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


1

Vehicle Technologies Office: Batteries  

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

Batteries to someone by Batteries to someone by E-mail Share Vehicle Technologies Office: Batteries on Facebook Tweet about Vehicle Technologies Office: Batteries on Twitter Bookmark Vehicle Technologies Office: Batteries on Google Bookmark Vehicle Technologies Office: Batteries on Delicious Rank Vehicle Technologies Office: Batteries on Digg Find More places to share Vehicle Technologies Office: Batteries on AddThis.com... Just the Basics Hybrid & Vehicle Systems Energy Storage Batteries Battery Systems Applied Battery Research Long-Term Exploratory Research Ultracapacitors Advanced Power Electronics & Electrical Machines Advanced Combustion Engines Fuels & Lubricants Materials Technologies Batteries battery/cell diagram Battery/Cell Diagram Batteries are important to our everyday lives and show up in various

2

Vehicle Technologies Office: Batteries  

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

Improving the batteries for electric drive vehicles, including hybrid electric (HEV) and plug-in electric (PEV) vehicles, is key to improving vehicles' economic, social, and environmental...

3

Vehicle Technologies Office: Batteries  

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

Batteries Batteries battery/cell diagram Battery/Cell Diagram Batteries are important to our everyday lives and show up in various consumer electronics and appliances, from MP3 players to laptops to our vehicles. Batteries play an important role in our vehicles and are gradually becoming more and more important as they assume energy storage responsibilities from fuel in vehicle propulsion systems. A battery is a device that stores chemical energy in its active materials and converts it, on demand, into electrical energy by means of an electrochemical reaction. An electrochemical reaction is a chemical reaction involving the transfer of electrons, and it is that reaction which creates electricity. There are three main parts of a battery: the anode, cathode, and electrolyte. The anode is the "fuel" electrode which gives up electrons to the external circuit to create the flow of electrons or electricity. The cathode is the oxidizing electrode which accepts electrons in the external circuit. Finally, the electrolyte carries the electric current, as ions, inside the cell, between the anode and cathode.

4

Johnson Controls Develops an Improved Vehicle Battery, Works...  

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

Johnson Controls Develops an Improved Vehicle Battery, Works to Cut Battery Costs in Half Johnson Controls Develops an Improved Vehicle Battery, Works to Cut Battery Costs in Half...

5

Vehicle Battery Basics | Department of Energy  

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

Vehicle Battery Basics Vehicle Battery Basics Vehicle Battery Basics November 22, 2013 - 1:58pm Addthis Batteries are essential for electric drive technologies such as hybrid electric vehicles (HEVs), plug-in hybrid electric vehicles (PHEVs), and all-electric vehicles (AEVs). What is a Battery? A battery is a device that stores chemical energy and converts it on demand into electrical energy. It carries out this process through an electrochemical reaction, which is a chemical reaction involving the transfer of electrons. Batteries have three main parts, each of which plays a different role in the electrochemical reaction: the anode, cathode, and electrolyte. The anode is the "fuel" electrode (or "negative" part), which gives up electrons to the external circuit to create a flow of electrons, otherwise

6

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

RR0DF106791 RR0DF106791 Hybrid Propulsion System: Mild Parallel Belt-Alternator Starter (BAS) Number of Electric Machines: 1 Motor: 15 kW (peak), AC induction Battery Specifications Manufacturer: Hitachi Type: Cylindrical Lithium-ion Number of Cells: 32 Nominal Cell Voltage: 3.6 V Nominal System Voltage: 115.2 V Rated Pack Capacity: 4.4 Ah Maximum Cell Charge Voltage 2 : 4.10 V Minimum Cell Discharge Voltage 2 : 3.00 V Thermal Management: Active - Forced air Pack Weight: 65 lb BEGINNING-OF-TEST: BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle Odometer: 5,715 mi Date of Test: January 8, 2013 Static Capacity Test Measured Average Capacity: 3.98 Ah Measured Average Energy Capacity: 460 Wh HPPC Test Pulse Discharge Power @ 50% DOD

7

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

RRXDF106605 RRXDF106605 Hybrid Propulsion System: Mild Parallel Belt-Alternator Starter (BAS) Number of Electric Machines: 1 Motor: 15 kW (peak), AC induction Battery Specifications Manufacturer: Hitachi Type: Cylindrical Lithium-ion Number of Cells: 32 Nominal Cell Voltage: 3.6 V Nominal System Voltage: 115.2 V Rated Pack Capacity: 4.4 Ah Maximum Cell Charge Voltage 2 : 4.10 V Minimum Cell Discharge Voltage 2 : 3.00 V Thermal Management: Active - Forced air Pack Weight: 65 lb BEGINNING-OF-TEST: BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle Odometer: 4,244 mi Date of Test: January 9, 2013 Static Capacity Test Measured Average Capacity: 3.88 Ah Measured Average Energy Capacity: 450 Wh HPPC Test Pulse Discharge Power @ 50% DOD

8

Vehicle Technologies Office: Exploratory Battery Materials Research  

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

Lowering the cost and improving the performance of batteries for plug-in electric vehicles requires improving every part of the battery, from underlying chemistry to packaging. To reach the EV...

9

Vehicle Technologies Office: Advanced Battery Development, System...  

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

learn how batteries are used in plug-in electric vehicles, visit the Alternative Fuels Data Center's page on batteries. Through the USABC, VTO supports a variety of research,...

10

US advanced battery consortium in-vehicle battery testing procedure  

SciTech Connect

This article describes test procedures to be used as part of a program to monitor the performance of batteries used in electric vehicle applications. The data will be collected as part of an electric vehicle testing program, which will include battery packs from a number of different suppliers. Most data will be collected by on-board systems or from driver logs. The paper describes the test procedure to be implemented for batteries being used in this testing.

NONE

1997-03-01T23:59:59.000Z

11

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles...  

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

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles High-Voltage Solid Polymer Batteries for Electric Drive Vehicles 2013 DOE Hydrogen and Fuel Cells Program and...

12

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles...  

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

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles High-Voltage Solid Polymer Batteries for Electric Drive Vehicles 2012 DOE Hydrogen and Fuel Cells Program and...

13

Computer-Aided Engineering for Electric Drive Vehicle Batteries...  

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

Computer-Aided Engineering for Electric Drive Vehicle Batteries (CAEBAT) Computer-Aided Engineering for Electric Drive Vehicle Batteries (CAEBAT) 2011 DOE Hydrogen and Fuel Cells...

14

Battery control system for hybrid vehicle and method for controlling a hybrid vehicle battery  

DOE Patents (OSTI)

A battery control system for controlling a state of charge of a hybrid vehicle battery includes a detecting arrangement for determining a vehicle operating state or an intended vehicle operating state and a controller for setting a target state of charge level of the battery based on the vehicle operating state or the intended vehicle operating state. The controller is operable to set a target state of charge level at a first level during a mobile vehicle operating state and at a second level during a stationary vehicle operating state or in anticipation of the vehicle operating in the stationary vehicle operating state. The invention further includes a method for controlling a state of charge of a hybrid vehicle battery.

Bockelmann, Thomas R. (Battle Creek, MI); Beaty, Kevin D. (Kalamazoo, MI); Zou, Zhanijang (Battle Creek, MI); Kang, Xiaosong (Battle Creek, MI)

2009-07-21T23:59:59.000Z

15

Advanced batteries for electric vehicle applications  

SciTech Connect

A technology assessment is given for electric batteries with potential for use in electric powered vehicles. Parameters considered include: specific energy, specific power, energy density, power density, cycle life, service life, recharge time, and selling price. Near term batteries include: nickel/cadmium and lead-acid batteries. Mid term batteries include: sodium/sulfur, sodium/nickel chloride, nickel/metal hydride, zinc/air, zinc/bromine, and nickel/iron systems. Long term batteries include: lithium/iron disulfide and lithium- polymer systems. Performance and life testing data for these systems are discussed. (GHH)

Henriksen, G.L.

1993-08-01T23:59:59.000Z

16

Vehicle Technologies Office: Applied Battery Research  

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

Applied battery research addresses the barriers facing the lithium-ion systems that are closest to meeting the technical energy and power requirements for hybrid electric vehicle (HEV) and electric...

17

Learning Policies For Battery Usage Optimization in Electric Vehicles  

E-Print Network (OSTI)

algorithmic chal- lenge. 1 Introduction Electric vehicles, partially or fully powered by batteries, are oneLearning Policies For Battery Usage Optimization in Electric Vehicles Stefano Ermon, Yexiang Xue for the widespread adoption of electric vehicles. Multi-battery systems that combine a standard battery

Bejerano, Gill

18

Johnson Controls Develops an Improved Vehicle Battery, Works to Cut Battery Costs in Half  

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

Johnson Controls is working to increase energy density of vehicle batteries while reducing manufacturing costs for lithium-ion battery cells.

19

Vehicle Technologies Office: Advanced Battery Development, System Analysis, and Testing  

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

To develop better lithium-ion (Li-ion) batteries for plug-in electric vehicles, researchers must integrate the advances made in exploratory battery materials and applied battery research into full...

20

Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Vehicle Battery and Vehicle Battery and Engine Research Tax Credits to someone by E-mail Share Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on Facebook Tweet about Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on Twitter Bookmark Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on Google Bookmark Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on Delicious Rank Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on Digg Find More places to share Alternative Fuels Data Center: Vehicle Battery and Engine Research Tax Credits on AddThis.com... More in this section... Federal State Advanced Search All Laws & Incentives Sorted by Type

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


21

Thermal Batteries for Electric Vehicles  

SciTech Connect

HEATS Project: UT Austin will demonstrate a high-energy density and low-cost thermal storage system that will provide efficient cabin heating and cooling for EVs. Compared to existing HVAC systems powered by electric batteries in EVs, the innovative hot-and-cold thermal batteries-based technology is expected to decrease the manufacturing cost and increase the driving range of next-generation EVs. These thermal batteries can be charged with off-peak electric power together with the electric batteries. Based on innovations in composite materials offering twice the energy density of ice and 10 times the thermal conductivity of water, these thermal batteries are expected to achieve a comparable energy density at 25% of the cost of electric batteries. Moreover, because UT Austin’s thermal energy storage systems are modular, they may be incorporated into the heating and cooling systems in buildings, providing further energy efficiencies and positively impacting the emissions of current building heating/cooling systems.

None

2011-11-21T23:59:59.000Z

22

Fact #823: June 2, 2014 Hybrid Vehicles use more Battery Packs but Plug-in Vehicles use More Battery Capacity  

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

Of the battery packs used for electrified vehicle powertrains in model year 2013, the greatest number went into conventional hybrid vehicles which use battery packs that average about 1.3 kilowatt...

23

2011 Hyundai Sonata 3539 - Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy’s Advanced Vehicle Testing Activity Program consists of vehicle, battery, and infrastructure testing on advanced technology related to transportation. The activity includes tests on hybrid electric vehicles, including testing hybrid electric vehicle batteries when both the vehicles and batteries are new and at the conclusion of 160,000 miles of on-road fleet testing. This report documents battery testing performed for the 2011 Hyundai Sonata Hybrid (VIN KMHEC4A47BA003539). Battery testing was performed by Intertek Testing Services NA. The Idaho National Laboratory and Intertek collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Matthew Shirk; Tyler Gray; Jeffrey Wishart

2014-09-01T23:59:59.000Z

24

Vehicle Technologies Office Merit Review 2014: Battery Thermal Characterization  

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

Presentation given by NREL at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about battery thermal characterization.

25

Vehicle Technologies Office Merit Review 2014: Battery Safety Testing  

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

Presentation given by Sandia National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about battery safety...

26

NREL: Continuum Magazine - Electric Vehicle Battery Development Gains  

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

Electric Vehicle Battery Development Gains Momentum Electric Vehicle Battery Development Gains Momentum Issue 5 Print Version Share this resource Electric Vehicle Battery Development Gains Momentum CAEBAT collaboration targets EDV batteries with longer range and lifespan, at a lower cost. A photo of two men silhouetted in front of six back-lit display screens showing battery models, located in a dark room (22008). Enlarge image NREL's modeling, simulation, and testing activities include battery safety assessment, next-generation battery technologies, material synthesis and research, subsystem analysis, and battery second use studies. Photo by Dennis Schroeder, NREL "When people get behind the wheel of an electric car, it should be a great driving experience. Period." Dr. Taeyoung Han, GM technical fellow, said,

27

Advanced Vehicle Testing - Beginning-of-Test Battery Testing...  

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

2.5 V Thermal Mgmt.: Passive, Vacuum-Sealed Unit Pack Weight: 294 kg BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle Odometer: 6,696 mi Date of...

28

Microsoft Word - Vehicle Battery EA_Pyrotek  

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

20 20 Environmental Assessment for Pyrotek, Inc. Electric Drive Vehicle Battery and Component Manufacturing Initiative Project, Sanborn, NY April 2010 Prepared for: Department of Energy National Energy Technology Laboratory Environmental Assessment DOE/EA-1720 Pyrotek, Incorporated, Sanborn, NY April 2010 National Environmental Policy Act (NEPA) Compliance Cover Sheet Proposed Action: The U.S. Department of Energy (DOE) proposes, through a cooperative agreement with Pyrotek, Incorporated (Pyrotek), to partially fund the construction of an industrial building; installation of electrically heated furnaces and other production equipment such as conveyors, collectors, screens, and cooling towers required to accomplish the proposed expansion of Pyrotek's graphitization process. The plant expansion would enable the manufacture

29

Battery electric vehicles, hydrogen fuel cells and biofuels. Which will  

E-Print Network (OSTI)

1 Battery electric vehicles, hydrogen fuel cells and biofuels. Which will be the winner? ICEPT considered are: improved internal combustion engine vehicles (ICEVs) powered by biofuels, battery electric. All three fuels considered (i.e.: biofuels, electricity and hydrogen) are in principle compatible

30

Costs of lithium-ion batteries for vehicles  

SciTech Connect

One of the most promising battery types under development for use in both pure electric and hybrid electric vehicles is the lithium-ion battery. These batteries are well on their way to meeting the challenging technical goals that have been set for vehicle batteries. However, they are still far from achieving the current cost goals. The Center for Transportation Research at Argonne National Laboratory undertook a project for the US Department of Energy to estimate the costs of lithium-ion batteries and to project how these costs might change over time, with the aid of research and development. Cost reductions could be expected as the result of material substitution, economies of scale in production, design improvements, and/or development of new material supplies. The most significant contributions to costs are found to be associated with battery materials. For the pure electric vehicle, the battery cost exceeds the cost goal of the US Advanced Battery Consortium by about $3,500, which is certainly enough to significantly affect the marketability of the vehicle. For the hybrid, however, the total cost of the battery is much smaller, exceeding the cost goal of the Partnership for a New Generation of Vehicles by only about $800, perhaps not enough to deter a potential buyer from purchasing the power-assist hybrid.

Gaines, L.; Cuenca, R.

2000-08-21T23:59:59.000Z

31

Reality Check: Cheaper Batteries are GOOD for America's Electric Vehicle  

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

Reality Check: Cheaper Batteries are GOOD for America's Electric Reality Check: Cheaper Batteries are GOOD for America's Electric Vehicle Manufacturers Reality Check: Cheaper Batteries are GOOD for America's Electric Vehicle Manufacturers September 16, 2011 - 11:05am Addthis Dan Leistikow Dan Leistikow Former Director, Office of Public Affairs Today's New York Times includes a story about loans the Department of Energy has issued for electric vehicle manufacturing. The story says that the price of advanced batteries for electric vehicles is rapidly declining. That's true. And it's also very good news, since it makes America more competitive. The story goes on to say that this price decline could hurt the electric vehicle manufacturers that the Department has extended loans to. That is not true. In fact, it's just the opposite. Think about it - cheaper

32

Computer-Aided Engineering for Electric Drive Vehicle Batteries (CAEBAT) (Presentation)  

SciTech Connect

This presentation describes NREL's computer aided engineering program for electric drive vehicle batteries.

Pesaran, A. A.

2011-05-01T23:59:59.000Z

33

Electric Vehicle Battery Testing: It's Hot Stuff! | Department of Energy  

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

Electric Vehicle Battery Testing: It's Hot Stuff! Electric Vehicle Battery Testing: It's Hot Stuff! Electric Vehicle Battery Testing: It's Hot Stuff! May 26, 2011 - 2:45pm Addthis NREL's Large-Volume Battery Calorimeter has the highest-capacity chamber in the world for testing of this kind. From bottom clockwise:NREL researchers Matthew Keyser, Dirk Long & John Ireland | Photo Courtesy of Dennis Schroeder NREL's Large-Volume Battery Calorimeter has the highest-capacity chamber in the world for testing of this kind. From bottom clockwise:NREL researchers Matthew Keyser, Dirk Long & John Ireland | Photo Courtesy of Dennis Schroeder Sarah LaMonaca Communications Specialist, Office of Energy Efficiency & Renewable Energy What does this mean for me? Increased performance and travel distance in future hybrid and

34

Battery Test Manual For Plug-In Hybrid Electric Vehicles  

SciTech Connect

This battery test procedure manual was prepared for the United States Department of Energy (DOE), Office of Energy Efficiency and Renewable Energy (EERE), Vehicle Technologies Program. It is based on technical targets established for energy storage development projects aimed at meeting system level DOE goals for Plug-in Hybrid Electric Vehicles (PHEV). The specific procedures defined in this manual support the performance and life characterization of advanced battery devices under development for PHEV’s. However, it does share some methods described in the previously published battery test manual for power-assist hybrid electric vehicles. Due to the complexity of some of the procedures and supporting analysis, a revision including some modifications and clarifications of these procedures is expected. As in previous battery and capacitor test manuals, this version of the manual defines testing methods for full-size battery systems, along with provisions for scaling these tests for modules, cells or other subscale level devices.

