the NESCOR project.

  11. SEADS 3.0. Sectoral Energy/Employment Analysis and Data System Methodology, Description, and Users Guide. Two Policy Scenarios Examined: An Increase in Government R&D Implementation of Voluntary Intensity. Reductions in Industry

    SciTech Connect (OSTI)

    Roop, J. M.; Anderson, D. M.; Elliott, D. B.; Schultz, R. W.

    2007-12-01

    This report describes the tool and the underlying methodology for SEADS 3.0, the Sectoral Energy/Employment Analysis and Data System, which is a software package designed for the analysis of policy that could be described by modifying final demands of consumer, businesses, or governments. The report also provides a users manual, examples for two analyses and the results for them.

  12. Integrated Canada-U.S. Power Sector Modeling with the Regional Energy Deployment System (ReEDS)

    SciTech Connect (OSTI)

    Martinez, A.; Eurek, K.; Mai, T.; Perry, A.

    2013-02-01

    The electric power system in North America is linked between the United States and Canada. Canada has historically been a net exporter of electricity to the United States. The extent to which this remains true will depend on the future evolution of power markets, technology deployment, and policies. To evaluate these and related questions, we modify the Regional Energy Deployment System (ReEDS) model to include an explicit representation of the grid-connected power system in Canada to the continental United States. ReEDS is unique among long-term capacity expansion models for its high spatial resolution and statistical treatment of the impact of variable renewable generation on capacity planning and dispatch. These unique traits are extended to new Canadian regions. We present example scenario results using the fully integrated Canada-U.S. version of ReEDS to demonstrate model capabilities. The newly developed, integrated Canada-U.S. ReEDS model can be used to analyze the dynamics of electricity transfers and other grid services between the two countries under different scenarios.

  13. Table 11.5c Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Commercial and Industrial Sectors, 1989-2010 (Subset of Table 11.5a; Metric Tons of Gas)

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

    c Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Commercial and Industrial Sectors, 1989-2010 (Subset of Table 11.5a; Metric Tons of Gas) Year Carbon Dioxide 1 Sulfur Dioxide Nitrogen Oxides Coal 2 Natural Gas 3 Petroleum 4 Geo- thermal 5 Non- Biomass Waste 6 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total Commercial Sector 8<//td> 1989 2,319,630 1,542,083 637,423 [ –] 803,754 5,302,890 37,398 4

  14. Brazil-GTZ Renewable Energy and Energy Efficiency Programme ...

    Open Energy Info (EERE)

    are also being conducted on behalf of the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU): The 1000 Roofs Project supports the spread of...

  15. Micropower | Open Energy Information

    Open Energy Info (EERE)

    search Name: Micropower Place: Italy Sector: Biomass, Solar, Wind energy Product: Italian firm operating in the wind energy, solar energy, biomass and biogas sectors. The...

  16. CLEAN Inventory | Open Energy Information

    Open Energy Info (EERE)

    Union (EU) United Nations Development Programme (UNDP) Nature Conservation and Nuclear Safety (BMU) Australian Agency for International Development (AusAID) Argentina...

  17. Public Sector Energy Efficiency Programs

    Broader source: Energy.gov [DOE]

    The program is available to local, state, and federal governments; public school districts; community colleges; and universities that receive electricity and natural gas distribution service from...

  18. Vision Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Vision Energy Place: Cincinnati, Ohio Zip: 45227 Sector: Wind energy Product: Vision Energy focuses on wind energy development and...

  19. Helium Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Helium Energy Place: Spain Sector: Renewable Energy Product: Spain-based renewable energy development company. References: Helium Energy1...

  20. Semplice Energy | Open Energy Information

    Open Energy Info (EERE)

    Semplice Energy Jump to: navigation, search Name: Semplice Energy Place: Reading, United Kingdom Sector: Efficiency, Renewable Energy Product: Semplice Energy is an energy...

  1. Best Energy | Open Energy Information

    Open Energy Info (EERE)

    Best Energy Place: Italy Sector: Renewable Energy Product: Italy-based energy company engaged in the development of renewable energy projects. References: Best Energy1 This...