Jeffrey R. Belt

2010-12-01T23:59:59.000Z

35

Vehicle Technologies Office Merit Review 2014: Advanced Battery Recycling  

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

Presentation given by OnTo Technology LLC at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about advanced battery recycling.

36

Comparison of various battery technologies for electric vehicles  

E-Print Network (OSTI)

four technologies; Lead-Acid, Nickel-Cadmium, Nickel-Metal Hydride and Zinc-Bromide. A standard set of testing procedures for electric vehicle batteries, based on industry accepted testing procedures, and any tests which were specific to individual...

Dickinson, Blake Edward

1993-01-01T23:59:59.000Z

37

2010 Ford Fusion VIN 4757 Hybrid Electric Vehicle Battery Test...  

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

1 2010 Ford Fusion VIN 4757 Hybrid Electric Vehicle Battery Test Results Tyler Gray Matthew Shirk January 2013 The Idaho National Laboratory is a U.S. Department of Energy National...

38

2011 Hyundai Sonata 4932 - Hybrid Electric Vehicle Battery Test...  

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

9679 2011 Hyundai Sonata 4932 - Hybrid Electric Vehicle Battery Test Results Tyler Gray Matthew Shirk Jeffrey Wishart July 2013 The Idaho National Laboratory is a U.S. Department...

39

2010 Honda Insight VIN 1748 Hybrid Electric Vehicle Battery Test...  

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

3 2010 Honda Insight VIN 1748 Hybrid Electric Vehicle Battery Test Results Tyler Gray Matthew Shirk January 2013 The Idaho National Laboratory is a U.S. Department of Energy...

40

2010 Toyota Prius VIN 0462 Hybrid Electric Vehicle Battery Test...  

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

5 2010 Toyota Prius VIN 0462 Hybrid Electric Vehicle Battery Test Results Tyler Gray Matthew Shirk January 2013 The Idaho National Laboratory is a U.S. Department of Energy...

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


41

2010 Honda Insight VIN 0141 Hybrid Electric Vehicle Battery Test...  

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

2 2010 Honda Insight VIN 0141 Hybrid Electric Vehicle Battery Test Results Tyler Gray Mathew Shirk January 2013 The Idaho National Laboratory is a U.S. Department of Energy...

42

2010 Toyota Prius VIN 6063 Hybrid Electric Vehicle Battery Test...  

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

6 2010 Toyota Prius VIN 6063 Hybrid Electric Vehicle Battery Test Results Tyler Gray Matthew Shirk January 2013 The Idaho National Laboratory is a U.S. Department of Energy...

43

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles  

E-Print Network (OSTI)

i Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed more robust. This report analyzes V2G power from three types of EDVs--battery, hybrid, and fuel cell and prices are high. Fuel cell and hybrid EDVs are sources of new power generation. For economic reasons

Firestone, Jeremy

44

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles  

E-Print Network (OSTI)

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed, and fuel cell. Battery EDVs can store electricity, charging during low demand times and discharging when power is scarce and prices are high. Fuel cell and hybrid EDVs are sources of new power generation

Firestone, Jeremy

45

EA-1851: Delphi Automotive Systems Electric Drive Vehicle Battery and  

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

EA-1851: Delphi Automotive Systems Electric Drive Vehicle Battery EA-1851: Delphi Automotive Systems Electric Drive Vehicle Battery and Component Manufacturing Initiative EA-1851: Delphi Automotive Systems Electric Drive Vehicle Battery and Component Manufacturing Initiative Summary This EA evaluates the environmental impacts of a proposal to provide a financial assistance grant under the American Recovery and Reinvestment Act of 2009 (ARRA) to Delphi Automotive Systems, Limited Liability Corporation (LLC) (Delphi). Delphi proposes to construct a laboratory referred to as the "Delphi Kokomo, IN Corporate Technology Center" (Delphi CTC Project) and retrofit a manufacturing facility. The project would advance DOE's Vehicle Technology Program through manufacturing and testing of electric-drive vehicle components as well as assist in the

46

Hybrid Electric Vehicle Testing (Batteries and Fuel Economies)  

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

Energy Hybrid Electric Vehicle Energy Hybrid Electric Vehicle Battery and Fuel Economy Testing Donald Karner a , James Francfort b a Electric Transportation Applications 401 South 2nd Avenue, Phoenix, AZ 85003, USA b Idaho National Laboratory, P.O. Box 1625, Idaho Falls, ID 83415, USA Abstract The Advanced Vehicle Testing Activity (AVTA), part of the U.S. Department of Energy's FreedomCAR and Vehicle Technologies Program, has conducted testing of advanced technology vehicles since August, 1995 in support of the AVTA goal to provide benchmark data for technology modeling, and research and development programs. The AVTA has tested over 200 advanced technology vehicles including full size electric vehicles, urban electric vehicles, neighborhood electric vehicles, and hydrogen internal combustion engine powered vehicles.

47

Chemical Sciences and Engineering - US China Electric Vehicle and Battery  

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

Presentations Presentations View program in brief » View the Conference Booklet with program (pdf) » Plenary Sessions 4th US - China Electric Vehicle and Battery Technology Workshop, Dave Howell, US Department of Energy (pdf) U.S. Department of Energy Vehicle Technologies Program Overview, Henry Kelly, US DOE Energy Efficiency and Renewable Energy (pdf) EcoPartnerships: A model for US-China Energy Collaboration, David Fleshler, Case Western Reserve University and QIN Xingcai, Tianjin Lishen Battery Joint-Stock Co., Ltd. (pdf) Lishen Advanced Battery Development for EV and ESS, Qin Xingcai, Tianjin Lishen Battery Joint-Stock Co., Ltd. (pdf) EV R&D in CAERI, Xiaochang Ren, China Automotive Engineering Research Institute (pdf) Roundtable 1: Joint Battery Technology Roadmapping

48

Recycling Hybrid and Elecectric Vehicle Batteries  

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

2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation

49

A global analysis and market strategy in the electric vehicle battery industry  

E-Print Network (OSTI)

As use of electric vehicles has been expected to grow, the batteries for the electric vehicles have become critical because the batteries are a key part of the paradigm shift in the automotive industry. However, the demand ...

Kim, Young Hee, S.M. Massachusetts Institute of Technology

2014-01-01T23:59:59.000Z

50

NREL's Isothermal Battery Calorimeters are Crucial Tools for Advancing Electric-Drive Vehicles  

E-Print Network (OSTI)

NREL's Isothermal Battery Calorimeters are Crucial Tools for Advancing Electric-Drive Vehicles, and plug-in hybrids. But before more Americans switch to electric-drive vehicles, automakers need batteries to the safety and performance of electric-drive batteries. The innovative Isothermal Battery Calorimeters (IBCs

51

Vehicle Technologies Office: Plug-In Electric Vehicles and Batteries  

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

With their immense potential for increasing the country's energy, economic, and environmental security, plug-in electric vehicles (PEVs, including plug-in hybrid electric and all-electric) will...

52

A zinc-air battery and flywheel zero emission vehicle  

SciTech Connect

In response to the 1990 Clean Air Act, the California Air Resources Board (CARB) developed a compliance plan known as the Low Emission Vehicle Program. An integral part of that program was a sales mandate to the top seven automobile manufacturers requiring the percentage of Zero Emission Vehicles (ZEVs) sold in California to be 2% in 1998, 5% in 2001 and 10% by 2003. Currently available ZEV technology will probably not meet customer demand for range and moderate cost. A potential option to meet the CARB mandate is to use two Lawrence Livermore National Laboratory (LLNL) technologies, namely, zinc-air refuelable batteries (ZARBs) and electromechanical batteries (EMBs, i. e., flywheels) to develop a ZEV with a 384 kilometer (240 mile) urban range. This vehicle uses a 40 kW, 70 kWh ZARB for energy storage combined with a 102 kW, 0.5 kWh EMB for power peaking. These technologies are sufficiently near-term and cost-effective to plausibly be in production by the 1999-2001 time frame for stationary and initial vehicular applications. Unlike many other ZEVs currently being developed by industry, our proposed ZEV has range, acceleration, and size consistent with larger conventional passenger vehicles available today. Our life-cycle cost projections for this technology are lower than for Pb-acid battery ZEVs. We have used our Hybrid Vehicle Evaluation Code (HVEC) to simulate the performance of the vehicle and to size the various components. The use of conservative subsystem performance parameters and the resulting vehicle performance are discussed in detail.

Tokarz, F.; Smith, J.R.; Cooper, J.; Bender, D.; Aceves, S.

1995-10-03T23:59:59.000Z

53

Monitoring Battery System for Electric Vehicle, Based On "One Wire" Technology  

E-Print Network (OSTI)

Santiago, Chile jdixon@ing.puc.cl Abstract-- A monitoring system for a battery powered electric vehicle (EV- powered electric vehicles, the need for fast information related to different components and equipmentMonitoring Battery System for Electric Vehicle, Based On "One Wire" Technology Javier Ibáñez Vial

Catholic University of Chile (Universidad Católica de Chile)

54

Diagnostic Characterization of High-Power Lithium-Ion Batteries For Use in Hybrid Electric Vehicles  

E-Print Network (OSTI)

Diagnostic Characterization of High-Power Lithium-Ion Batteries For Use in Hybrid Electric Vehicles and electric vehicles due to their relatively high specific energy and specific power. The Advanced Technology of lithium-ion batteries for hybrid electric vehicle (HEV) applications. The ATD Program is a joint effort

55

Novel Latent Heat Storage Devices for Thermal Management of Electric Vehicle Battery Systems  

Science Journals Connector (OSTI)

A major aspect for safe and efficient operation of battery electric vehicles (BEV) is the thermal management of their battery systems. As temperature uniformity and level highly ... performance and the lifetime, ...

Ch. Huber; A. Jossen; R. Kuhn

2014-01-01T23:59:59.000Z

56

Heat transfer and thermal management of electric vehicle batteries with phase change materials  

Science Journals Connector (OSTI)

This paper examines a passive thermal management system for electric vehicle batteries, consisting of encapsulated phase change material ( ... process to absorb the heat generated by a battery. A new configuratio...

M. Y. Ramandi; I. Dincer; G. F. Naterer

2011-07-01T23:59:59.000Z

57

NREL Uses Fuel Cells to Increase the Range of Battery Electric Vehicles (Fact Sheet)  

SciTech Connect

NREL analysis identifies potential cost-effective scenarios for using small fuel cell power units to increase the range of medium-duty battery electric vehicles.

Not Available

2014-01-01T23:59:59.000Z

58

Second law analysis of a liquid cooled battery thermal management system for hybrid and electric vehicles.  

E-Print Network (OSTI)

??As hybrid and electric vehicles continue to evolve there is a need for better battery thermal management systems (BTMS), which maintain uniformity of operating temperature… (more)

Ramotar, Lokendra

2010-01-01T23:59:59.000Z

59

Nickel-Metal-Hydride Batterie--High Energy Storage for Electric Vehicles  

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

Freedomcar & Vehicle Technologies Program Freedomcar & Vehicle Technologies Program Nickel-Metal-Hydride Batteries - High Energy Storage for Electric Vehicles Background The key to making electric vehicles (EVs) practical is the development of batteries that can provide performance comparable with that of con ventional vehicles at a similar cost. Most EV batteries have limited energy storage capabili ties, permitting only relatively short driving distances before the batteries must be recharged. In 1991, under a coopera tive agreement with The U.S. Department of Energy (DOE), the United States Advanced Battery Consortium (USABC) initiated development of nickel- metal-hydride (NiMH) battery technology and established it as a prime mid-term candidate for use in EVs. DOE funding has been instru

60

NREL Reveals Links Among Climate Control, Battery Life, and Electric Vehicle Range (Fact Sheet)  

SciTech Connect

Researchers at the National Renewable Energy Laboratory (NREL) are providing new insights into the relationships between the climate-control systems of plug-in electric vehicles and the distances these vehicles can travel on a single charge. In particular, NREL research has determined that 'preconditioning' a vehicle-achieving a comfortable cabin temperature and preheating or precooling the battery while the vehicle is still plugged in-can extend its driving range and improve battery life over the long term.

Not Available

2012-06-01T23:59:59.000Z

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


61

U.S.-China Electric Vehicle and Battery Technology Workshop | Department of  

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

Electric Vehicle and Battery Technology Workshop Electric Vehicle and Battery Technology Workshop U.S.-China Electric Vehicle and Battery Technology Workshop August 31, 2010 - 2:52pm Addthis DOE's Office of Policy and International Affairs and China's Ministry of Science and Technology convened a 3-day workshop at Argonne National Laboratory that brought together more than 100 U.S. and Chinese experts from government, industry, and academia to discuss progress made in the electric vehicle industry to date and opportunities for increased collaboration. The workshop was held in support of the U.S.-China Electric Vehicles Initiative announced by President Obama and China's President Hu Jintao in 2009. Participants engaged in three concurrent roundtables on battery technology roadmapping, battery test procedures, and vehicle

62

2011 Honda CR-Z 4466 - Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy’s Advanced Vehicle Testing Activity Program consists of vehicle, battery, and infrastructure testing on advanced technology related to transportation. The activity includes tests on hybrid electric vehicles, including testing traction batteries when both the vehicles and batteries are new and at the conclusion of 160,000 miles of on-road fleet testing. This report documents battery testing performed for the 2011 Honda CR-Z (VIN JHMZF1C67BS004466). Battery testing was performed by Intertek Testing Services NA. The Idaho National Laboratory and Intertek collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Office of the U.S. Department of Energy.

Tyler Gray; Matthew Shirk; Jeffrey Wishart

2014-09-01T23:59:59.000Z

63

2011 HONDA CR-Z 2982 - HYBRID ELECTRIC VEHICLE BATTERY TEST RESULTS  

SciTech Connect

The U.S. Department of Energy’s Advanced Vehicle Testing Activity Program consists of vehicle, battery, and infrastructure testing on advanced technology related to transportation. The activity includes tests on hybrid electric vehicles, including testing traction batteries when both the vehicles and batteries are new and at the conclusion of 160,000 miles of on-road fleet testing. This report documents battery testing performed for the 2011 Honda CR-Z (VIN JHMZF1C64BS002982). Battery testing was performed by Intertek Testing Services NA. The Idaho National Laboratory and Intertek collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Office of the U.S. Department of Energy.

Gray, Tyler [Interek; Shirk, Matthew [Idaho National Laboratory; Wishart, Jeffrey [Interek

2014-09-01T23:59:59.000Z

64

Chemical Sciences and Engineering - US China Electric Vehicle and Battery  

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

Program Program View the Conference Booklet with program (pdf) » THURSDAY, AUGUST 4 Time Title, Speaker Plenary Session 9:00 AM Welcome and Orientation Welcome to Argonne by Eric Isaacs, Laboratory Director Orientation, Logistics and Workshop Format by Larry Johnson, Transportation Center Director 9:20 - 10:40 Technology Policy: US-China Collaboration on the Electric Vehicle Initiative Henry Kelly, USDOE Principal Deputy Assistant Secretary, Energy Efficiency and Renewable Energy ZHANG Zhihong, MOST, Deputy Director General, Department of New and High Technology WU Feng, Beijing Institute of Technology, Chief Scientist of National (973) Advance Secondary Battery Project Dave Howell, USDOE Vehicle Technologies Program, Team Lead, Hybrid Electric Systems 10:40 - 11:00 Tea/Coffee Break

65

Battery Utilization in Electric Vehicles: Theoretical Analysis and an Almost Optimal Online Algorithm  

E-Print Network (OSTI)

powered vehicles [Kirsch, 2000, Anderson and Anderson, 2010]. Electric Vehicles (EVs) are currentlyBattery Utilization in Electric Vehicles: Theoretical Analysis and an Almost Optimal Online n current demands in electric vehicles. When serving a demand, the current allocation might be split

Tamir, Tami

66

Fact #822: May 26, 2014 Battery Capacity Varies Widely for Plug-In Vehicles  

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

Battery-electric vehicles have capacities ranging from 12 kilowatt-hours (kWh) in the Scion iQ EV to 85 kWh in the Tesla Model S. Plug-in hybrid-electric vehicles typically have smaller battery...

67

A Multiphase Traction/Fast-Battery-Charger Drive for Electric or Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

A Multiphase Traction/Fast-Battery-Charger Drive for Electric or Plug-in Hybrid Vehicles Solutions on an original electric drive [1]-[3] dedicated to the vehicle traction and configurable as a battery charger concerning the electrical machine control. This paper deals with the control of this drive [1], focusing

Paris-Sud XI, Université de

68

VP 100: President Obama Hails Electric-Vehicle Battery Plant | Department  

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

VP 100: President Obama Hails Electric-Vehicle Battery Plant VP 100: President Obama Hails Electric-Vehicle Battery Plant VP 100: President Obama Hails Electric-Vehicle Battery Plant July 15, 2010 - 5:05pm Addthis Stephen Graff Former Writer & editor for Energy Empowers, EERE What does this project do? Puts the U.S. in position to produce 40 percent of the world's supply of advanced batteries by 2015 - up from it's current level of 2 percent Makes us less dependent on foreign oil Creates jobs in an emerging sector of manufacturing The electric-vehicle industry received more support Thursday when President Obama delivered remarks in Holland, Michigan, at the groundbreaking ceremony for an American Recovery and Reinvestment Act-funded battery cell plant. "This is about more than just building a new factory," President Obama told

69

VP 100: President Obama Hails Electric-Vehicle Battery Plant | Department  

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

President Obama Hails Electric-Vehicle Battery Plant President Obama Hails Electric-Vehicle Battery Plant VP 100: President Obama Hails Electric-Vehicle Battery Plant July 15, 2010 - 5:05pm Addthis Stephen Graff Former Writer & editor for Energy Empowers, EERE What does this project do? Puts the U.S. in position to produce 40 percent of the world's supply of advanced batteries by 2015 - up from it's current level of 2 percent Makes us less dependent on foreign oil Creates jobs in an emerging sector of manufacturing The electric-vehicle industry received more support Thursday when President Obama delivered remarks in Holland, Michigan, at the groundbreaking ceremony for an American Recovery and Reinvestment Act-funded battery cell plant. "This is about more than just building a new factory," President Obama told

70

Diagnostic Characterization of High Power Lithium-Ion Batteries for Use in Hybrid Electric Vehicles  

E-Print Network (OSTI)

Diagnostic Characterization of High Power Lithium-Ion Batteries for Use in Hybrid Electric Vehicles are a fast-growing technology that is attrac- tive for use in portable electronics and electric vehicles due electric vehicle HEV applications.c A baseline cell chemistry was identified as a carbon anode negative

71

FC/Battery Power Management for Electric Vehicle Based Interleaved dc-dc Boost Converter Topology  

E-Print Network (OSTI)

FC/Battery Power Management for Electric Vehicle Based Interleaved dc- dc Boost Converter Topology power systems in electric vehicle application, in order to decrease the FC current ripple. Therefore the performance of the FC system during transient and instantaneous peak power demands in electric vehicle

Paris-Sud XI, Université de

72

Batteries for electric drive vehicles: Evaluation of future characteristics and costs through a Delphi study  

SciTech Connect

Uncertainty about future costs and operating attributes of electric drive vehicles (EVs and HEVs) has contributed to considerable debate regarding the market viability of such vehicles. One way to deal with such uncertainty, common to most emerging technologies, is to pool the judgments of experts in the field. Data from a two-stage Delphi study are used to project the future costs and operating characteristics of electric drive vehicles. The experts projected basic vehicle characteristics for EVs and HEVs for the period 2000-2020. They projected the mean EV range at 179 km in 2000, 270 km in 2010, and 358 km in 2020. The mean HEV range on battery power was projected as 145 km in 2000, 212 km in 2010, and 244 km in 2020. Experts` opinions on 10 battery technologies are analyzed and characteristics of initial battery packs for the mean power requirements are presented. A procedure to compute the cost of replacement battery packs is described, and the resulting replacement costs are presented. Projected vehicle purchase prices and fuel and maintenance costs are also presented. The vehicle purchase price and curb weight predictions would be difficult to achieve with the mean battery characteristics. With the battery replacement costs added to the fuel and maintenance costs, the conventional ICE vehicle is projected to have a clear advantage over electric drive vehicles through the projection period.

Vyas, A.D.; Ng, H.K.; Anderson, J.L.; Santini, D.J.

1997-07-01T23:59:59.000Z

73

Life-cycle energy analyses of electric vehicle storage batteries. Final report  

SciTech Connect

The results of several life-cycle energy analyses of prospective electric vehicle batteries are presented. The batteries analyzed were: Nickel-zinc; Lead-acid; Nickel-iron; Zinc-chlorine; Sodium-sulfur (glass electrolyte); Sodium-sulfur (ceramic electrolyte); Lithium-metal sulfide; and Aluminum-air. A life-cycle energy analysis consists of evaluating the energy use of all phases of the battery's life, including the energy to build it, operate it, and any credits that may result from recycling of the materials in it. The analysis is based on the determination of three major energy components in the battery life cycle: Investment energy, i.e., The energy used to produce raw materials and to manufacture the battery; operational energy i.e., The energy consumed by the battery during its operational life. In the case of an electric vehicle battery, this energy is the energy required (as delivered to the vehicle's charging circuit) to power the vehicle for 100,000 miles; and recycling credit, i.e., The energy that could be saved from the recycling of battery materials into new raw materials. The value of the life-cycle analysis approach is that it includes the various penalties and credits associated with battery production and recycling, which enables a more accurate determination of the system's ability to reduce the consumption of scarce fuels. The analysis of the life-cycle energy requirements consists of identifying the materials from which each battery is made, evaluating the energy needed to produce these materials, evaluating the operational energy requirements, and evaluating the amount of materials that could be recycled and the energy that would be saved through recycling. Detailed descriptions of battery component materials, the energy requirements for battery production, and credits for recycling, and the operational energy for an electric vehicle, and the procedures used to determine it are discussed.

Sullivan, D; Morse, T; Patel, P; Patel, S; Bondar, J; Taylor, L

1980-12-01T23:59:59.000Z

74

Building a Better Battery for Vehicles and the Grid | Department of Energy  

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

Building a Better Battery for Vehicles and the Grid Building a Better Battery for Vehicles and the Grid Building a Better Battery for Vehicles and the Grid November 30, 2012 - 12:28pm Addthis Argonne scientists Ira Bloom (front) and Javier Bareño prepare a sample of battery materials for Raman spectroscopy, which is used to gather information regarding the nature of the materials present in the sample. | Photo courtesy of Argonne National Laboratory. Argonne scientists Ira Bloom (front) and Javier Bareño prepare a sample of battery materials for Raman spectroscopy, which is used to gather information regarding the nature of the materials present in the sample. | Photo courtesy of Argonne National Laboratory. Michael Hess Michael Hess Former Digital Communications Specialist, Office of Public Affairs

75

Batteries, vehicle and infrastructure: interlocking elements of a new engineering system concept for personal mobility  

Science Journals Connector (OSTI)

The concept proposed aims at overcoming deterrents to Electric Vehicle (EV) adoption. The system features quick en-route exchange of batteries, requiring minimal equipment at the battery exchange station, which stands in favour of this EV system's adoption. The human interface of the equipment was devised to satisfy ergonomic requirements. Added convenience and speed of battery exchange can be achieved with more sophisticated equipment installed at exchange stations where depleted vehicle batteries are swiftly swapped for fully charged ones in only a couple of minutes. The EV proposed has standard plug-in capability for regular battery charge. It is based on a notion of ownership beyond common entrenched models, since the battery system is to be owned by the organisations that are to provide the en-route exchange service. The paper concludes listing the most important engineering aspects that need to be dealt with in the engineering design of the system concept.

Denis A. Coelho; Andre S. Camboa

2010-01-01T23:59:59.000Z

76

Vehicle Technologies Office Merit Review 2014: High Energy High Power Battery Exceeding PHEV-40 Requirements  

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

Presentation given by [company name] at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about high energy high power battery...

77

Vehicle Technologies Office Merit Review 2014: High Energy Lithium Batteries for PHEV Applications  

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

Presentation given by [company name] at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about high energy lithium batteries...

78

EV Everywhere: Innovative Battery Research Powering Up Plug-In Electric Vehicles  

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

Find out how the Energy Department, in partnership with industry and national laboratories, is helping to improve the efficiency and affordability of plug-in electric vehicles through battery research.

79

Progress of the Computer-Aided Engineering of Electric Drive Vehicle Batteries (CAEBAT) (Presentation)  

SciTech Connect

This presentation, Progress of Computer-Aided Engineering of Electric Drive Vehicle Batteries (CAEBAT) is about simulation and computer-aided engineering (CAE) tools that are widely used to speed up the research and development cycle and reduce the number of build-and-break steps, particularly in the automotive industry. Realizing this, DOE?s Vehicle Technologies Program initiated the CAEBAT project in April 2010 to develop a suite of software tools for designing batteries.

Pesaran, A. A.; Han, T.; Hartridge, S.; Shaffer, C.; Kim, G. H.; Pannala, S.

2013-06-01T23:59:59.000Z

80

Evaluation of the Effects of Thermal Management on Battery Life in Plug-in Hybrid Electric Vehicles Tugce Yuksel  

E-Print Network (OSTI)

Evaluation of the Effects of Thermal Management on Battery Life in Plug-in Hybrid Electric Vehicles a simulation model that aims to evaluate the effect of thermal management on battery life. The model consists of two sub- models: a thermal model and a battery degradation model. The temperature rise in the battery

Michalek, Jeremy J.

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


81

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles  

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

complete Timeline Budget Barriers Partners Overview * Barriers addressed: - A. Battery cost - C. Performance: Energy Density - E. Lifetime * Targets - prototype cells...

82

Transient modeling and validation of lithium ion battery pack with air cooled thermal management system for electric vehicles  

Science Journals Connector (OSTI)

A transient numerical model of a lithium ion battery (LiB) pack with air cooled thermal management system is developed and validated for electric vehicle applications. In the battery model, the open circuit volta...

G. Y. Cho; J. W. Choi; J. H. Park; S. W. Cha

2014-08-01T23:59:59.000Z

83

Vehicle Technologies Office Merit Review 2013: A High-Performance PHEV Battery Pack  

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

Presentation given by LG Chem at 2013 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting about a high-performance battery pack the company is researching for plug-in electric vehicles.

84

ARPA-E Program Takes an Innovative Approach to Electric Vehicle Batteries |  

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

ARPA-E Program Takes an Innovative Approach to Electric Vehicle ARPA-E Program Takes an Innovative Approach to Electric Vehicle Batteries ARPA-E Program Takes an Innovative Approach to Electric Vehicle Batteries September 4, 2013 - 1:29pm Addthis Dr. Ping Liu of ARPA-E discusses the RANGE program and its innovative approach to energy storage for electric vehicles. | Photo courtesy of ARPA-E. Dr. Ping Liu of ARPA-E discusses the RANGE program and its innovative approach to energy storage for electric vehicles. | Photo courtesy of ARPA-E. Mark D. Mitchell Communications Support Contractor to ARPA-E What are the key facts? ARPA-E's new RANGE Program looks at electric vehicle design from a holistic level. Through RANGE, ARPA-E is working to make EVs cost and performance competitive with internal combustion engines, while also allowing them to

85

Comparison of the environmental impact of five electric vehicle battery technologies using LCA  

Science Journals Connector (OSTI)

The environmental assessment of various electric vehicle battery technologies (lead-acid, nickel-cadmium, nickel-metal hydride, sodium nickel-chloride, and lithium-ion) was performed in the context of the European end-of-life vehicles directive (2000/53/EC). An environmental single-score based on a life-cycle approach, was allocated to each of the studied battery technologies through the combined use of the Simapro® software and of the life cycle impact assessment (LCIA) method Eco-indicator 99. The allocation of a single-score enables determining which battery technology is to be used preferably in electric vehicles and to indicate how to further improve the overall environmental friendliness of electric vehicles in the future.

Julien Matheys; Jean-Marc Timmermans; Joeri Van Mierlo; Sandrine Meyer; Peter Van den Bossche

2009-01-01T23:59:59.000Z

86

Design and Simulation of Passive Thermal Management System for Lithium-ion Battery Packs on an Unmanned Ground Vehicle.  

E-Print Network (OSTI)

?? The transient thermal response of a 15-cell, 48 volt, lithium-ion battery pack for an unmanned ground vehicle was simulated with ANSYS Fluent. Heat generation… (more)

Parsons, Kevin Kenneth

2012-01-01T23:59:59.000Z

87

An assessment of research and development leadership in advanced batteries for electric vehicles  

SciTech Connect

Due to the recently enacted California regulations requiring zero emission vehicles be sold in the market place by 1998, electric vehicle research and development (R&D) is accelerating. Much of the R&D work is focusing on the Achilles` heel of electric vehicles -- advanced batteries. This report provides an assessment of the R&D work currently underway in advanced batteries and electric vehicles in the following countries: Denmark, France, Germany, Italy, Japan, Russia, and the United Kingdom. Although the US can be considered one of the leading countries in terms of advanced battery and electric vehicle R&D work, it lags other countries, particularly France, in producing and promoting electric vehicles. The US is focusing strictly on regulations to promote electric vehicle usage while other countries are using a wide variety of policy instruments (regulations, educational outreach programs, tax breaks and subsidies) to encourage the use of electric vehicles. The US should consider implementing additional policy instruments to ensure a domestic market exists for electric vehicles. The domestic is the largest and most important market for the US auto industry.

Bruch, V.L.

1994-02-01T23:59:59.000Z

88

Experimental investigation of battery thermal management system for electric vehicle based on paraffin/copper foam  

Science Journals Connector (OSTI)

Abstract To enhance the heat transfer of phase change material in battery thermal management system for electric vehicle, a battery thermal management system by using paraffin/copper foam was designed and experimentally investigated in this paper. The thermal performances of the system such as temperature reduction and distribution are discussed in detail. The results showed that the local temperature difference in both a single cell and battery module were increased with the increase of discharge current, and obvious fluctuations of local temperature difference can be observed when the electric vehicle is in road operating state. When the battery is discharging at constant current, the maximum temperature and local temperature difference of the battery module with paraffin/copper foam was lower than 45 °C and 5 °C, respectively. After the battery thermal management system was assembled in electric vehicle, the maximum temperature and local temperature difference in road operating state was lower than 40 °C and 3 °C, respectively. The experimental results demonstrated that paraffin/copper foam coupled battery thermal management presented an excellent cooling performance.

Zhonghao Rao; Yutao Huo; Xinjian Liu; Guoqing Zhang

2014-01-01T23:59:59.000Z

89

US Department of Energy Hybrid Vehicle Battery and Fuel Economy Testing  

SciTech Connect

The Advanced Vehicle Testing Activity (AVTA), part of the U.S. Department of Energy’s FreedomCAR and Vehicle Technologies Program, has conducted testing of advanced technology vehicles since August, 1995 in support of the AVTA goal to provide benchmark data for technology modeling, and research and development programs. The AVTA has tested over 200 advanced technology vehicles including full size electric vehicles, urban electric vehicles, neighborhood electric vehicles, and hydrogen internal combustion engine powered vehicles. Currently, the AVTA is conducting significant tests of hybrid electric vehicles (HEV). This testing has included all HEVs produced by major automotive manufacturers and spans over 1.3 million miles. The results of all testing are posted on the AVTA web page maintained by the Idaho National Laboratory. Through the course of this testing, the fuel economy of HEV fleets has been monitored and analyzed to determine the "real world" performance of their hybrid energy systems, particularly the battery. While the initial "real world" fuel economy of these vehicles has typically been less than that evaluated by the manufacturer and varies significantly with environmental conditions, the fuel economy and, therefore, battery performance, has remained stable over vehicle life (160,000 miles).

Donald Karner; J.E. Francfort

2005-09-01T23:59:59.000Z

90

U.S. Department of Energy Vehicle Technologies Program: Battery Test Manual For Plug-In Hybrid Electric Vehicles  

SciTech Connect

This battery test procedure manual was prepared for the United States Department of Energy (DOE), Office of Energy Efficiency and Renewable Energy (EERE), Vehicle Technologies Office. It is based on technical targets for commercial viability established for energy storage development projects aimed at meeting system level DOE goals for Plug-in Hybrid Electric Vehicles (PHEV). The specific procedures defined in this manual support the performance and life characterization of advanced battery devices under development for PHEV’s. However, it does share some methods described in the previously published battery test manual for power-assist hybrid electric vehicles. Due to the complexity of some of the procedures and supporting analysis, future revisions including some modifications and clarifications of these procedures are expected. As in previous battery and capacitor test manuals, this version of the manual defines testing methods for full-size battery systems, along with provisions for scaling these tests for modules, cells or other subscale level devices. The DOE-United States Advanced Battery Consortium (USABC), Technical Advisory Committee (TAC) supported the development of the manual. Technical Team points of contact responsible for its development and revision are Renata M. Arsenault of Ford Motor Company and Jon P. Christophersen of the Idaho National Laboratory. The development of this manual was funded by the Unites States Department of Energy, Office of Energy Efficiency and Renewable Energy, Vehicle Technologies Office. Technical direction from DOE was provided by David Howell, Energy Storage R&D Manager and Hybrid Electric Systems Team Leader. Comments and questions regarding the manual should be directed to Jon P. Christophersen at the Idaho National Laboratory (jon.christophersen@inl.gov).

Jon P. Christophersen

2014-09-01T23:59:59.000Z

91

Development of High Energy Lithium Batteries for Electric Vehicles  

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

2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting

92

Computer-Aided Engineering for Electric Drive Vehicle Batteries (CAEBAT)  

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

2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation

93

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles  

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

2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting

94

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles  

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

2013 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting

95

Status and evaluation of hybrid electric vehicle batteries for short term applications. Final report  

SciTech Connect

The objective of this task is to compile information regarding batteries which could be use for electric cars or hybrid vehicles in the short term. More specifically, this study applies lead-acid batteries and nickel-cadmium battery technologies which are more developed than the advanced batteries which are presently being investigated under USABC contracts and therefore more accessible in production efficiency and economies of scale. Moreover, the development of these batteries has advanced the state-of-the-art not only in terms of performance and energy density but also in cost reduction. The survey of lead-acid battery development took the biggest part of the effort, since they are considered more apt to be used in the short-term. Companies pursuing the advancement of lead-acid batteries were not necessarily the major automobile battery manufacturers. Innovation is found more in small or new companies. Other battery systems for short-term are discussed in the last part of this report. We will review the various technologies investigated, their status and prognosis for success in the short term.

Himy, A. [Westinghouse Electric Co., Pittsburgh, PA (United States). Machinery Technology Div.

1995-07-01T23:59:59.000Z

96

Advanced battery thermal management for electrical-drive vehicles using reciprocating cooling flow and spatial-resolution, lumped-capacitance thermal model.  

E-Print Network (OSTI)

?? The thermal management of traction battery systems for electrical-drive vehicles directly affects vehicle dynamic performance, long-term durability and cost of the battery systems. The… (more)

Mahamud, Rajib

2011-01-01T23:59:59.000Z

97

Illinois: High-Energy, Concentration-Gradient Cathode Material for Plug-in Hybrids and All-Electric Vehicles Could Reduce Batteries' Cost and Size  

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

Batteries for electric drive vehicles and renewable energy storage will reduce petroleum usage, improving energy security and reducing harmful emissions.