  2. Vice President Biden Announces New Private Sector Backing for Five

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

    Pioneering Energy Companies | Department of Energy New Private Sector Backing for Five Pioneering Energy Companies Vice President Biden Announces New Private Sector Backing for Five Pioneering Energy Companies August 30, 2011 - 6:12pm Addthis WASHINGTON, D.C. - Speaking at the National Clean Energy Summit 4.0 today in Las Vegas, Nevada, Vice President Joe Biden announced another promising milestone for the Department of Energy's Advanced Research Projects Agency-Energy (ARPA-E): five

  3. Fact #619: April 19, 2010 Transportation Sector Revenue by Industry |

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

    Department of Energy 9: April 19, 2010 Transportation Sector Revenue by Industry Fact #619: April 19, 2010 Transportation Sector Revenue by Industry According the latest Economic Census (2002), the trucking industry is the largest contributor of revenue in the transportation sector, contributing more than one-quarter of the sectors revenue. The air industry contributes just under one-quarter, as does other transportation and support activities, which include sightseeing, couriers and

  4. Designing Effective State Programs for the Industrial Sector - New SEE

    Office of Environmental Management (EM)

    Action Publication | Department of Energy Designing Effective State Programs for the Industrial Sector - New SEE Action Publication Designing Effective State Programs for the Industrial Sector - New SEE Action Publication March 24, 2014 - 12:56pm Addthis Industrial Energy Efficiency: Designing Effective State Programs for the Industrial Sector provides state regulators, utilities, and other program administrators with an overview of U.S. industrial energy efficiency programs delivered by a

  5. Policies to Spur Energy Access. Executive Summary; Volume 1, Engaging the Private Sector in Expanding Access to Electricity; Volume 2, Case Studies to Public-Private Models to Finance Decentralized Electricity Access

    SciTech Connect (OSTI)

    Walters, Terri; Rai, Neha; Esterly, Sean; Cox, Sadie; Reber, Tim; Muzammil, Maliha; Mahmood, Tasfiq; Kaur, Nanki; Tesfaye, Lidya; Mamuye, Simret; Knuckles, James; Morris, Ellen; de Been, Merijn; Steinbach, Dave; Acharya, Sunil; Chhetri, Raju Pandit; Bhushal, Ramesh

    2015-09-01

    Government policy is one of the most important factors in engaging the private sector in providing universal access to electricity. In particular, the private sector is well positioned to provide decentralized electricity products and services. While policy uncertainty and regulatory barriers can keep enterprises and investors from engaging in the market, targeted policies can create opportunities to leverage private investment and skills to expand electricity access. However, creating a sustainable market requires policies beyond traditional electricity regulation. The report reviews the range of policy issues that impact the development and expansion of a market for decentralized electricity services from establishing an enabling policy environment to catalyzing finance, building human capacity, and integrating energy access with development programs. The case studies in this report show that robust policy frameworks--addressing a wide range of market issues--can lead to rapid transformation in energy access. The report highlights examples of these policies in action Bangladesh, Ethiopia, Mali, Mexico, and Nepal.

  6. Foro Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Place: Littleton, Colorado Sector: Geothermal energy Product: Colorado-based startup developing hybrid thermalmechanical geothermal drilling technology. Coordinates:...

  7. Assess institutional frameworks for LEDS for land-use sector...

    Open Energy Info (EERE)

    Energy in Low Income Countries (SREP) Nepal-Sectoral Climate Impacts Economic Assessment Nepal-UNEP Green Economy Advisory Services Nicaragua-Joint Programme on Resource...

  8. Indonesia-NAMA Programme for the Construction Sector in Asia...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Low emission development planning, -LEDS, -NAMA, Market...

  9. Thailand-NAMA Programme for the Construction Sector in Asia ...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Low emission development planning, -LEDS, -NAMA, Market...

  10. Philippines-NAMA Programme for the Construction Sector in Asia...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Low emission development planning, -LEDS, -NAMA, Market...

  11. Vietnam-NAMA Programme for the Construction Sector in Asia |...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Low emission development planning, -LEDS, -NAMA, Market...

  12. Malaysia-NAMA Programme for the Construction Sector in Asia ...

    Open Energy Info (EERE)

    United Nations Environment Programme (UNEP) Sector Climate Focus Area Renewable Energy, Buildings, Industry Topics Low emission development planning, -LEDS, -NAMA, Market...

  13. The Greenhouse Gas Protocol Initiative: Sector Specific Tools...

    Open Energy Info (EERE)

    World Resources Institute, World Business Council for Sustainable Development Sector: Energy, Climate Focus Area: Industry, Greenhouse Gas Phase: Determine Baseline, Evaluate...