98

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles. Volume 1, Cell and battery safety  

SciTech Connect

This report is the first of four volumes that identify and assess the environmental, health, and safety issues involved in using sodium-sulfur (Na/S) battery technology as the energy source in electric and hybrid vehicles that may affect the commercialization of Na/S batteries. This and the other reports on recycling, shipping, and vehicle safety are intended to help the Electric and Hybrid Propulsion Division of the Office of Transportation Technologies in the US Department of Energy (DOE/EHP) determine the direction of its research, development, and demonstration (RD&D) program for Na/S battery technology. The reports review the status of Na/S battery RD&D and identify potential hazards and risks that may require additional research or that may affect the design and use of Na/S batteries. This volume covers cell design and engineering as the basis of safety for Na/S batteries and describes and assesses the potential chemical, electrical, and thermal hazards and risks of Na/S cells and batteries as well as the RD&D performed, under way, or to address these hazards and risks. The report is based on a review of the literature and on discussions with experts at DOE, national laboratories and agencies, universities, and private industry. Subsequent volumes will address environmental, health, and safety issues involved in shipping cells and batteries, using batteries to propel electric vehicles, and recycling and disposing of spent batteries. The remainder of this volume is divided into two major sections on safety at the cell and battery levels. The section on Na/S cells describes major component and potential failure modes, design, life testing and failure testing, thermal cycling, and the safety status of Na/S cells. The section on batteries describes battery design, testing, and safety status. Additional EH&S information on Na/S batteries is provided in the appendices.

Ohi, J.M.

1992-09-01T23:59:59.000Z

99

Battery Energy Availability and Consumption during Vehicle Charging across Ambient Temperatures and Battery Temperature (conditioning)  

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

2013 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting

100

Vehicle Technologies Office Merit Review 2014: Overview and Progress of Applied Battery Research (ABR) Activities  

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

Presentation given by the Department of Energy's Energy Storage area at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about the research area that addresses near term (less than 5 years) opportunities and barriers as battery materials move from R&D to cell construction and validation.

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


101

Contribution of Li-Ion Batteries to the Environmental Impact of Electric Vehicles  

Science Journals Connector (OSTI)

Contribution of Li-Ion Batteries to the Environmental Impact of Electric Vehicles ... The production of concentrated lithium brine includes inspissations of lithium containing brine by solar energy in the desert of Atacama. ... Concerning EI99 H/A, the production of the anode generates the highest impact, while CED, GWP, and ADP show the highest impact for the production of the cathode. ...

Dominic A. Notter; Marcel Gauch; Rolf Widmer; Patrick Wäger; Anna Stamp; Rainer Zah; Hans-Jörg Althaus

2010-08-09T23:59:59.000Z

102

Switching algorithms for extending battery life in Electric Vehicles Ron Adany a,*, Doron Aurbach b  

E-Print Network (OSTI)

reserved. 1. Introduction Electric Vehicles (EVs) are the next generation of cars in the world-determined threshold [3]. The energy extracted from the battery during full discharge is the integration of voltage-hours). However, an alternative definition, which we use throughout this paper, can be the total accumulated

Kraus, Sarit

103

ESS 2012 Peer Review - Secondary Use of Vehicle Batteries in Power Systems - Omer Onar, ORNL  

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

/2012 1 /2012 1 National Academy of Engineering - BMED December 2008 www.oe.energy.gov U.S. Department of Energy - 1000 Independence Ave., SW Washington, DC 20585 Secondary Use of Vehicle Batteries in Power Systems December 2008 Secondary Use of Vehicle Batteries in Power Systems Objective Life-cycle Funding Summary FY12 FY13 300k ?k Technical Scope The objective is this project is to carry out a collaborative effort among ORNL, original equipment manufacturers (OEM)s, and other partners to develop a cogent and informed view of the economic and technological value of secondary use of EV batteries in grid support. CES is one of the highlighted synergistic applications with a high value to cost relationship. Specific grid services related to CES (community energy storage) is

104

Regulatory Influences That Will Likely Affect Success of Plug-in Hybrid and Battery Electric Vehicles  

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

Influences That Will Likely Influences That Will Likely Affect Success of Plug-in Hybrid and Battery Electric Vehicles By Dan Santini Argonne National Laboratory dsantini@anl.gov Clean Cities Coordinators' Webinar Sept. 16, 2010 Vehicle fuel use regulation/policy measures differ. Which should measure plug-in success?  Corporate average fuel economy (CAFE) ratings do not represent real world fuel use. However, the range ratings of EVs and PHEVs are based on CAFE tests.  "Window sticker" information on vehicle fuel use predicts more gasoline and electricity use than CAFE ratings. - The GREET model (basis of GHG saving estimates) is based on real world fuel use

105

Ultracapacitor/Battery Hybrid Energy Storage Systems for Electric Vehicles.  

E-Print Network (OSTI)

??This thesis deals with the design of Hybrid Energy Storage System (HESS) for Light Electric Vehicles (LEV) and EVs. More specifically, a tri-mode high-efficiency non-isolated… (more)

Moshirvaziri, Mazhar

2012-01-01T23:59:59.000Z

106

Microsoft Word - Vehicle Battery Final EA_Toda 3-19-10.doc  

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

4 4 Environmental Assessment for Toda America, Incorporated Electric Drive Vehicle Battery and Component Manufacturing Initiative Project Battle Creek, MI March 2010 Prepared for: Department of Energy National Energy Technology Laboratory Environmental Assessment and Finding of No Significant Impact DOE/EA-1714 Toda America, Incorporated, Battle Creek, MI March 2010 National Environmental Policy Act (NEPA) Compliance Cover Sheet Proposed Action: The U.S. Department of Energy (DOE) proposes, through a cooperative agreement with Toda America, Incorporated (Toda) to partially fund the construction of a manufacturing plant to produce oxide materials for cathodes for lithium-ion batteries. The plant would be constructed within an existing industrial park in Battle Creek,

107

Vehicle Technologies Office Merit Review 2014: Overview and Progress of the Battery Testing, Design and Analysis Activity  

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

Presentation given by the Department of Energy's Energy Storage area at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about the battery testing, design, and analysis activity.

108

A Vehicle Systems Approach to Evaluate Plug-in Hybrid Battery Cold Start, Life and Cost Issues  

E-Print Network (OSTI)

The batteries used in plug-in hybrid electric vehicles (PHEVs) need to overcome significant technical challenges in order for PHEVs to become economically viable and have a large market penetration. The internship at Argonne National Laboratory (ANL...

Shidore, Neeraj Shripad

2012-07-16T23:59:59.000Z

109

A techno-economic analysis and optimization of Li-ion batteries for light-duty passenger vehicle electrification  

E-Print Network (OSTI)

A techno-economic analysis and optimization of Li-ion batteries for light-duty passenger vehicle 15213, USA h i g h l i g h t s We analyze EV Li-ion NMC-G battery & pack designs and optimize thickness a b s t r a c t We conduct a techno-economic analysis of Li-ion NMC-G prismatic pouch battery

McGaughey, Alan

110

Online Identification of Power Required for Self-Sustainability of the Battery in Hybrid Electric Vehicles  

SciTech Connect

Hybrid electric vehicles have shown great potential for enhancing fuel economy and reducing emissions. Deriving a power management control policy to distribute the power demanded by the driver optimally to the available subsystems (e.g., the internal combustion engine, motor, generator, and battery) has been a challenging control problem. One of the main aspects of the power management control algorithms is concerned with the self-sustainability of the electrical path, which must be guaranteed for the entire driving cycle. This paper considers the problem of identifying online the power required by the battery to maintain the state of charge within a range of the target value. An algorithm is presented that realizes how much power the engine needs to provide to the battery so that self-sustainability of the electrical path is maintained.

Malikopoulos, Andreas [ORNL

2014-01-01T23:59:59.000Z

111

Microsoft Word - Vehicle Battery Final EA Celgard 4-29-10.doc  

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

3 3 Environmental Assessment for Celgard LLC Electric Drive Vehicle Battery and Component Manufacturing Initiative Project Concord, NC April 2010 Prepared for: Department of Energy National Energy Technology Laboratory Environmental Assessment DOE/EA-1713 Celgard LLC, Concord, NC April 2010 National Environmental Policy Act (NEPA) Compliance Cover Sheet Proposed Action: The U.S. Department of Energy (DOE) proposes, through a cooperative agreement with Celgard LLC (Celgard), to partially fund the construction of a small industrial facility (approximately 135,000 square feet) on approximately 20.6 acres of land for the manufacturing of separator materials for commercial hybrid-electric vehicle (HEV) batteries. The facility would be constructed on parcels within the International Business Park,

112

EA-1869: Supplement to General Motors Corp., Electric Vehicle/Battery  

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

9: Supplement to General Motors Corp., Electric 9: Supplement to General Motors Corp., Electric Vehicle/Battery Manufacturing Application, White Marsh, Maryland, and Wixom, Michigan (DOE/EA-1723-S1) EA-1869: Supplement to General Motors Corp., Electric Vehicle/Battery Manufacturing Application, White Marsh, Maryland, and Wixom, Michigan (DOE/EA-1723-S1) Overview Based on the analysis in the Environmental Assessment DOE determined that its proposed action, to award a federal grant to General Motors to establish an electric motor components manufacturing and electric drive assembly facility would result in no significant adverse impacts. Public Comment Opportunities No public comment opportunities available at this time. Documents Available for Download September 29, 2011 EA-1869: Final Environmental Assessment and Finding of No Significant

113

Microsoft Word - Final EA ENERG2 Vehicle Battery 4-2-10.doc  

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

8 8 Environmental Assessment For EnerG2, Inc. Electric Drive Vehicle Battery and Component Manufacturing Initiative Project Albany, OR April 2010 Prepared for: Department of Energy National Energy Technology Laboratory Environmental Assessment DOE/EA-1718 EnerG2, Inc., Albany, OR April 2010 National Environmental Policy Act (NEPA) Compliance Cover Sheet Proposed Action: The U.S. Department of Energy (DOE) proposes, through a cooperative agreement with EnerG2, Inc. (EnerG2) to partially fund the establishment of a commercial-size manufacturing plant that would produce nanostructured carbon powder that could be used in manufacturing ultra-capacitors and battery anodes. The plant would be setup in Albany, Oregon and would support the anticipated growth in the electric drive vehicle (EDV) industry and

114

Vehicle Technologies Office Merit Review 2014: Overview and Progress of the Batteries for Advanced Transportation Technologies (BATT) Activity  

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

Presentation given by the Department of Energy's Energy Storage area at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about the research area that is examining new battery materials and addressing fundamental chemical and mechanical instability issues in batteries.

115

Overcoming the Range Limitation of Medium-Duty Battery Electric Vehicles through the use of Hydrogen Fuel-Cells  

SciTech Connect

Battery electric vehicles possess great potential for decreasing lifecycle costs in medium-duty applications, a market segment currently dominated by internal combustion technology. Characterized by frequent repetition of similar routes and daily return to a central depot, medium-duty vocations are well positioned to leverage the low operating costs of battery electric vehicles. Unfortunately, the range limitation of commercially available battery electric vehicles acts as a barrier to widespread adoption. This paper describes the National Renewable Energy Laboratory's collaboration with the U.S. Department of Energy and industry partners to analyze the use of small hydrogen fuel-cell stacks to extend the range of battery electric vehicles as a means of improving utility, and presumably, increasing market adoption. This analysis employs real-world vocational data and near-term economic assumptions to (1) identify optimal component configurations for minimizing lifecycle costs, (2) benchmark economic performance relative to both battery electric and conventional powertrains, and (3) understand how the optimal design and its competitiveness change with respect to duty cycle and economic climate. It is found that small fuel-cell power units provide extended range at significantly lower capital and lifecycle costs than additional battery capacity alone. And while fuel-cell range-extended vehicles are not deemed economically competitive with conventional vehicles given present-day economic conditions, this paper identifies potential future scenarios where cost equivalency is achieved.

Wood, E.; Wang, L.; Gonder, J.; Ulsh, M.

2013-10-01T23:59:59.000Z

116

Procedures for safe handling of off-gases from electric vehicle lead-acid batteries during overcharge  

SciTech Connect

The potential for generation of toxic gases from lead-acid batteries has long been recognized. Prior to the current interest in electric vehicles, there were no studies specificaly oriented to toxic gas release from traction batteries, however. As the Department of Energy Demonstration Project (in the Electric and Hybrid Vehicle Program) progresses, available data from past studies and parallel health effects programs must be digested into guidance to the drivers and maintenance personnel, tailored to their contact with electric vehicles. The basic aspects of lead-acid battery operation, vehicle use, and health effects of stibine and arsine to provide electric vehicle users with the information behind the judgment that vehicle operation and testing may proceed are presented. Specifically, it is concluded that stibine generation or arsine generation at rapid enough rates to induce acute toxic response is not at all likely. Procedures to guard against low-level exposure until more definitive data on ambient concentrations of the gases are collected are presented for both charging the batteries and driving the vehicles. A research plan to collect additional quantitative data from electric traction batteries is presented.

LaBelle, S.J.; Bhattacharyya, M.H.; Loutfy, R.O.; Varma, R.

1980-01-25T23:59:59.000Z

117

Cost-effectiveness of plug-in hybrid electric vehicle battery capacity and charging infrastructure investment for reducing US gasoline consumption  

E-Print Network (OSTI)

backup for long trips) or gasoline-powered hybrid electric vehicles. If more gasoline savings are neededCost-effectiveness of plug-in hybrid electric vehicle battery capacity and charging infrastructure online 22 October 2012 Keywords: Plug-in hybrid electric vehicle Charging infrastructure Battery size a b

Michalek, Jeremy J.

118

Vehicle Technologies Office Merit Review 2014: The Voltage Fade Project, A New Paradigm for Applied Battery Research  

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

Presentation given by the Department of Energy's Energy Storage area at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about a new approach to the challenge of voltage fade in batteries for plug-in electric vehicles.

119

Vehicle Technologies Office Merit Review 2014: High-Voltage Solid Polymer Batteries for Electric Drive Vehicles  

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

Presentation given by Seeo, Inc. at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about high-voltage solid polymer...

120

Optimal power management and powertrain components sizing of fuel cell/battery hybrid electric vehicles based on particle swarm optimisation  

Science Journals Connector (OSTI)

Combining a Fuel Cell (FC), as primary power source, with a Battery Energy System (BES), as an auxiliary source, for high power demands is a promising approach for future hybrid electric vehicles (HEV). The powertrain control strategy and the component sizing significantly affect the vehicle performance, cost, vehicle efficiency and fuel economy. This paper presents a developed control strategy for optimising the power sharing between sources and components sizing by using Particle Swarm Optimisation (PSO) algorithm. This control strategy implemented on FC/Battery hybrid electric vehicle in order to achieve the best performance with minimum fuel consumption and minimum powertrain components sizing for a given driving cycle with high efficiency. The powertrain and the proposed control strategy have been simulated by Matlab/Simulink. The simulation results have demonstrated that the optimal sizing of the powertrain of FC/battery components and the minimum fuel consumption have been improved by applying the PSO control strategy.

Omar Hegazy; Joeri Van Mierlo

2012-01-01T23:59:59.000Z

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


121

A procedure for derating a substation transformer in the presence of widespread electric vehicle battery charging  

SciTech Connect

This paper studies the effect of electric vehicle (EV) battery charging on a substation transformer that supplies commercial, residential, industrial, and EV load on a peak summer day. The analysis begins on modeling non-EV load with typical utility load shapes. EV load is modeled using the results from an analytical solution technique that predicts the net power and harmonic currents generated by a group of EV battery chargers. The authors evaluate the amount of transformer derating by maintaining constant daily transformer loss-of-life, with and without EV charging. This analysis shows that the time of day and the length of time during which the EVs begin charging are critical in determining the amount of transformer derating required. The results show that with proper control, EV charging may have very little effect on power system components at the substation level.

Staats, P.T.; Grady, W.M.; Arapostathis, A. [Univ. of Texas, Austin, TX (United States)] [Univ. of Texas, Austin, TX (United States); Thallam, R.S. [Salt River Project, Phoenix, AZ (United States)] [Salt River Project, Phoenix, AZ (United States)

1997-10-01T23:59:59.000Z

122

Reduction of Electric Vehicle Life-Cycle Impacts through Battery Recycling  

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

Reduction of Electric Vehicle Life-Cycle Impacts through Battery Recycling 29 th International Battery Seminar and Exhibit Ft. Lauderdale, FL March 15, 2012 The submitted manuscript has been created by UChicago Argonne, LLC, Operator of Argonne National Laboratory ("Argonne"). Argonne, a U.S. Department of Energy Office of Science laboratory, is operated under Contract No. DE-AC02-06CH11357. The U.S. Government retains for itself, and others acting on its behalf, a paid-up nonexclusive, irrevocable worldwide license in said article to reproduce, prepare derivative works, distribute copies to the public, and perform publicly and display publicly, by or on behalf of the Government. Why think about recycling?  Material scarcity alleviated

123

Understanding fuel savings mechanisms from hybrid vehicles to guide optimal battery sizing for India  

Science Journals Connector (OSTI)

Global transportation-related CO2 emissions are expected to substantially increase by 2050, with a majority of growth coming from rapidly developing countries like India. To understand the potential for using hybrid vehicles to limit the CO2 emissions growth, this paper compares driving conditions and the fuel savings potential of hybrids in the USA and India. It is shown that hybrids offer more fuel savings potential in India than in the USA, largely because of the limited highway driving in India. In order of relative importance, the analysis shows that fuel savings from power-split hybrids come from: 1) enabling higher efficiency engine operation; 2) energy recovered from regenerative braking; 3) engine shutdown. This understanding of the fuel savings mechanisms of hybrids and their relative importance is used in assessing how smaller battery capacities for hybrids in India can be used to reduce costs for this highly cost-sensitive market while preserving fuel savings. A parametric analysis of battery size on fuel savings mechanisms is carried out, and it is shown that hybrid vehicles for Indian driving conditions should ideally have a power capacity between 15 and 20 kW, with 10 kW as a lower limit.

Samveg Saxena; Amol Phadke; Anand Gopal; Venkat Srinivasan

2014-01-01T23:59:59.000Z

124

Prediction of thermal behaviors of an air-cooled lithium-ion battery system for hybrid electric vehicles  

Science Journals Connector (OSTI)

Abstract Thermal management has been one of the major issues in developing a lithium-ion (Li-ion) hybrid electric vehicle (HEV) battery system since the Li-ion battery is vulnerable to excessive heat load under abnormal or severe operational conditions. In this work, in order to design a suitable thermal management system, a simple modeling methodology describing thermal behavior of an air-cooled Li-ion battery system was proposed from vehicle components designer's point of view. A proposed mathematical model was constructed based on the battery's electrical and mechanical properties. Also, validation test results for the Li-ion battery system were presented. A pulse current duty and an adjusted US06 current cycle for a two-mode HEV system were used to validate the accuracy of the model prediction. Results showed that the present model can give good estimations for simulating convective heat transfer cooling during battery operation. The developed thermal model is useful in structuring the flow system and determining the appropriate cooling capacity for a specified design prerequisite of the battery system.

Yong Seok Choi; Dal Mo Kang

2014-01-01T23:59:59.000Z

125

Optimal economy-based battery degradation management dynamics for fuel-cell plug-in hybrid electric vehicles  

Science Journals Connector (OSTI)

Abstract This work analyses the economical dynamics of an optimized battery degradation management strategy intended for plug-in hybrid electric vehicles (PHEVs) with consideration given to low-cost technologies, such as lead-acid batteries. The optimal management algorithm described herein is based on discrete dynamic programming theory (DDP) and was designed for the purpose of PHEV battery degradation management; its operation relies on simulation models using data obtained experimentally on a physical PHEV platform. These tools are first used to define an optimal management strategy according to the economical weights of PHEV battery degradation and the secondary energy carriers spent to manage its deleterious effects. We then conduct a sensitivity study of the proposed optimization process to the fluctuating economic parameters associated with the fuel and energy costs involved in the degradation management process. Results demonstrate the influence of each parameter on the process's response, including daily total operating costs and expected battery lifetime, as well as establish boundaries for useful application of the method; in addition, they provide a case for the relevance of inexpensive battery technologies, such as lead-acid batteries, for economy-centric PHEV applications where battery degradation is a major concern.

François Martel; Sousso Kelouwani; Yves Dubé; Kodjo Agbossou

2015-01-01T23:59:59.000Z

126

Lithium/iron sulfide batteries for electric-vehicle propulsion and other applications. Progress report, October 1979-March 1980  

SciTech Connect

The research and development activities of the program at Argonne National Laboratory (ANL) on lithium/iron sulfide batteries during the period October 1979-March 1980 is described. Although the major emphasis is currently on batteries for electric-vehicle propulsion, stationary energy-storage applications are also under investigation. The individual battery cells, which operate at 400 to 500/sup 0/C, are of a vertically oriented, prismatic design with two or more positive electrodes of FeS or FeS/sub 2/, facing negative electrodes of lithium-aluminum or lithium-silicon alloy, and molten LiCl-KCl electrolyte. The ANL program consists of cell chemistry studies, materials engineering, and component and auxiliary systems development. Important elements of this program are studies of the effects of design modifications on cell performance and post-test examinations of cells. During the reporting period, cell and battery development work has been aimed primarily at the first phase of the Mark II electric-vehicle battery program, which consists of an effort to develop high-reliability cells having boron nitride felt separators. Later in the Mark II program, the cells will be tested in 10-cell modules. Work on stationary energy-storage batteries during this period has consisted mainly of conceptual design studies. 23 figures, 9 tables.

None

1980-08-01T23:59:59.000Z

127

Analysis of environmental factors impacting the life cycle cost analysis of conventional and fuel cell/battery-powered passenger vehicles. Final report  

SciTech Connect

This report presents the results of the further developments and testing of the Life Cycle Cost (LCC) Model previously developed by Engineering Systems Management, Inc. (ESM) on behalf of the U.S. Department of Energy (DOE) under contract No. DE-AC02-91CH10491. The Model incorporates specific analytical relationships and cost/performance data relevant to internal combustion engine (ICE) powered vehicles, battery powered electric vehicles (BPEVs), and fuel cell/battery-powered electric vehicles (FCEVs).

NONE

1995-01-31T23:59:59.000Z

128

Hierarchically Structured Materials for Lithium Batteries. |...  

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

battery (LIB) is one of the most promising power sources to be deployed in electric vehicles (EV), including solely battery powered vehicles, plug-in hybrid electric vehicles,...

129

NREL Reveals Links Among Climate Control, Battery Life, and Electric Vehicle Range (Fact Sheet), Innovation: The Spectrum of Clean Energy Innovation, NREL (National Renewable Energy Laboratory)  

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

Reveals Links Among Reveals Links Among Climate Control, Battery Life, and Electric Vehicle Range Researchers at the National Renewable Energy Laboratory (NREL) are providing new insights into the relationships between the climate-control systems of plug-in electric vehicles and the distances these vehicles can travel on a single charge. In particular, NREL research has determined that "preconditioning" a vehicle- achieving a comfortable cabin temperature and preheating or precooling the battery while the vehicle is still plugged in-can extend its driving range and improve battery life over the long term. One of the most significant barriers to widespread deployment of electric vehicles is range anxiety-a driver's uncertainty about the vehicle's ability to reach a destination before fully

130

Chlorine hazard evaluation for the zinc-chlorine electric vehicle battery. Final technical report. [50 kWh  

SciTech Connect

Hazards associated with conceivable accidental chlorine releases from zinc-chlorine electric vehicle batteries are evaluated. Since commercial batteries are not yet available, this hazard assessment is based on both theoretical chlorine dispersion models and small-scale and large-scale spill tests with chlorine hydrate (which is the form of chlorine storage in the charged battery). Six spill tests involving the chlorine hydrate equivalent of a 50-kWh battery indicate that the danger zone in which chlorine vapor concentrations intermittently exceed 100 ppM extends at least 23 m directly downwind of a spill onto a warm (30 to 38/sup 0/C) road surface. Other accidental chlorine release scenarios may also cause some distress, but are not expected to produce the type of life-threatening chlorine exposures that can result from large hydrate spills. Chlorine concentration data from the hydrate spill tests compare favorably with calculations based on a quasi-steady area source dispersion model and empirical estimates of the hydrate decomposition rate. The theoretical dispersion model was combined with assumed hydrate spill probabilities and current motor vehicle accident statistics in order to project expected chlorine-induced fatality rates. These calculations indicate that expected chlorine fataility rates are several times higher in a city such as Los Angeles with a warm and calm climate than in a colder and windier city such as Boston. Calculated chlorine-induced fatality rate projections for various climates are presented as a function of hydrate spill probability in order to illustrate the degree of vehicle/battery crashworthiness required to maintain chlorine-induced fatality rates below current vehicle fatality rates due to fires and asphyxiations. 37 figures, 19 tables.

Zalosh, R. G.; Bajpai, S. N.; Short, T. P.; Tsui, R. K.

1980-04-01T23:59:59.000Z

131

Hunan Copower EV Battery Co Ltd | Open Energy Information  

Open Energy Info (EERE)

EV Battery Co Ltd Place: Hunan Province, China Sector: Vehicles Product: Producer of batteries and battery-related products for electric vehicles. References: Hunan Copower EV...

132

Richmond Electric Vehicle Initiative Electric Vehicle Readiness...  

Office of Environmental Management (EM)

MO) Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels Modeling, Testing, Data & Results Education...

133

Predicting Battery Pack Thermal and Electrical Performance in a Vehicle Using Realistic Drive Cycle Power Profiles  

Science Journals Connector (OSTI)

The heat generated during battery charge and discharge cycles is a major ... issue, particularly since the performance of a battery depends on its operating temperature. As a consequence, robust thermal managemen...

Allen Curran; Scott Peck

2013-01-01T23:59:59.000Z

134

NREL's emulation tool helps manufacturers ensure the safety and reliability of electric vehicle batteries.  

E-Print Network (OSTI)

in a short circuit between electrodes during use. As electric car manufacturers turn to Li-ion batteries

135

Modeling of passive thermal management for electric vehicle battery packs with PCM between cells  

Science Journals Connector (OSTI)

Abstract A passive thermal management system is examined for an electric vehicle battery pack. Phase change material (PCM) is infused in foam layers separating the lithium-ion (Li-ion) cells. Known operating conditions lead to selecting a suitable PCM for the application, n-octadecane wax. Suitable porous foam for infusion is decided on through experimentation. Finite volume based simulations are conducted to study the thermal behavior of a 4 cell sub-module. The effect of different discharge rates are compared for this sub-module, with and without the PCM's presence. The results show that the maximum temperature in the system is decreased up to 7.3 K by replacing dry foam with PCM-soaked “wet foam”. The addition of PCM also makes the temperature distribution more uniform across the cells. The modeling results give indication of the quantity of PCM required, show the influence of the transient melt behavior under dynamic operating conditions, and examine design constraints associated with this approach.

N. Javani; I. Dincer; G.F. Naterer; G.L. Rohrauer

2014-01-01T23:59:59.000Z

136

Simplified Heat Generation Model for Lithium ion battery used in Electric Vehicle  

Science Journals Connector (OSTI)

It is known that temperature variations inside a battery may greatly affect its performance, life, and reliability. In an effort to gain a better understanding of the heat generation in Lithium ion batteries, a simple heat generation models were constructed in order to predict the thermal behaviour of a battery pack. The Lithium ion battery presents in this paper is Lithium Iron Phosphate (LiFePO4). The results show that the model can be viewed as an acceptable approximation for the variation of the battery pack temperature at a continuous discharge current from data provided by the manufacturer and literature.

Nur Hazima Faezaa Ismail; Siti Fauziah Toha; Nor Aziah Mohd Azubir; Nizam Hanis Md Ishak; Mohd Khair Hassan; Babul Salam Ksm Ibrahim

2013-01-01T23:59:59.000Z

137

Test and evaluation of the Philips Model PE 1701 and Lester Model 9865 electric vehicle battery chargers  

SciTech Connect

The Philips Model PE 1701 and the Lester Model 9865 electric vehicle battery chargers have been tested by the Tennessee Valley Authority. Charger input/output voltage, current, power characteristics, and input waveform distortion were measured and induced electromagnetic interference was evaluated while the chargers recharged a fully discharged lead-acid battery pack. Electrical quantities were measured with precision volt-ampere-watt meters, frequency counters, a digital storage oscilloscope, and a spectrum analyzer. The Philips charger required 12.2 hours to recharge a 144-V battery; it had an energy efficiency of 86.0 percent and a specific power of 87.4 W/kg (39.7 W/lb). Input current distortion was between 6.9 and 23.0 percent, and electromagnetic interference was observed on AM radio. The Lester charger required 8.2 hours to recharge a 106-V battery; it had an energy efficiency of 83.0 percent and a specific power of 117.3 W/kg (53.3 W/lb). Current distortion was between 52.7 and 97.4 percent, and electromagnetic interference was observed on AM radio.

Reese, R.W.; Driggans, R.L.; Keller, A.S.

1984-04-01T23:59:59.000Z

138

Test and evaluation of the Chloride Spegel S1P108/30 electric vehicle battery charger  

SciTech Connect

The Chloride Spegel Model S1P108/30 electric vehicle battery charger was tested by the Tennessee Valley Authority (TVA) as an account of work sponsored by the Electric Power Research Institute (EPRI). Charger input/output voltage, current, and power characteristics and input waveform distortion were measured; and induced electromagnetic interference was evaluated as the charger recharged a lead-acid battery pack. Electrical quantities were measured with precision volt-ampere-watt meters, frequency counters, a digital-storage oscilloscope, and a spectrum analyzer. THe Chloride charger required 8.5 hours to recharge a 216V tubular plate lead-acid battery from 100 percent depth of discharge (DOD). Energy efficiency was 83 percent, specific power was 37.4 W/kg (17.0 W/lb), input current distortion varied from 22.4 to 34.1 percent, and electromagnetic interference was observed on AM radio. Tests were conducted with the battery at initial DOD of 100, 75, 50, and 25 percent. Charge factor was 1.14 from 100-percent DOD, increasing to 1.39 from 25-percent DOD.

Driggans, R.L.; Keller, A.S.

1985-09-01T23:59:59.000Z

139

Design of battery pack and internal combustion engine thermal models for hybrid electric vehicles.  

E-Print Network (OSTI)

?? This thesis focuses on the design of computational models, capable of simulating the thermal behaviour of a battery pack and internal combustion engine equipping… (more)

Catacchio, Gabriele

2013-01-01T23:59:59.000Z

140

Performance, Charging, and Second-use Considerations for Lithium Batteries for Plug-in Electric Vehicles  

E-Print Network (OSTI)

power required by the electric motor. The characteristics ofthe battery size and the electric motor and engine powers,electric range and electric motor power (mid-size passenger

Burke, Andrew

2009-01-01T23:59:59.000Z

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


141

Batteries - Home  

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

Advanced Battery Research, Development, and Testing Advanced Battery Research, Development, and Testing Argonne's Research Argonne plays a major role in the US Department of Energy's (DOE's) energy storage program within its Office of Vehicle Technologies. Activities include: Developing advanced anode and cathode materials under DOE's longer term exploratory R&D program Leading DOE's applied R&D program focused on improving lithium-ion (Li-Ion) battery technology for use in transportation applications Developing higher capacity electrode materials and electrolyte systems that will increase the energy density of lithium batteries for extended electric range PHEV applications Conducting independent performance and life tests on other advanced (Li-Ion, Ni-MH, Pb-Acid) batteries. Argonne's R&D focus is on advanced lithium battery technologies to meet the energy storage needs of the light-duty vehicle market.

142

Development of Production-Intent Plug-In Hybrid Vehicle Using Advanced Lithium-Ion Battery Packs with Deployment to a Demonstration Fleet  

SciTech Connect

The primary goal of this project was to speed the development of one of the first commercially available, OEM-produced plug-in hybrid electric vehicles (PHEV). The performance of the PHEV was expected to double the fuel economy of the conventional hybrid version. This vehicle program incorporated a number of advanced technologies, including advanced lithium-ion battery packs and an E85-capable flex-fuel engine. The project developed, fully integrated, and validated plug-in specific systems and controls by using GM’s Global Vehicle Development Process (GVDP) for production vehicles. Engineering Development related activities included the build of mule vehicles and integration vehicles for Phases I & II of the project. Performance data for these vehicles was shared with the U.S. Department of Energy (DOE). The deployment of many of these vehicles was restricted to internal use at GM sites or restricted to assigned GM drivers. Phase III of the project captured the first half or Alpha phase of the Engineering tasks for the development of a new thermal management design for a second generation battery module. The project spanned five years. It included six on-site technical reviews with representatives from the DOE. One unique aspect of the GM/DOE collaborative project was the involvement of the DOE throughout the OEM vehicle development process. The DOE gained an understanding of how an OEM develops vehicle efficiency and FE performance, while balancing many other vehicle performance attributes to provide customers well balanced and fuel efficient vehicles that are exciting to drive. Many vehicle content and performance trade-offs were encountered throughout the vehicle development process to achieve product cost and performance targets for both the OEM and end customer. The project team completed two sets of PHEV development vehicles with fully integrated PHEV systems. Over 50 development vehicles were built and operated for over 180,000 development miles. The team also completed four GM engineering development Buy-Off rides/milestones. The project included numerous engineering vehicle and systems development trips including extreme hot, cold and altitude exposure. The final fuel economy performance demonstrated met the objectives of the PHEV collaborative GM/DOE project. Charge depletion fuel economy of twice that of the non-PHEV model was demonstrated. The project team also designed, developed and tested a high voltage battery module concept that appears to be feasible from a manufacturability, cost and performance standpoint. The project provided important product development and knowledge as well as technological learnings and advancements that include multiple U.S. patent applications.

No, author

2013-09-29T23:59:59.000Z

143

Vehicle Technologies Office Merit Review 2014: Advanced in situ Diagnostic Techniques for Battery Materials  

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

Presentation given by Brookhaven National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about advanced in...

144

High-Power Electrochemical Storage Devices and Plug-in Hybrid Electric Vehicle Battery Development  

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

Presentation from the U.S. DOE Office of Vehicle Technologies "Mega" Merit Review 2008 on February 25, 2008 in Bethesda, Maryland.

145

KAir Battery  

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

KAir Battery, from Ohio State University, is commercializing highly energy efficient cost-effective potassium air batteries for use in the electrical stationary storage systems market (ESSS). Beyond, the ESSS market potential applications range from temporary power stations and electric vehicle.

146

Battery Thermal Management System Design Modeling (Presentation)  

SciTech Connect

Presents the objectives and motivations for a battery thermal management vehicle system design study.

Kim, G-H.; Pesaran, A.

2006-10-01T23:59:59.000Z

147

Cost-effectiveness of plug-in hybrid electric vehicle battery capacity and charging infrastructure investment for reducing US gasoline consumption  

Science Journals Connector (OSTI)

Federal electric vehicle (EV) policies in the United States currently include vehicle purchase subsidies linked to EV battery capacity and subsidies for installing charging stations. We assess the cost-effectiveness of increased battery capacity vs. nondomestic charging infrastructure installation for plug-in hybrid electric vehicles as alternate methods to reduce gasoline consumption for cars, trucks, and \\{SUVs\\} in the US. We find across a wide range of scenarios that the least-cost solution is for more drivers to switch to low-capacity plug-in hybrid electric vehicles (short electric range with gasoline backup for long trips) or gasoline-powered hybrid electric vehicles. If more gasoline savings are needed per vehicle, nondomestic charging infrastructure installation is substantially more expensive than increased battery capacity per gallon saved, and both approaches have higher costs than US oil premium estimates. Cost effectiveness of all subsidies are lower under a binding fuel economy standard. Comparison of results to the structure of current federal subsidies shows that policy is not aligned with fuel savings potential, and we discuss issues and alternatives.