  14. Summit County - Energy Smart Colorado Renewable Energy Rebate...

    Open Energy Info (EERE)

    Rebate Program Applicable Sector Residential Eligible Technologies Solar Water Heat, Photovoltaics Active Incentive Yes Implementing Sector Local Energy Category Renewable...

  15. Lake County - Energy Smart Colorado Renewable Energy Rebate Program...

    Open Energy Info (EERE)

    Rebate Program Applicable Sector Residential Eligible Technologies Solar Water Heat, Photovoltaics Active Incentive Yes Implementing Sector Local Energy Category Renewable...

  16. Chemical Sector Analysis | NISAC

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    NISACChemical Sector Analysis content top Chemical Supply Chain Analysis Posted by Admin on Mar 1, 2012 in | Comments 0 comments Chemical Supply Chain Analysis NISAC has developed a range of capabilities for analyzing the consequences of disruptions to the chemical manufacturing industry. Each capability provides a different but complementary perspective on the questions of interest-questions like Given an event, will the entire chemical sector be impacted or just parts? Which chemicals, plants,

  17. Land Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Land Energy Place: North Yorkshire, United Kingdom Zip: YO62 5DQ Sector: Biomass, Renewable Energy Product: A renewable-energy company...

  18. Conexia Energy | Open Energy Information

    Open Energy Info (EERE)

    Conexia Energy Jump to: navigation, search Name: Conexia Energy Place: Aix-en-Provence, France Zip: 13857 Sector: Renewable Energy Product: French renewable energy consulting and...

  19. Raz Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Raz Energy Place: Carolles, France Zip: 50740 Sector: Renewable Energy Product: Carolles-based renewable energy consultancy and project...

  20. JMB Energie | Open Energy Information

    Open Energy Info (EERE)

    Jump to: navigation, search Name: JMB Energie Place: Marseilles, France Sector: Solar, Wind energy Product: JMB Energie is producer of green energy primarily through the...

  1. Energy Insight | Open Energy Information

    Open Energy Info (EERE)

    Energy Insight Jump to: navigation, search Tool Summary LAUNCH TOOL Name: Energy Insight AgencyCompany Organization: Tendril Connect Sector: Energy Focus Area: Energy Efficiency...

  2. Nature Energie | Open Energy Information

    Open Energy Info (EERE)

    Nature Energie Jump to: navigation, search Name: Nature Energie Place: France Sector: Solar, Wind energy Product: French developer of wind and solar energy projects. References:...

  3. EVZA Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: EVZA Energy Place: Germany Sector: Renewable Energy Product: Waste disposal comapany involved with renewable energy in the form of...

  4. Simple Energy | Open Energy Information

    Open Energy Info (EERE)

    Summary LAUNCH TOOL Name: Simple Energy AgencyCompany Organization: Simple Energy Sector: Energy Focus Area: Energy Efficiency Resource Type: Softwaremodeling tools User...

  5. Modeling the Integrated Expansion of the Canadian and U.S. Power Sectors with the Regional Energy Deployment System (ReEDS)

    SciTech Connect (OSTI)

    Zinaman, Owen; Ibanez, Eduardo; Heimiller, Donna; Eurek, Kelly; Mai, Trieu

    2015-07-02

    This document describes the development effort for creating a robust representation of the combined capacity expansion of the U.S. and Canadian electric sectors within the NREL ReEDS model. Thereafter, it demonstrates the newly established capability through an illustrative sensitivity analysis. In conducting the sensitivity analysis, we describe the value of an integrated modeling approach.

  6. RenewableEnergyStocks com | Open Energy Information

    Open Energy Info (EERE)

    Place: Washington State Sector: Renewable Energy Product: Investor and industry portal for the renewable energy sector. References: RenewableEnergyStocks.com1 This article...