Scott B. Peterson; Jeremy J. Michalek

2013-01-01T23:59:59.000Z

148

Vehicle Technologies Office Merit Review 2014: High-Voltage Solid...  

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

High-Voltage Solid Polymer Batteries for Electric Drive Vehicles Vehicle Technologies Office Merit Review 2014: High-Voltage Solid Polymer Batteries for Electric Drive Vehicles...

149

Qualitative thermal characterization and cooling of lithium batteries for electric vehicles  

Science Journals Connector (OSTI)

The paper deals with the cooling of batteries. The first step was the thermal characterization of a single cell of the module, which consists in the detection of the thermal field by means of thermographic tests during electric charging and discharging. The purpose was to identify possible critical hot points and to evaluate the cooling demand during the normal operation of an electric car. After that, a study on the optimal configuration to obtain the flattening of the temperature profile and to avoid hot points was executed. An experimental plant for cooling capacity evaluation of the batteries, using air as cooling fluid, was realized in our laboratory in ENEA Casaccia. The plant is designed to allow testing at different flow rate and temperatures of the cooling air, useful for the assessment of operative thermal limits in different working conditions. Another experimental facility was built to evaluate the thermal behaviour changes with water as cooling fluid. Experimental tests were carried out on the LiFePO4 batteries, under different electric working conditions using the two loops. In the future, different type of batteries will be tested and the influence of various parameters on the heat transfer will be assessed for possible optimal operative solutions.

A Mariani; F D'Annibale; G Boccardi; G P Celata; C Menale; R Bubbico; F Vellucci

2014-01-01T23:59:59.000Z

150

Non-Aqueous Battery Systems  

Science Journals Connector (OSTI)

...0 V. Practical non-aqueous batteries have energies extending from 100...electric watches to 20 kWh secondary batteries being developed for vehicle traction...10 years, to a military lithium thermal battery delivering all of its energy in...

1996-01-01T23:59:59.000Z

151

Vehicle Technologies Office Merit Review 2014: Development of Computer-Aided Design Tools for Automotive Batteries  

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

Presentation given by CD-Adapco at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about development of computer-aided...

152

Vehicle Technologies Office Merit Review 2014: Electric Drive and Advanced Battery and Components Testbed (EDAB)  

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

Presentation given by Idaho National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about Electric Drive and...

153

Vehicle Technologies Office Merit Review 2014: Stand-Alone Battery Thermal Management System  

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

Presentation given by DENSO International America, Inc. at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about stand-alone...

154

Vehicle Technologies Office Merit Review 2014: Development of Electrolytes for Lithium-ion Batteries  

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

Presentation given by University of Rhode Island at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about the development of...

155

Vehicle Technologies Office Merit Review 2014: Overview of the DOE Advanced Battery R&D Program  

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

Presentation given by U.S. Department of Energy at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting providing an overview of...

156

Vehicle Technologies Office Merit Review 2014: Electrode Architecture-Assembly of Battery Materials and Electrodes  

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

Presentation given by Hydro-Québec at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about electrode architecture-assembly...

157

Vehicle Technologies Office Merit Review 2014: Development of Computer-Aided Design Tools for Automotive Batteries  

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

Presentation given by General Motors at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about development of computer-aided...

158

Vehicle Technologies Office Merit Review 2014: Daikin Advanced Lithium Ion Battery Technology – High Voltage Electrolyte  

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

Presentation given by Daikin America at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about Daikin advanced lithium ion...

159

Simulations of Plug-in Hybrid Vehicles Using Advanced Lithium Batteries and Ultracapacitors on Various Driving Cycles  

E-Print Network (OSTI)

7: Simulation results for the batteries alone kW kW Batteryor even lithium-ion batteries. This is another advantagewith the air-electrode batteries. Table 6: Simulation

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

160

Batteries for Plug-in Hybrid Electric Vehicles (PHEVs): Goals and the State of Technology circa 2008  

E-Print Network (OSTI)

safety and cost. Third, Li-Ion battery designs are betterattributes of one type of Li-Ion battery cannot necessarilycapabilities. In any case, Li-Ion battery technologies hold

Axsen, Jonn; Burke, Andy; Kurani, Kenneth S

2008-01-01T23:59:59.000Z

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


161

Can innovative business models overcome resistance to electric vehicles? Better Place and battery electric cars in Denmark  

Science Journals Connector (OSTI)

This paper explores the geographical and policy context for an emergent business model from Better Place to deliver battery electric car mobility in Denmark. It argues that the combination of radically different technologies and a highly complex multi-agency operating environment theoretically provide the conditions and requirements for such an emergent business model. While focused on battery electric cars, renewable energy generation and smart grids, the paper has wider applicability to an understanding of the interplay between place, innovation and sustainability which suggests that diverse solutions are likely to be the characteristic solution rather than ubiquity and standardization. The paper argues, however, that the innovative business model, the deployment of electric vehicles, and the use of renewable energy systems, in this case largely based on wind power, while mutually supportive and contributing to wider policy aims with respect to the reduction of carbon emissions, may still fail in the face of entrenched practices. At the theoretical level it is concluded that theorization of business models needs a broader perspective beyond the typical ‘value creation, value capture’ rubric to better understand the wider role such models have in meeting societal goals, and to understand the structural impediments to organizational and technical innovation.

Thomas Budde Christensen; Peter Wells; Liana Cipcigan

2012-01-01T23:59:59.000Z

162

EV Everywhere: Innovative Battery Research Powering Up Plug-In...  

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

EV Everywhere: Innovative Battery Research Powering Up Plug-In Electric Vehicles EV Everywhere: Innovative Battery Research Powering Up Plug-In Electric Vehicles January 24, 2014 -...

163

Reality Check: Cheaper Batteries are GOOD for America's Electric...  

Energy Savers (EERE)

Reality Check: Cheaper Batteries are GOOD for America's Electric Vehicle Manufacturers Reality Check: Cheaper Batteries are GOOD for America's Electric Vehicle Manufacturers...

164

Modeling & Simulation - Batteries  

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

Production of Batteries for Electric and Hybrid Vehicles Production of Batteries for Electric and Hybrid Vehicles battery assessment graph Lithium-ion (Li-ion) batteries are currently being implemented in hybrid electric (HEV), plug-in hybrid electric (PHEV), and electric (EV) vehicles. While nickel metal-hydride will continue to be the battery chemistry of choice for some HEV models, Li-ion will be the dominate battery chemistry of the remaining market share for the near-future. Large government incentives are currently necessary for customer acceptance of the vehicles such as the Chevrolet Volt and Nissan Leaf. Understanding the parameters that control the cost of Li-ion will help researchers and policy makers understand the potential of Li-ion batteries to meet battery energy density and cost goals, thus enabling widespread adoption without incentives.

165

Batteries Breakout Session  

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

capture external conditions (consumer and infrastructure) * Capture Secondary use of batteries * EV100 Primary Vehicle, felt not practical? Barriers Interfering with Reaching the...

166

Draft Supplemental Environmental Assessment For General Motors LLC Electric Drive Vehicle Battery and Component Manufacturing Initiative White Marsh, Maryland, DOE/EA-1723S (December 2010)  

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

DRAFT SUPPLEMENTAL ENVIRONMENTAL DRAFT SUPPLEMENTAL ENVIRONMENTAL ASSESSMENT For General Motors LLC Electric Drive Vehicle Battery and Component Manufacturing Initiative White Marsh, Maryland May 2011 U.S. DEPARTMENT OF ENERGY NATIONAL ENERGY TECHNOLOGY LABORATORY U.S. Department of Energy General Motors National Energy Technology Laboratory Supplemental Environmental Assessment i May 2011 ACKNOWLEDGEMENT This report was prepared with the support of the U.S. Department of Energy (DOE) under Award Number DE-EE0002629. U.S. Department of Energy General Motors National Energy Technology Laboratory Supplemental Environmental Assessment ii May 2011 COVER SHEET Responsible Agency: U.S. Department of Energy (DOE) Title: General Motors LLC Electric Drive Vehicle Battery and Component Manufacturing

167

Polymer Electrolytes for Advanced Lithium Batteries | Department...  

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

Advanced Lithium Batteries Polymer Electrolytes for Advanced Lithium Batteries 2009 DOE Hydrogen Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation...

168

PHEV Battery Cost Assessment | Department of Energy  

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

PHEV Battery Cost Assessment PHEV Battery Cost Assessment 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting...

169

PHEV Battery Cost Assessment | Department of Energy  

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

PHEV Battery Cost Assessment PHEV Battery Cost Assessment 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation...

170

Vehicle Technologies Office: National Laboratories | Department...  

Office of Environmental Management (EM)

Technology R&D Center at Argonne National Laboratory Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions...

171

Challenges in Electric Vehicle Adoption and Vehicle-Grid Integration.  

E-Print Network (OSTI)

??With rapid innovation in vehicle and battery technology and strong support from governmental bodies and regulators, electric vehicles (EV) sales are poised to rise. While… (more)

Xi, Xiaomin

2013-01-01T23:59:59.000Z

172

Life Cycle Environmental Assessment of Lithium-Ion and Nickel Metal Hydride Batteries for Plug-In Hybrid and Battery Electric Vehicles  

Science Journals Connector (OSTI)

Infrastructure and transport requirements, though often generic, were always included. ... vehicles (PHEV), which use electricity from the grid to power a portion of travel, could play a role in reducing greenhouse gas (GHG) emissions from the transport sector; however, meaningful GHG emissions redns. ... storage systems in renewable energy plants, as well as power systems for sustainable vehicles, such as hybrid and elec. ...

Guillaume Majeau-Bettez; Troy R. Hawkins; Anders Hammer Strømman

2011-04-20T23:59:59.000Z

173

Evaluation of Zr(Ni, Mn){sub 2} Laves phase alloys as negative active material for Ni-MH electric vehicle batteries  

SciTech Connect

Laves phase alloys of compositions (Zr, Ti)(Ni, Mn, M){sub x} where M = Cr, V, Co, Al, and 1.9 < x < 2.1 with hexagonal C14 or cubic C15 structure have been studied in order to select the most suitable AB{sub 2} alloys as an active material for nickel-metal hydride (Ni-MH) batteries. With the selected alloy, feasibility of MH negative electrodes using industrial technology and containing more than 97% of the alloy powder has been demonstrated. 22 Ah Ni-MH batteries for electric vehicle application have been assembled, and 600 cycles have been achieved at steady C/3 charge and discharge rates and 80% depth of discharge.

Knosp, B. [Alcatel Alsthom Recherche, Marcoussis (France); Jordy, C.; Blanchard, P. [SAFT Research Dept., Marcoussis (France); Berlureau, T. [SAFT Advanced and Industrial Battery Div., Bordeaux (France)

1998-05-01T23:59:59.000Z

174

Advanced Vehicles Group: Center for Transportation Technologies and Systems  

SciTech Connect

Describes R&D in advanced vehicle systems and components (e.g., batteries) by NREL's Advanced Vehicles Group.

Not Available

2008-08-01T23:59:59.000Z

175

Applying the Battery Ownership Model in Pursuit of Optimal Battery...  

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

Ownership Model in Pursuit of Optimal Battery Use Strategies 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer...

176

Life Cycle Environmental Impact of High-Capacity Lithium Ion Battery with Silicon Nanowires Anode for Electric Vehicles  

Science Journals Connector (OSTI)

The grid electricity used in this analysis is average U.S. electricity mix with 89.56% of nonrenewable energies. ... The results demonstrate that the major opportunity for reducing the life cycle impacts of the battery pack is to use clean energy supply for battery operation, such as solar and wind electricity, which could reduce these environmental impacts significantly. ... All the above analyses including the life cycle inventory analysis, impact analysis, uncertainty, and sensitivity analysis together confirm that the LIB pack using SiNW anode from metal-assisted chemical etching could have environmental impacts comparable with those of conventional battery pack, while significantly increasing the battery energy storage and extending the driving range of EVs in the future. ...

Bingbing Li; Xianfeng Gao; Jianyang Li; Chris Yuan

2014-01-31T23:59:59.000Z

177

Vehicles Success Stories | Department of Energy  

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

is a group that funds electrochemical storage research and development. April 15, 2013 Johnson Controls Develops an Improved Vehicle Battery, Works to Cut Battery Costs in Half...

178

Hybrid Electric Vehicle Testing  

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

Transportation Association Conference Transportation Association Conference Vancouver, Canada December 2005 Hybrid Electric Vehicle Testing Jim Francfort U.S. Department of Energy - FreedomCAR & Vehicle Technologies Program, Advanced Vehicle Testing Activity INL/CON-05-00964 Presentation Outline * Background & goals * Testing partners * Hybrid electric vehicle testing - Baseline performance testing (new HEV models) - 1.5 million miles of HEV fleet testing (160k miles per vehicle in 36 months) - End-of-life HEV testing (rerun fuel economy & conduct battery testing @ 160k miles per vehicle) - Benchmark data: vehicle & battery performance, fuel economy, maintenance & repairs, & life-cycle costs * WWW information location Background * Advanced Vehicle Testing Activity (AVTA) - part of the

179

Polymers For Advanced Lithium Batteries | Department of Energy  

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

Polymers For Advanced Lithium Batteries Polymers For Advanced Lithium Batteries 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and...

180

Polymers For Advanced Lithium Batteries | Department of Energy  

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

Polymers For Advanced Lithium Batteries Polymers For Advanced Lithium Batteries 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and...

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


181

Development of Computer-Aided Design Tools for Automotive Batteries...  

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

More Documents & Publications Progress of Computer-Aided Engineering of Batteries (CAEBAT) Computer-Aided Engineering for Electric Drive Vehicle Batteries (CAEBAT)...

182

Overcharge Protection for PHEV Batteries | Department of Energy  

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

Overcharge Protection for PHEV Batteries Overcharge Protection for PHEV Batteries 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and...

183

Overview of the Batteries for Advanced Transportation Technologies...  

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

Overview of the Batteries for Advanced Transportation Technologies (BATT) Program Overview of the Batteries for Advanced Transportation Technologies (BATT) Program 2010 DOE Vehicle...

184

Automotive Li-ion Battery Cooling Requirements | Department of...  

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

Automotive Li-ion Battery Cooling Requirements Presents thermal management of lithium-ion battery packs for electric vehicles cunningham.pdf More Documents & Publications...

185

New INL High Energy Battery Test Facility | Department of Energy  

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

INL High Energy Battery Test Facility New INL High Energy Battery Test Facility 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and...

186

NREL Battery Thermal and Life Test Facility | Department of Energy  

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

NREL Battery Thermal and Life Test Facility NREL Battery Thermal and Life Test Facility 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit...

187

Abuse Testing of High Power Batteries | Department of Energy  

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

Testing of High Power Batteries Abuse Testing of High Power Batteries 2009 DOE Hydrogen Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting,...

188

Overview and Progress of the Battery Testing, Analysis, and Design...  

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

Battery Testing, Analysis, and Design Activity Overview and Progress of the Battery Testing, Analysis, and Design Activity 2012 DOE Hydrogen and Fuel Cells Program and Vehicle...

189

Li-Ion Battery Cell Manufacturing | Department of Energy  

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

Li-Ion Battery Cell Manufacturing Li-Ion Battery Cell Manufacturing 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer...

190

PHEV and LEESS Battery Cost Assessment | Department of Energy  

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

PHEV and LEESS Battery Cost Assessment PHEV and LEESS Battery Cost Assessment 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and...

191

Phylion Battery | Open Energy Information  

Open Energy Info (EERE)

Vehicles Product: Jiangsu-province-based producer of high-power high-energy Li-ion batteries for such uses as electric bicycles, hybrid vehicles, lighting, medical equipment,...

192

Vehicles | Department of Energy  

Energy Savers (EERE)

Calculator is an interactive tool that helps you plan a route, pick a car and estimate a fuel costs. Subtopics Alternative Fuel Vehicles Batteries Hydrogen & Fuel Cells Bioenergy...

193

Vehicle Technologies Office Merit Review 2014: Overcoming Processing Cost Barriers of High-Performance Lithium-Ion Battery Electrodes  

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

Presentation given by Oak Ridge National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about overcoming...

194

Vehicle Technologies Office Merit Review 2014: Significant Enhancement of Computational Efficiency in Nonlinear Multiscale Battery Model for Computer Aided Engineering  

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

Presentation given by NREL at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about significant enhancement of computational...

195

Vehicle Technologies Office Merit Review 2014: Innovative Manufacturing and Materials for Low-Cost Lithium-Ion Batteries  

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

Presentation given by Optodot Corporation at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about innovative manufacturing...

196

Vehicle Technologies Office Merit Review 2014: Wiring Up Silicon Nanostructures for High Energy Lithium-Ion Battery Anodes  

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

Presentation given by Stanford University at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about wiring up silicon...

197

Vehicle Technologies Office Merit Review 2014: Manufacturability Study and Scale-Up for Large Format Lithium Ion Batteries  

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

Presentation given by Oak Ridge National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about...

198

Vehicle Technologies Office's Research Recognized by R&D 100...  

Office of Environmental Management (EM)

Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels Modeling, Testing, Data & Results Education...

199

EcoCAR 3 Pushes the Vehicle Efficiency Envelope | Department...  

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

III Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels Modeling, Testing, Data & Results Education...

200

NREL: Vehicles and Fuels Research - Systems Analysis and Integration  

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

evaluates the impact of emerging technologies on efficiency, performance, cost, and battery life for a full range of vehicles-conventional vehicles, hybrid electric vehicles,...

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


201

Vehicle Technologies Office: 2012 Fuel and Lubricant Technologies...  

Energy Savers (EERE)

2008-2009 Fuels Technologies R&D Progress Report Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels...

202

Vehicle Technologies Office Merit Review 2014: Emissions Modeling...  

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

Feedstocks Vehicles Home About Vehicle Technologies Office Plug-in Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels Modeling, Testing, Data & Results...

203

Washington: Graphene Nanostructures for Lithium Batteries Recieves 2012 R&D 100 Award  

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

EERE-supported graphene nanostructures increases capacity of batteries, improves performance and convenience of electric vehicles.

204

Influence of Electric Vehicles Connected to the Grid Guangbin Li (gl2423) Influence of Electric Vehicles Connected to the Grid  

E-Print Network (OSTI)

vehicles and its meaning of research An electric vehicle refers to the vehicle powered from batteries that are only powered from internal batteries, called Battery Electric Vehicle (BEV); those that can be powered the fuel cell as its power, called Fuel Cell Electric Vehicle (FCEV). BEV achieves the "zero-release" goal

Lavaei, Javad

205

Vehicle Technologies Office Merit Review 2014: Post-Test Analysis of Lithium-Ion Battery Materials at Argonne National Laboratory  

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

Presentation given by Argonne National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about post-test...

206

Vehicle Technologies Office Merit Review 2014: Roll-to-Roll Electrode Processing NDE for Advanced Lithium Secondary Batteries  

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

Presentation given by Oak Ridge National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about roll-to-roll...

207

Vehicle Technologies Office Merit Review 2014: DC Fast Charging Effects on Battery Life and EVSE Efficiency and Security Testing  

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

Presentation given by Idaho National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about DC fast charging...

208

Vehicle Technologies Office Merit Review 2014: High Energy, Long Cycle Life Lithium-ion Batteries for EV Applications  

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

Presentation given by The Pennsylvania State University at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about high energy...

209

Vehicle Technologies Office Merit Review 2014: Real-time Metrology for Li-ion Battery R&D and Manufacturing  

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

Presentation given by Applied Spectra, Inc at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about real-time metrology for...

210

Batteries for Plug-in Hybrid Electric Vehicles (PHEVs): Goals and the State of Technology circa 2008  

E-Print Network (OSTI)

a PHEV has both an electric motor and a heat engine—usuallythe vehicle only by an electric motor using electricity fromand forth with the electric motor to maximize efficiency.

Axsen, Jonn; Burke, Andy; Kurani, Kenneth S

2008-01-01T23:59:59.000Z

211

Batteries for Plug-in Hybrid Electric Vehicles (PHEVs): Goals and the State of Technology circa 2008  

E-Print Network (OSTI)

chemistries. In summary, electric-drive interest groups,the present and future of electric-drive vehicles, including24 -vii- 1.0 Introduction Electric-drive continues to pique

Axsen, Jonn; Burke, Andy; Kurani, Kenneth S

2008-01-01T23:59:59.000Z

212

Vehicle Technologies Office: Upcoming Events | Department of...  

Energy Savers (EERE)

Electric Vehicles & Batteries Fuel Efficiency & Emissions Alternative Fuels Modeling, Testing, Data & Results Education & Workforce Development Financial Opportunities News Events...

213

Synthesis, Characterization and Performance of Cathodes for Lithium Ion Batteries  

E-Print Network (OSTI)

battery used for hybrid electric vehicles (HEVs) or electric vehicles (EVs) due to its low cost, low toxicity, thermal andthermal stability. 109-112 Thus, it proves to be a promising candidate cathode in battery

Zhu, Jianxin

2014-01-01T23:59:59.000Z

214

Rechargeable lithium battery energy storage systems for vehicular applications.  

E-Print Network (OSTI)

??Batteries are used on-board vehicles for broadly two applications – starting-lighting-ignition (SLI) and vehicle traction. This thesis examines the suitability of the rechargeable lithium battery… (more)

HURIA, TARUN

2012-01-01T23:59:59.000Z

215

Nuclear batteries  

Science Journals Connector (OSTI)

Nuclear batteries ... Describes the structure, operation, and application of nuclear batteries. ... Nuclear / Radiochemistry ...

Alfred B. Garrett

1956-01-01T23:59:59.000Z

216

Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Vehicle Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations to someone by E-mail Share Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations on Facebook Tweet about Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations on Twitter Bookmark Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations on Google Bookmark Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations on Delicious Rank Alternative Fuels Data Center: Electric Vehicle Supply Equipment (EVSE) and Battery Exchange Station Regulations on Digg Find More places to share Alternative Fuels Data Center: Electric

217

A Multi-Level Grid Interactive Bi-directional AC/DC-DC/AC Converter and a Hybrid Battery/Ultra-capacitor Energy Storage System with Integrated Magnetics for Plug-in Hybrid Electric Vehicles  

SciTech Connect

This study presents a bi-directional multi-level power electronic interface for the grid interactions of plug-in hybrid electric vehicles (PHEVs) as well as a novel bi-directional power electronic converter for the combined operation of battery/ultracapacitor hybrid energy storage systems (ESS). The grid interface converter enables beneficial vehicle-to-grid (V2G) interactions in a high power quality and grid friendly manner; i.e, the grid interface converter ensures that all power delivered to/from grid has unity power factor and almost zero current harmonics. The power electronic converter that provides the combined operation of battery/ultra-capacitor system reduces the size and cost of the conventional ESS hybridization topologies while reducing the stress on the battery, prolonging the battery lifetime, and increasing the overall vehicle performance and efficiency. The combination of hybrid ESS is provided through an integrated magnetic structure that reduces the size and cost of the inductors of the ESS converters. Simulation and experimental results are included as prove of the concept presenting the different operation modes of the proposed converters.

Onar, Omer C [ORNL] [ORNL

2011-01-01T23:59:59.000Z

218

Development of Computer-Aided Design Tools for Automotive Batteries...  

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

More Documents & Publications Progress of Computer-Aided Engineering of Batteries (CAEBAT) Vehicle Technologies Office Merit Review 2014: Development of...

219

EA-1723: General Motors LLC Electric Drive Vehicle Battery and Component Manufacturing Initiative Application White Marsh, Maryland and Wixom, Michigan  

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

DOE’s Proposed Action is to provide GM with $105,387,000 in financial assistance in a cost sharing arrangement to facilitate construction and operation of a manufacturing facility to produce electric motor components and assemble an electric drive unit. This Proposed Action through the Vehicle Technologies Program will accelerate the development and production of electric-drive vehicle systems and reduce the United States’ consumption of petroleum. This Proposed Action will also meaningfully assist in the nation’s economic recovery by creating manufacturing jobs in the United States in accordance with the objectives of the Recovery Act.

220

Battery-Powered Electric and Hybrid Electric Vehicle Projects to Reduce Greenhouse Gas Emissions: A Resource for Project Development  

SciTech Connect

The transportation sector accounts for a large and growing share of global greenhouse gas (GHG) emissions. Worldwide, motor vehicles emit well over 900 million metric tons of carbon dioxide (CO2) each year, accounting for more than 15 percent of global fossil fuel-derived CO2 emissions.1 In the industrialized world alone, 20-25 percent of GHG emissions come from the transportation sector. The share of transport-related emissions is growing rapidly due to the continued increase in transportation activity.2 In 1950, there were only 70 million cars, trucks, and buses on the world’s roads. By 1994, there were about nine times that number, or 630 million vehicles. Since the early 1970s, the global fleet has been growing at a rate of 16 million vehicles per year. This expansion has been accompanied by a similar growth in fuel consumption.3 If this kind of linear growth continues, by the year 2025 there will be well over one billion vehicles on the world’s roads.4 In a response to the significant growth in transportation-related GHG emissions, governments and policy makers worldwide are considering methods to reverse this trend. However, due to the particular make-up of the transportation sector, regulating and reducing emissions from this sector poses a significant challenge. Unlike stationary fuel combustion, transportation-related emissions come from dispersed sources. Only a few point-source emitters, such as oil/natural gas wells, refineries, or compressor stations, contribute to emissions from the transportation sector. The majority of transport-related emissions come from the millions of vehicles traveling the world’s roads. As a result, successful GHG mitigation policies must find ways to target all of these small, non-point source emitters, either through regulatory means or through various incentive programs. To increase their effectiveness, policies to control emissions from the transportation sector often utilize indirect means to reduce emissions, such as requiring specific technology improvements or an increase in fuel efficiency. Site-specific project activities can also be undertaken to help decrease GHG emissions, although the use of such measures is less common. Sample activities include switching to less GHG-intensive vehicle options, such as electric vehicles (EVs) or hybrid electric vehicles (HEVs). As emissions from transportation activities continue to rise, it will be necessary to promote both types of abatement activities in order to reverse the current emissions path. This Resource Guide focuses on site- and project-specific transportation activities. .

National Energy Technology Laboratory

2002-07-31T23:59:59.000Z

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


221

Batteries | Department of Energy  

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

Batteries Batteries Batteries A small New York City startup is hoping it has the next big solution in energy storage. A video documents what the company's breakthrough means for the future of grid-scale energy storage. Learn more. First invented by Thomas Edison, batteries have changed a lot in the past century, but there is still work to do. Improving this type of energy storage technology will have dramatic impacts on the way Americans travel and the ability to incorporate renewable energy into the nation's electric grid. On the transportation side, the Energy Department is working to reduce the costs and weight of electric vehicle batteries while increasing their energy storage and lifespan. The Department is also supports research, development and deployment of battery technologies that would allow the

222

Batteries - EnerDel Lithium-Ion Battery  

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

EnerDel/Argonne Advanced High-Power Battery for Hybrid Electric Vehicles EnerDel/Argonne Advanced High-Power Battery for Hybrid Electric Vehicles EnerDel lithium-ion battery The EnerDel Lithium-Ion Battery The EnerDel/Argonne lithium-ion battery is a highly reliable and extremely safe device that is lighter in weight, more compact, more powerful and longer-lasting than the nickel-metal hydride (Ni-MH) batteries in today's hybrid electric vehicles (HEVs). The battery is expected to meet the U.S. Advanced Battery Consortium's $500 manufacturing price criterion for a 25-kilowatt battery, which is almost a sixth of the cost to make comparable Ni-MH batteries intended for use in HEVs. It is also less expensive to make than comparable Li-ion batteries. That cost reduction is expected to help make HEVs more competitive in the marketplace and enable consumers to receive an immediate payback in

223

Vehicle Technologies Office Merit Review 2014: High Energy Lithium...  

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

High Energy Lithium Batteries for PHEV Applications Vehicle Technologies Office Merit Review 2014: High Energy Lithium Batteries for PHEV Applications Presentation given by...

224

Vehicle Technologies Office Merit Review 2014: Development of...  

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

Development of Electrolytes for Lithium-ion Batteries Vehicle Technologies Office Merit Review 2014: Development of Electrolytes for Lithium-ion Batteries Presentation given by...

225

2011 Nissan Leaf - VIN 0356 - Advanced Vehicle Testing - Baseline...  

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

Sheets (MSDS) for all unique hazardous materials the vehicle is equipped with, including Energy Storage System (ESS) batteries or capacitors, and auxiliary batteries. (3)...

226

2013 Chevrolet Malibu ECO Advanced Vehicle Testing - Baseline...  

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

Sheets (MSDS) for all unique hazardous materials the vehicle is equipped with, including Energy Storage System (ESS) batteries or capacitors, and auxiliary batteries. (3)...

227

2013 Chevrolte Volt - VIN 3929 - Advanced Vehicle Testing - Baseline...  

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

Sheets (MSDS) for all unique hazardous materials the vehicle is equipped with, including Energy Storage System (ESS) batteries or capacitors, and auxiliary batteries. (3)...

228

2011 Chevrolte Volt - VIN 0815 - Advanced Vehicle Testing - Baseline...  

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

Sheets (MSDS) for all unique hazardous materials the vehicle is equipped with, including Energy Storage System (ESS) batteries or capacitors, and auxiliary batteries. (3)...

229

2011 Hyundai Sonata Hybrid - vin 4932 Advanced Vehicle Testing...  

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

Sheets (MSDS) for all unique hazardous materials the vehicle is equipped with, including Energy Storage System (ESS) batteries or capacitors, and auxiliary batteries. (3)...

230

Batteries: Overview of Battery Cathodes  

SciTech Connect

The very high theoretical capacity of lithium (3829 mAh/g) provided a compelling rationale from the 1970's onward for development of rechargeable batteries employing the elemental metal as an anode. The realization that some transition metal compounds undergo reductive lithium intercalation reactions reversibly allowed use of these materials as cathodes in these devices, most notably, TiS{sub 2}. Another intercalation compound, LiCoO{sub 2}, was described shortly thereafter but, because it was produced in the discharged state, was not considered to be of interest by battery companies at the time. Due to difficulties with the rechargeability of lithium and related safety concerns, however, alternative anodes were sought. The graphite intercalation compound (GIC) LiC{sub 6} was considered an attractive candidate but the high reactivity with commonly used electrolytic solutions containing organic solvents was recognized as a significant impediment to its use. The development of electrolytes that allowed the formation of a solid electrolyte interface (SEI) on surfaces of the carbon particles was a breakthrough that enabled commercialization of Li-ion batteries. In 1990, Sony announced the first commercial batteries based on a dual Li ion intercalation system. These devices are assembled in the discharged state, so that it is convenient to employ a prelithiated cathode such as LiCoO{sub 2} with the commonly used graphite anode. After charging, the batteries are ready to power devices. The practical realization of high energy density Li-ion batteries revolutionized the portable electronics industry, as evidenced by the widespread market penetration of mobile phones, laptop computers, digital music players, and other lightweight devices since the early 1990s. In 2009, worldwide sales of Li-ion batteries for these applications alone were US$ 7 billion. Furthermore, their performance characteristics (Figure 1) make them attractive for traction applications such as hybrid electric vehicles (HEVs), plug-in hybrid electric vehicles (PHEVs), and electric vehicles (EVs); a market predicted to be potentially ten times greater than that of consumer electronics. In fact, only Liion batteries can meet the requirements for PHEVs as set by the U.S. Advanced Battery Consortium (USABC), although they still fall slightly short of EV goals. In the case of Li-ion batteries, the trade-off between power and energy shown in Figure 1 is a function both of device design and the electrode materials that are used. Thus, a high power battery (e.g., one intended for an HEV) will not necessarily contain the same electrode materials as one designed for high energy (i.e., for an EV). As is shown in Figure 1, power translates into acceleration, and energy into range, or miles traveled, for vehicular uses. Furthermore, performance, cost, and abuse-tolerance requirements for traction batteries differ considerably from those for consumer electronics batteries. Vehicular applications are particularly sensitive to cost; currently, Li-ion batteries are priced at about $1000/kWh, whereas the USABC goal is $150/kWh. The three most expensive components of a Li-ion battery, no matter what the configuration, are the cathode, the separator, and the electrolyte. Reduction of cost has been one of the primary driving forces for the investigation of new cathode materials to replace expensive LiCoO{sub 2}, particularly for vehicular applications. Another extremely important factor is safety under abuse conditions such as overcharge. This is particularly relevant for the large battery packs intended for vehicular uses, which are designed with multiple cells wired in series arrays. Premature failure of one cell in a string may cause others to go into overcharge during passage of current. These considerations have led to the development of several different types of cathode materials, as will be covered in the next section. Because there is not yet one ideal material that can meet requirements for all applications, research into cathodes for Li-ion batteries is, as of this writ

Doeff, Marca M

2010-07-12T23:59:59.000Z

231

Vehicle Technologies Office: Plug-in Electric Vehicle Basics  

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

Basics Basics Plug-in electric vehicles (PEVs), which include both plug-in hybrid electric vehicles and all-electric vehicles, use electricity as either their primary fuel or to improve efficiency. Commonly Used PEV Terms All-electric vehicle (AEV) - A vehicle with plug-in capability; driving energy comes entirely from its battery. Plug-in hybrid electric vehicle (PHEV) - A vehicle with plug-in capability; driving energy can come from either its battery or a liquid fuel like gasoline, diesel, or biofuels. Plug-in electric vehicle (PEV) - Any vehicle with plug-in capability. This includes AEVs and PHEVs. Hybrid electric vehicle (HEV) - A vehicle that has an electric drive system and battery but does not have plug-in capability; driving energy comes only from liquid fuel.

232

Electric and Gasoline Vehicle Lifecycle Cost and Energy-Use Model  

E-Print Network (OSTI)

analyses of the manufacturing cost of the key unique components of electric vehicles: batteries, fuel cells,

Delucchi, Mark; Burke, Andy; Lipman, Timothy; Miller, Marshall

2000-01-01T23:59:59.000Z

233

Battery systems performance studies - HIL components testing...  

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

systems performance studies - HIL components testing Battery systems performance studies - HIL components testing 2009 DOE Hydrogen Program and Vehicle Technologies Program Annual...

234

High Voltage Electrolyte for Lithium Batteries  

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

battery using high voltage high energy cathode materials to enable large-scale, cost competitive production of the next generation of electric-drive vehicles. To...

235

USABC Battery Separator Development | Department of Energy  

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

Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation es007smith2011p.pdf More Documents & Publications USABC Battery Separator Development Overview...

236

Kayo Battery Industries Group | Open Energy Information  

Open Energy Info (EERE)

Vehicles Product: Shenzhen-based company, started by Hong Kong Highpower Technology and Japan Kayo Group, active in producing Lithium and NiMH batteries for various applications...