  7. Workforce Training for the Electric Power Sector: Awards | Department of

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

    Energy Awards Workforce Training for the Electric Power Sector: Awards List of Workforce Training Awards for the Electric Power Sector under the American Recovery and Reinvestment Act organized by state, including, city, recipients, type of project, description, location, Department of Energy funding, and total project cost. Updated November 10, 2011. PDF icon Workforce Development Awards 2011 11 10.pdf More Documents & Publications Workforce Training for the Electric Power Sector

  8. Transitioning the Transportation Sector: Exploring the Intersection of

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

    Hydrogen Fuel Cell and Natural Gas Vehicles | Department of Energy Transitioning the Transportation Sector: Exploring the Intersection of Hydrogen Fuel Cell and Natural Gas Vehicles Transitioning the Transportation Sector: Exploring the Intersection of Hydrogen Fuel Cell and Natural Gas Vehicles Sandia National Laboratories, the American Gas Association, and Toyota, in support of the U.S. Department of Energy (DOE), held the Transitioning the Transportation Sector: Exploring the Intersection

  9. UN-Energy-Measuring Energy Access | Open Energy Information

    Open Energy Info (EERE)

    Network (UN-Energy) Sector: Energy Focus Area: Renewable Energy, Non-renewable Energy Topics: Co-benefits assessment, - Energy Access Resource Type: Dataset, Maps Website:...

  10. Renewables and Sector Partnerships

    Broader source: Energy.gov [DOE]

    U.S. Department of Energy (DOE) Office of Energy Efficiency and Renewable Energy (EERE) Community Renewable Energy Success Stories Webinar series presentation by Susanna Sutherland, City of Knoxville, Tennessee, on financing solar energy systems.

  11. Table 11.5a Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Total (All Sectors), 1989-2010 (Sum of Tables 11.5b and 11.5c; Metric Tons of Gas)

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

    a Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Total (All Sectors), 1989-2010 (Sum of Tables 11.5b and 11.5c; Metric Tons of Gas) Year Carbon Dioxide 1 Sulfur Dioxide Nitrogen Oxides Coal 2 Natural Gas 3 Petroleum 4 Geo- thermal 5 Non- Biomass Waste 6 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total 1989 1,573,566,415 218,383,703 145,398,976 363,247 5,590,014 1,943,302,355 14,468,564 1,059 984,406

  12. Table 11.5b Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Electric Power Sector, 1989-2010 (Subset of Table 11.5a; Metric Tons of Gas)

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

    b Emissions From Energy Consumption for Electricity Generation and Useful Thermal Output: Electric Power Sector, 1989-2010 (Subset of Table 11.5a; Metric Tons of Gas) Year Carbon Dioxide 1 Sulfur Dioxide Nitrogen Oxides Coal 2 Natural Gas 3 Petroleum 4 Geo- thermal 5 Non- Biomass Waste 6 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total Coal 2 Natural Gas 3 Petroleum 4 Other 7 Total 1989 1,520,229,870 169,653,294 133,545,718 363,247 4,365,768 1,828,157,897 13,815,263 832 809,873 6,874

  13. Caithness Energy LLC | Open Energy Information

    Open Energy Info (EERE)

    New York, New York Zip: 10017 Sector: Geothermal energy, Renewable Energy, Solar, Wind energy Product: Caithness Energy is a renewable energy project developer, plant owner and...

  14. Advanced Renewable Energy | Open Energy Information

    Open Energy Info (EERE)

    Renewable Energy Jump to: navigation, search Name: Advanced Renewable Energy Place: Italy Sector: Biomass, Renewable Energy, Wind energy Product: Advanced Renewable Energy Ltd...

  15. Boreal Renewable Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Boreal Renewable Energy Place: Acton, Massachusetts Zip: 1720 Sector: Hydro, Renewable Energy, Solar, Wind energy Product: Renewable Energy...

  16. India's Integrated Energy Policy | Open Energy Information

    Open Energy Info (EERE)

    search Name India's Integrated Energy Policy AgencyCompany Organization Government of India Sector Energy Focus Area Conventional Energy, Energy Efficiency, Renewable Energy...

  17. EcoEnergy | Open Energy Information

    Open Energy Info (EERE)

    EcoEnergy Jump to: navigation, search Name: EcoEnergy Place: Beloit, Wisconsin Zip: 53511 Sector: Biomass, Renewable Energy, Wind energy Product: String representation "EcoEnergy...

  18. Distributed Generation System Characteristics and Costs in the Buildings Sector

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Distributed Generation System Characteristics and Costs in the Buildings Sector August 2013 Independent Statistics & Analysis www.eia.gov U.S. Department of Energy Washington, DC 20585 U.S. Energy Information Administration | Distributed Generation System Characteristics and Costs in the Buildings Sector i This report was prepared by the U.S. Energy Information Administration (EIA), the statistical and analytical agency within the U.S. Department of Energy. By law, EIA's data, analyses, and

  19. Universal Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Universal Energy Place: Nanjing, Jiangsu Province, China Sector: Solar Product: Universal Energy is a PV module and solar hot water systems...

  20. Natec Energy | Open Energy Information

    Open Energy Info (EERE)

    Natec Energy Jump to: navigation, search Name: Natec Energy Place: Madrid, Spain Zip: 28015 Sector: Solar Product: Solar system developer and supplier, Natec Energy is active in...

  1. Proark Energy | Open Energy Information

    Open Energy Info (EERE)

    Proark Energy Place: Copenhagen, Denmark Zip: 1370 Sector: Renewable Energy, Solar, Wind energy Product: Copenhagen-based management company owned by Proark - the Danish real...

  2. Akis Energy | Open Energy Information

    Open Energy Info (EERE)

    Jump to: navigation, search Name: Akis Energy Place: Istanbul, Turkey Sector: Solar, Wind energy Product: Istanbul-based energy division of the Akis Group and developer of...

  3. ENECO Energie | Open Energy Information

    Open Energy Info (EERE)

    Place: Rotterdam, Netherlands Zip: 3000 CL Sector: Biomass, Renewable Energy, Solar, Wind energy Product: Dutch-based energy company that transports, produces, trades and sells...

  4. Plymouth Energy | Open Energy Information

    Open Energy Info (EERE)

    New Hampshire Zip: 3245 Sector: Renewable Energy Product: A local initiative to encourage energy conservation and promote the use of renewable energies. Coordinates: 43.725544,...

  5. Dezentrale Energie | Open Energy Information

    Open Energy Info (EERE)

    Dezentrale Energie Jump to: navigation, search Name: Dezentrale Energie Place: Neustadt a. Rbge., Germany Zip: D-31535 Sector: Wind energy Product: Wind power developer....

  6. Tigo Energy | Open Energy Information

    Open Energy Info (EERE)

    Tigo Energy Jump to: navigation, search Name: Tigo Energy Place: Los Gatos, California Zip: 95032 Sector: Solar Product: Tigo Energy builds hardware and software intelligence into...

  7. Positive Energy | Open Energy Information

    Open Energy Info (EERE)

    Positive Energy Name: Positive Energy Address: 3201 Calle Marie Place: Santa Fe, New Mexico Zip: 87507 Sector: Solar Product: Renewable energy products and services Phone Number:...

  8. Valence Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Valence Energy Place: Santa Clara, California Zip: 95050 Sector: Services Product: California-based energy management software and services...

  9. Tioga Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Logo: Tioga Energy Name: Tioga Energy Address: 2755 Campus Drive Place: San Mateo, California Zip: 94403 Region: Bay Area Sector: Solar Product:...

  10. Tenax Energy | Open Energy Information

    Open Energy Info (EERE)

    navigation, search Logo: Tenax Energy Name: Tenax Energy Place: Darwin, NT Country: Australia Zip: 0801 Sector: Marine and Hydrokinetic, Ocean, Renewable Energy Year Founded:...

  11. Forth Energy | Open Energy Information

    Open Energy Info (EERE)

    search Name: Forth Energy Place: United Kingdom Sector: Renewable Energy Product: Joint venture between SSE and Forth Ports to develop renewable energy at ports around the...

  12. Todd Energy | Open Energy Information

    Open Energy Info (EERE)

    Jump to: navigation, search Name: Todd Energy Place: New Zealand Sector: Renewable Energy Product: New Zealand energy company with operations in exploration, production and...

  13. Bryte Energy | Open Energy Information

    Open Energy Info (EERE)

    Name: Bryte Energy Place: Leicestershire, United Kingdom Zip: LE3 0QP Sector: Hydro, Hydrogen, Renewable Energy, Services Product: Bryte Energy Ltd provides consultancy services...

  14. Winkra Energie | Open Energy Information

    Open Energy Info (EERE)

    Winkra Energie Jump to: navigation, search Name: Winkra Energie Place: Hannover, Germany Zip: 30175 Sector: Wind energy Product: Hannover-based wind farm developer and operator,...

  15. Refex Energy | Open Energy Information

    Open Energy Info (EERE)

    Refex Energy Jump to: navigation, search Name: Refex Energy Place: Tamil Nadu, India Zip: 600017 Sector: Wind energy Product: Part of the refrigeration major Refex Group, plans to...

  16. Solydair Energies | Open Energy Information

    Open Energy Info (EERE)

    search Logo: Solydair Energies Name: Solydair Energies Address: Miraval Place: Les Thuiles Zip: 04400 Sector: Renewable Energy Product: Solar Evolution Year Founded: 2009...

  17. Dei Energy | Open Energy Information

    Open Energy Info (EERE)

    Place: Bulgaria Sector: Renewable Energy Product: Bulgarian utility engaged in renewable energy project development. References: Dei Energy1 This article is a stub. You can help...

  18. Energy Enterprises | Open Energy Information

    Open Energy Info (EERE)

    Energy Enterprises Place: Mays Landing, New Jersey Zip: 8330 Sector: Solar Product: Energy Enterprises is a licensed dealer, installer, and servicer of solar energy systems,...

  19. Colexon Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Colexon Energy Place: Hamburg, Hamburg, Germany Zip: 20354 Sector: Solar, Wind energy Product: Germany-based PV system integrator and solar...

  20. ENRO Energie | Open Energy Information

    Open Energy Info (EERE)

    Energie Jump to: navigation, search Name: ENRO Energie Place: Essen, Germany Zip: 45128 Sector: Geothermal energy Product: Germany-based company engaged in the design and...

  1. Sterling Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Sterling Energy Place: Capistrano Beach, California Zip: 92624 Sector: Renewable Energy, Services Product: String representation "Sterling...

  2. Bourne Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Logo: Bourne Energy Name: Bourne Energy Address: Box 2761 Place: Malibu, California Zip: 90265 Region: Southern CA Area Sector: Marine and...

  3. Workforce Training for the Electric Power Sector: Map of Projects |

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

    Department of Energy Map of Projects Workforce Training for the Electric Power Sector: Map of Projects Map showing the number of projects awarded in each State through the Workforce Training for the Electric Power Sector grants under the American Recovery and Reinvestment Act. PDF icon Workforce Training for the Electric Power Sector: Map of Projects More Documents & Publications Smart Grid Investment Grants: Map of Projects Developing and Enhancing Workforce Training Programs: Number of

  4. Energy Intensity Indicators: Manufacturing Energy Intensity

    Broader source: Energy.gov [DOE]

    The manufacturing sector comprises 18 industry sectors, generally defined at the three-digit level of the North American Industrial Classification System (NAICS). The manufacturing energy data...

  5. Sustainable Energy Technologies Ltd | Open Energy Information

    Open Energy Info (EERE)

    Zip: T2N 2A1 Sector: Solar, Wind energy Product: Canadian manufacturer of power inverters for solar, wind, fuel cells, and power storage sectors. References: Sustainable...

  6. BrightPath Energy LLC | Open Energy Information

    Open Energy Info (EERE)

    York Zip: 10011 Sector: Renewable Energy, Services Product: New York-based provider of project advisory and management services in the renewable energy sector. References:...

  7. Alternative Energy Consultants | Open Energy Information

    Open Energy Info (EERE)

    Consultants Jump to: navigation, search Name: Alternative Energy Consultants Place: Texas Sector: Biofuels, Renewable Energy Product: String representation "Alternative Ene ......

  8. LBNL International Energy Studies | Open Energy Information

    Open Energy Info (EERE)

    Lawrence Berkeley National Laboratory Sector Energy, Land Focus Area Energy Efficiency, Forestry Topics Implementation, GHG inventory, Policiesdeployment programs,...

  9. LBNL China Energy Group | Open Energy Information

    Open Energy Info (EERE)

    Organization Lawrence Berkeley National Laboratory Sector Energy Focus Area Energy Efficiency Topics Implementation, GHG inventory, Market analysis, Policiesdeployment programs,...

  10. EnergyPLAN | Open Energy Information

    Open Energy Info (EERE)

    Sustainable Energy Planning Research Group at Aalborg University Sector: Energy Topics: Market analysis, Pathways analysis, Policiesdeployment programs, Resource...

  11. Agrupacion Eolica | Open Energy Information

    Open Energy Info (EERE)

    Agrupacion Eolica Jump to: navigation, search Name: Agrupacion Eolica Place: Spain Sector: Wind energy Product: Agrupacin Elica operates in the wind energy sector in the...

  12. Ghana-Climate Finance Readiness Programme | Open Energy Information

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  13. El Salvador-Climate Finance Readiness Programme | Open Energy...

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  14. Benin-Climate Finance Readiness Programme | Open Energy Information

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  15. Nepal-Climate Finance Readiness Programme | Open Energy Information

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  16. Fiji-Climate Finance Readiness Programme | Open Energy Information

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  17. Colombia-Climate Finance Readiness Programme | Open Energy Information

    Open Energy Info (EERE)

    support from the German Federal Ministry for the Environment, Nature Conservation and Nuclear Safety (BMU). The Programme will prepare developing countries to effectively and...

  18. LEDSGP/about/Asia LEDS Partnership | Open Energy Information

    Open Energy Info (EERE)

    Capacity Building Programme (LECBP) United Nations Development Programme (UNDP) Nature Conservation and Nuclear Safety (BMU) The European Union (EU) German Federal Ministry...

  19. Mercury Energy formerly Aquus Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy formerly Aquus Energy Jump to: navigation, search Name: Mercury Energy (formerly Aquus Energy) Place: New Rochelle, New York Zip: 10801 Sector: Solar Product: Integrator of...

  20. CP Energy Group LLC CP Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Group LLC CP Energy Jump to: navigation, search Name: CP Energy Group, LLC (CP Energy) Place: Boston, Massachusetts Zip: 2108 Sector: Services Product: Boston-based merchant...

  1. Horizon Wind Energy formerly Zilkha Renewable Energy | Open Energy...

    Open Energy Info (EERE)

    Energy formerly Zilkha Renewable Energy Jump to: navigation, search Name: Horizon Wind Energy (formerly Zilkha Renewable Energy) Place: Houston, Texas Zip: 77002 Sector: Wind...

  2. Static Sankey Diagram of Onsite Generation in U.S. Manufacturing Sector |

    Energy Savers [EERE]

    Department of Energy Onsite Generation in U.S. Manufacturing Sector Static Sankey Diagram of Onsite Generation in U.S. Manufacturing Sector The Onsite Generation Static Sankey diagram shows how steam and electricity are generated by U.S. manufacturing plants. Click on the Full Sector, Process Energy, and Nonprocess Energy thumbnails below the diagram to see further detail on energy flows in manufacturing. Also, see the Dynamic Manufacturing Energy Sankey Tool to pan, zoom, and customize the

  3. NREL-Energy Assessment Training Course | Open Energy Information

    Open Energy Info (EERE)

    Company Organization: National Renewable Energy Laboratory Sector: Energy Focus Area: Energy Efficiency, Buildings Resource Type: Training materials Website:...

  4. Making the market right for environmentally sound energy-efficient technologies: US buildings sector successes that might work in developing countries and Eastern Europe

    SciTech Connect (OSTI)

    Gadgil, A.; Rosenfeld, A.H.; Price, L.

    1991-12-01

    Between 1973 and 1985, when energy prices were high, all Organization for Economic Cooperation and Development (OECD) countries improved their E/GNP by about 2.5% annually. Increased energy efficiency accounted for 2/3rds of this improvement; the remaining portion was due to structural changes in the economy. In the US, analytic and policy tools that have successfully promoted energy efficiency include integrated resource planning, energy use labels, energy use standards, ``Golden Carrot`` incentive programs, and revenue-neutral ``feebates.`` In addition, a number of low cost, environmentally sound, energy-efficient technologies, such as electronic ballasts, compact fluorescent lamps, and low-emissivity windows, have recently been developed. We discuss how many of these policies and technologies are probably exportable to developing countries and Eastern Europe, giving examples of successful starts in India, the ASEAN countries, and Brazil.

  5. Searching for Dark Sector

    Broader source: All U.S. Department of Energy (DOE) Office Webpages (Extended Search)

    Dark Sector Physics with MiniBooNE Georgia Karagiorgi, Columbia University On behalf of the MiniBooNE Collaboration 3 rd International Conference on New Frontiers in Physics August 6, 2014 MiniBooNE: Past & current highlights MiniBooNE, an accelerator-based neutrino experiment at Fermilab, has run for 10 years with neutrino and antineutrino beams, collecting data for ~2x10 21 POT, amounting to 100k's of neutrino interactions. It has been able to address the two-neutrino oscillation

  6. Sky Energy Inc | Open Energy Information

    Open Energy Info (EERE)

    Energy Inc Jump to: navigation, search Name: Sky Energy, Inc Place: Greenville, South Carolina Zip: 29607 Sector: Renewable Energy, Wind energy Product: Sells renewable...

  7. Natural Currents Energy Group | Open Energy Information

    Open Energy Info (EERE)

    Natural Currents Energy Group Jump to: navigation, search Name: Natural Currents Energy Group Place: New York Sector: Hydro, Ocean, Renewable Energy, Solar, Wind energy Product:...

  8. California Energy Power | Open Energy Information

    Open Energy Info (EERE)

    Power Jump to: navigation, search Name: California Energy & Power Place: Pomona, California Zip: CA 91767 Sector: Renewable Energy, Wind energy Product: California Energy & Power...

  9. Generation Energy Inc | Open Energy Information

    Open Energy Info (EERE)

    Generation Energy Inc Jump to: navigation, search Name: Generation Energy, Inc. Place: Sterling, Virginia Zip: 20166 Sector: Renewable Energy, Wind energy Product: Generation...

  10. Brayton Energy LLC | Open Energy Information

    Open Energy Info (EERE)

    Brayton Energy LLC Jump to: navigation, search Name: Brayton Energy LLC Place: Hampton, New Hampshire Zip: 3842 Sector: Renewable Energy Product: Brayton Energy was established in...

  11. Pangea Green Energy | Open Energy Information

    Open Energy Info (EERE)

    Pangea Green Energy Jump to: navigation, search Name: Pangea Green Energy Place: Torino, Italy Zip: 101280 Sector: Renewable Energy Product: Renewable energy project developer...

  12. Brasil Green Energy | Open Energy Information

    Open Energy Info (EERE)

    Energy Jump to: navigation, search Name: Brasil Green Energy Place: Brazil Sector: Renewable Energy Product: Brazilian-based company which seeks renewable energy investment...

  13. Pioneer Green Energy | Open Energy Information

    Open Energy Info (EERE)

    Green Energy Jump to: navigation, search Name: Pioneer Green Energy Place: Austin, Texas Sector: Renewable Energy, Solar, Wind energy Product: String representation "Pioneer Green...

  14. Solar Home Energy | Open Energy Information

    Open Energy Info (EERE)

    Home Energy Jump to: navigation, search Name: Solar Home Energy Place: Bournemouth, United Kingdom Sector: Renewable Energy, Solar Product: Solar Home Energy is one of the...

  15. EOL Energy Ltda | Open Energy Information

    Open Energy Info (EERE)

    EOL Energy Ltda Jump to: navigation, search Name: EOL Energy Ltda Place: Brazil Sector: Wind energy Product: Brazil based wind project developer. References: EOL Energy Ltda1...

  16. Higher Power Energy LLC | Open Energy Information

    Open Energy Info (EERE)

    Higher Power Energy LLC Jump to: navigation, search Name: Higher Power Energy, LLC Place: Flower Mound, Texas Zip: 78028 Sector: Renewable Energy, Wind energy Product: Higher Power...

  17. Jasper Energy LLC | Open Energy Information

    Open Energy Info (EERE)

    Jasper Energy LLC Place: Harrison, New York Zip: 10528 Sector: Renewable Energy, Solar, Wind energy Product: String representation "Jasper Energy L ... greenpower)." is too...

  18. Clean Energy Solutions Center | Open Energy Information

    Open Energy Info (EERE)

    Center Jump to: navigation, search Logo: Clean Energy Solutions Center Name Clean Energy Solutions Center AgencyCompany Organization Clean Energy Ministerial Sector Energy Focus...

  19. Cleantech Energies Ltd | Open Energy Information

    Open Energy Info (EERE)

    Energies Ltd Place: United Kingdom Sector: Renewable Energy Product: A renewable energy fund. Formally Star Asset Management. References: Cleantech Energies Ltd1 This...

  20. Green Star Alternative Energy | Open Energy Information

    Open Energy Info (EERE)

    Alternative Energy Jump to: navigation, search Name: Green Star Alternative Energy Place: San Diego, California Zip: 92108 Sector: Wind energy Product: A US-based wind energy...