237

Bubbles Help Break Energy Storage Record for Lithium Air-Batteries  

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

Bubbles Help Break Energy Storage Record for Lithium Air-Batteries Foam-base graphene keeps oxygen flowing in batteries that holds promise for electric vehicles January...

238

Commercializing Light-Duty Plug-In/Plug-Out Hydrogen-Fuel-Cell Vehicles: "Mobile Electricity" Technologies, Early California Household Markets, and Innovation Management  

E-Print Network (OSTI)

2002. EPRI, "Advanced Batteries for Electric-Drive Vehicles:12 2.2.2.1 PHEV uncertainties: Batteries andwith big propulsion batteries. However, recent activities (

Williams, Brett D

2010-01-01T23:59:59.000Z

239

An Activity-Based Assessment of the Potential Impacts of Plug-In Hybrid Electric Vehicles on Energy and Emissions Using One-Day Travel Data  

E-Print Network (OSTI)

by adding additional batteries to the design, allowing theincreases. Advanced Batteries for Electric-Drive Vehicles (generally require larger batteries with correspondingly

Recker, W. W.; Kang, J. E.

2010-01-01T23:59:59.000Z

240

Electric Vehicle Smart Charging Infrastructure  

E-Print Network (OSTI)

Vehicles on the US Power Grid." The 25th World Battery,infrastructure assignment and power grid impacts assessmentfrom the vehicle to the power grid and overcome its current

Chung, Ching-Yen

2014-01-01T23:59:59.000Z

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


241

Power Conditioning for Plug-In Hybrid Electric Vehicles  

E-Print Network (OSTI)

Plugin Hybrid Electric Vehicles (PHEVs) propel from the electric energy stored in the batteries and gasoline stored in the fuel tank. PHEVs and Electric Vehicles (EVs) connect to external sources to charge the batteries. Moreover, PHEVs can supply...

Farhangi, Babak

2014-07-25T23:59:59.000Z

242

Electric Drive Vehicle Level Control Development Under Various...  

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

3 The objective is to develop the entire vehicle thermal management system for two electric drive vehicles (HEVs, PHEVs). Limited battery power and low engine efficiency at...

243

Capturing the Usage of the German Car Fleet for a One Year Period to Evaluate the Suitability of Battery Electric Vehicles – A Model based Approach  

Science Journals Connector (OSTI)

Abstract The low driving range of battery electric vehicles (BEV) is often considered as relevant reason for the low BEV sales. In order to verify this assumption, the usage of conventional cars in Germany needs to be analyzed. These analyses may help to make more reliable and realistic statements to what extent German cars could be replaced by \\{BEVs\\} without restrictions for their users. Most travel surveys do only consider a single day or a short period of time in the analysis. Longer time periods should be taken into consideration when analyzing the travel data since the daily car usage is not identical every day. Since there are no representative and detailed car usage surveys over longer periods available a hybrid car usage model was developed to close that gap. This model is mainly based on three mobility surveys: the German Mobility Panel (MOP), the car mileage and fuel consumption survey, and the long distance travel survey INVERMO. We show that 13% of the modeled German private car fleet never exceeds 100 km per day during a full year and could be replaced by \\{BEVs\\} without any usage restrictions for their car owners. Another 16% of the modeled private car fleet is driven more than 100 km on 1-4 days during a full year and can be substituted with slight adjustments. These cars are often second cars of a household and used less intensively (6,600 km/year resp. 7600 km/year) than cars not suited for BEV substitution (14,800 km/year). Households that could replace their cars tend to have a lower disposable income. The crux of the matter, however, is that substitution of conventional cars is often not feasible since the mobility budget of BEV suited households tends to be too low or does not make economic sense due to the low annual mileage.

Christine Weiss; Bastian Chlond; Michael Heilig; Peter Vortisch

2014-01-01T23:59:59.000Z

244

Vehicle Technologies Office: Energy Storage  

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

Energy Storage Energy Storage Improving the batteries for electric drive vehicles, including hybrid electric (HEV) and plug-in electric (PEV) vehicles, is key to improving vehicles' economic, social, and environmental sustainability. In fact, transitioning to a light-duty fleet of HEVs and PEVs could reduce U.S. foreign oil dependence by 30-60% and greenhouse gas emissions by 30-45%, depending on the exact mix of technologies. For a general overview of electric drive vehicles, see the DOE's Alternative Fuel Data Center's pages on Hybrid and Plug-in Electric Vehicles and Vehicle Batteries. While a number of electric drive vehicles are available on the market, further improvements in batteries could make them more affordable and convenient to consumers. In addition to light-duty vehicles, some heavy-duty manufacturers are also pursuing hybridization of medium and heavy-duty vehicles to improve fuel economy and reduce idling.

245

Argonne TTRDC - Publications - Transforum 10.2 - Battery Facilities  

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

New Battery Facilities Will Help Accelerate Commercialization of Technologies New Battery Facilities Will Help Accelerate Commercialization of Technologies Gang Cheng tests batteries At existing Argonne battery testing labs, researcher Gang Cheng conducts an experiment to detect moisture in battery electrolytes. Moisture is detrimental to the performance and longevity of battery cells. Argonne will soon have three new battery facilities to bolster its research and development of battery materials and batteries for hybrid electric vehicles, plug-in hybrid electric vehicles and all other electric vehicles. The Lab was recently awarded $8.8 million in American Recovery and Reinvestment Act (ARRA) funding to build a Battery Prototype Cell Fabrication Facility, a Materials Production Scale-Up Facility and a Post-Test Analysis Facility.

246

Hybrid Vehicle Technology - Home  

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

* Batteries * Batteries * Modeling * Testing Hydrogen & Fuel Cells Materials Modeling, Simulation & Software Plug-In Hybrid Electric Vehicles PSAT Smart Grid Student Competitions Technology Analysis Transportation Research and Analysis Computing Center Working With Argonne Contact TTRDC Hybrid Vehicle Technology revolutionize transportation Argonne's Research Argonne researchers are developing and testing various hybrid electric vehicles (HEVs) and their components to identify the technologies, configurations, and engine control strategies that provide the best combination of high fuel economy and low emissions. Vehicle Validation Argonne also serves as the lead laboratory for hardware-in-the-loop (HIL) and technology validation for the U.S. Department of Energy (DOE). HIL is a

247

Plug-in Electric Vehicle Interactions with a Small Office Building: An Economic Analysis using DER-CAM  

E-Print Network (OSTI)

Environmental Benefits of Electric Vehicles Integration onof using plug-in hybrid electric vehicle battery packs forN ATIONAL L ABORATORY Plug-in Electric Vehicle Interactions

Momber, Ilan

2010-01-01T23:59:59.000Z

248

Horizon Batteries formerly Electrosource | Open Energy Information  

Open Energy Info (EERE)

Batteries formerly Electrosource Batteries formerly Electrosource Jump to: navigation, search Name Horizon Batteries (formerly Electrosource) Place Texas Sector Vehicles Product Manufacturer of high-power, light-weight batteries for use in electric and hybrid-electric vehicles, engine-starting and telecommunication stand-by power applications. References Horizon Batteries (formerly Electrosource)[1] LinkedIn Connections CrunchBase Profile No CrunchBase profile. Create one now! This article is a stub. You can help OpenEI by expanding it. Horizon Batteries (formerly Electrosource) is a company located in Texas . References ↑ "Horizon Batteries (formerly Electrosource)" Retrieved from "http://en.openei.org/w/index.php?title=Horizon_Batteries_formerly_Electrosource&oldid=346600

249

VEHICLE SPECIFICATIONS  

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

Page 1 of 5 Page 1 of 5 VEHICLE SPECIFICATIONS 1 Vehicle Features Base Vehicle: 2011 Nissan Leaf VIN: JN1AZ0CP5BT000356 Class: Mid-size Seatbelt Positions: 5 Type: EV Motor Type: Three-Phase, Four-Pole Permanent Magnet AC Synchronous Max. Power/Torque: 80 kW/280 Nm Max. Motor Speed: 10,390 rpm Cooling: Active - Liquid cooled Battery Manufacturer: Automotive Energy Supply Corporation Type: Lithium-ion - Laminate type Cathode/Anode Material: LiMn 2 O 4 with LiNiO 2 /Graphite Pack Location: Under center of vehicle Number of Cells: 192 Cell Configuration: 2 parallel, 96 series Nominal Cell Voltage: 3.8 V Nominal System Voltage: 364.8 V Rated Pack Capacity: 66.2 Ah Rated Pack Energy: 24 kWh Max. Cell Charge Voltage 2 : 4.2 V Min. Cell Discharge Voltage 2 : 2.5 V

250

Batteries: Overview of Battery Cathodes  

E-Print Network (OSTI)

insertion reactions. For Li-ion battery materials, it refersis widespread throughout the Li-ion battery literature, thisthe chemistry of the Li-ion battery is not fixed, unlike the

Doeff, Marca M

2011-01-01T23:59:59.000Z

251

Design and fabrication of evaporators for thermo-adsorptive batteries  

E-Print Network (OSTI)

Current heating and cooling within electric vehicles places a significant demand on the battery, greatly reducing their potential driving range. An Advanced Thermo- Adsorptive Battery (ATB) reduces this load by storing ...

Farnham, Taylor A

2014-01-01T23:59:59.000Z

252

High Voltage Electrolytes for Li-ion Batteries | Department of...  

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

Electrolytes for Li-ion Batteries High Voltage Electrolytes for Li-ion Batteries 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and...

253

Abuse Testing of High Power Batteries | Department of Energy  

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

Abuse Testing of High Power Batteries Abuse Testing of High Power Batteries Presentation from the U.S. DOE Office of Vehicle Technologies "Mega" Merit Review 2008 on February 25,...

254

Overview of Battery R&D Activities | Department of Energy  

Energy Savers (EERE)

of Battery R&D Activities Overview of Battery R&D Activities 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation...

255

Overview of Battery R&D Activities | Department of Energy  

Energy Savers (EERE)

of Battery R&D Activities Overview of Battery R&D Activities 2011 DOE Hydrogen and Fuel Cells Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation...

256

Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Batteries for Hybrid Batteries for Hybrid and Plug-In Electric Vehicles to someone by E-mail Share Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on Facebook Tweet about Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on Twitter Bookmark Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on Google Bookmark Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on Delicious Rank Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on Digg Find More places to share Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles on AddThis.com... More in this section... Electricity Basics Benefits & Considerations

257

Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Infrastructure and Battery Tax Exemptions to someone by E-mail Infrastructure and Battery Tax Exemptions to someone by E-mail Share Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on Facebook Tweet about Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on Twitter Bookmark Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on Google Bookmark Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on Delicious Rank Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on Digg Find More places to share Alternative Fuels Data Center: Electric Vehicle (EV) Infrastructure and Battery Tax Exemptions on AddThis.com...

258

> 070131-073Vehicle  

E-Print Network (OSTI)

-how developed with the design ofthe ROAZ ASV [3] [4]. Power is provided by electric batteries. The computer> 070131-073Vehicle for Network Centric Operations H. Ferreira-The design and development of the Swordfish Autonomous Surface Vehicle (ASV) system is discussed. Swordfish

Marques, Eduardo R. B.

259

Vehicles Success Stories | Department of Energy  

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

the next generation of hybrid and electric vehicles. February 10, 2014 Washington: Graphene Nanostructures for Lithium Batteries Recieves 2012 R&D 100 Award EERE-supported...

260

Advanced Technology Vehicle Lab Benchmarking - Level 1  

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

HEV (PHEV) * Battery Electric (BEV or EV) * Fuel Cell Vehicle Alternative fuels * Hydrogen, Natural Gas * Ethanol, Butanol * Diesel (Bio, Fisher-Tropsch) APRF Test Process:...

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


261

Advanced Technology Vehicle Lab Benchmarking - Level 1  

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

* Hybrid Electric (HEV) * Plug-in HEV (PHEV) * Battery Electric (BEV or EV) * Fuel Cell Vehicle Alternative fuels * Hydrogen * Ethanol, Butanol * Diesel (Bio,...

262

Vehicle Technologies Office Merit Review 2014: Manufacturability...  

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

Batteries Presentation given by Oak Ridge National Laboratory at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation...

263

Thermal management optimization of an air-cooled Li-ion battery module using pin-fin heat sinks for hybrid electric vehicles  

Science Journals Connector (OSTI)

Abstract Three dimensional transient thermal analysis of an air-cooled module that contains prismatic Li-ion cells next to a special kind of aluminum pin fin heat sink whose heights of pin fins increase linearly through the width of the channel in air flow direction was studied for thermal management of Lithium-ion battery pack. The effects of pin fins arrangements, discharge rates, inlet air flow velocities, and inlet air temperatures on the battery were investigated. The results showed that despite of heat sinks with uniform pin fin heights that increase the standard deviation of the temperature field, using this kind of pin fin heat sink compare to the heat sink without pin fins not only decreases the bulk temperature inside the battery, but also decreases the standard deviation of the temperature field inside the battery as well. Increasing the inlet air temperature leads to decreasing the standard deviation of the temperature field while increases the maximum temperature of the battery. Furthermore, increasing the inlet air velocity first increases the standard deviation of the temperature field till reaches to the maximum point, and after that decreases. Also, increasing the inlet air velocity leads to decrease in the maximum temperature of the battery.

Shahabeddin K. Mohammadian; Yuwen Zhang

2015-01-01T23:59:59.000Z

264

Argonne TTRDC - APRF - Research Activities - Ultracapacitors with Batteries  

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

Active Combination of Ultracapacitors with Batteries for PHEVs Active Combination of Ultracapacitors with Batteries for PHEVs Ultracapacitors Ultracapacitors will dramatically boost the power of lithium-ion batteries, enabling plug-in vehicles to travel much further on a single charge. Lithium-ion battery The newest generation of lithium-ion battery (foreground) has an energy density three times that of the batteries in today's electric cars (background). Argonne researchers are investigating the benefits of combining ultracapacitors with lithium-ion batteries. This combination can dramatically boost the power of lithium-ion batteries, offering a potential solution to the battery-related challenges facing electric vehicles. This technology can: Exponentially increase the calendar and cycle lifetimes of lithium-ion batteries

265

Making Li-air batteries rechargeable: material challenges  

SciTech Connect

A Li-air battery could potentially provide three to five times higher energy density/specific energy than conventional batteries, thus enable the driving range of an electric vehicle comparable to a gasoline vehicle. However, making Li-air batteries rechargeable presents significant challenges, mostly related with materials. Herein, we discuss the key factors that influence the rechargeability of Li-air batteries with a focus on nonaqueous system. The status and materials challenges for nonaqueous rechargeable Li-air batteries are reviewed. These include electrolytes, cathode (electocatalysts), lithium metal anodes, and oxygen-selective membranes (oxygen supply from air). The perspective of rechargeable Li-air batteries is provided.

Shao, Yuyan; Ding, Fei; Xiao, Jie; Zhang, Jian; Xu, Wu; Park, Seh Kyu; Zhang, Jiguang; Wang, Yong; Liu, Jun

2013-02-25T23:59:59.000Z

266

EV Everywhre Grand Challenge - Battery Status and Cost Reduction...  

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

EV Everywhere Grand Challenge Battery Status and Cost Reduction Prospects July 26, 2012 David Howell Team Lead, Hybrid & Electric Systems Vehicle Technologies Program U.S....

267

Overview and Progress of the Batteries for Advanced Transportation...  

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

Technologies Overview and Progress of the Batteries for Advanced Transportation Technologies 2013 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit...

268

Electric Drive and Advanced Battery and Components Testbed (EDAB...  

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

and Peer Evaluation Meeting vss033carlson2012o.pdf More Documents & Publications Electric Drive and Advanced Battery and Components Testbed (EDAB) Vehicle Technologies Office...

269

High capacity nanostructured electrode materials for lithium-ion batteries.  

E-Print Network (OSTI)

??The lithium-ion battery is currently the most widely used electrochemical storage system on the market, with applications ranging from portable electronics to electric vehicles, to… (more)

Seng, Kuok H

2013-01-01T23:59:59.000Z

270

Battery Thermal Modeling and Testing | Department of Energy  

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

Program, and Vehicle Technologies Program Annual Merit Review and Peer Evaluation es110smith2011p.pdf More Documents & Publications NREL Battery Thermal and Life Test Facility...

271

Impact of Battery Management on Fuel Efficiency Validity | Department...  

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

Validity Impact of Battery Management on Fuel Efficiency Validity 2012 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer...

272

Role of Recycling in the Life Cycle of Batteries  

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

ROLE OF RECYCLING IN THE LIFE CYCLE OF BATTERIES ROLE OF RECYCLING IN THE LIFE CYCLE OF BATTERIES J.L. Sullivan, L. Gaines, and A. Burnham Argonne National Laboratory, Energy Systems Division Keywords: battery, materials, recycling, energy Abstract Over the last few decades, rechargeable battery production has increased substantially. Applications including phones, computers, power tools, power storage, and electric-drive vehicles are either commonplace or will be in the next decade or so. Because advanced rechargeable batteries, like those

273

Accomodating Electric Vehicles  

E-Print Network (OSTI)

Accommodating Electric Vehicles Dave Aasheim 214-551-4014 daasheim@ecotality.com A leader in clean electric transportation and storage technologies ECOtality North America Overview Today ? Involved in vehicle electrification... ECOtality North America Overview Today ?Warehouse Material Handling ? Lift trucks ? Pallet Jacks ? Over 200 Customers ? Over 5,000 Installations ECOtality North America Overview Today ? 1990?s involved in EV1 ? EV Chargers ? Vehicle & battery...

Aasheim, D.

2011-01-01T23:59:59.000Z

274

Electric Vehicle Basics | Department of Energy  

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

Electric Vehicle Basics Electric Vehicle Basics Electric Vehicle Basics July 30, 2013 - 4:45pm Addthis Text Version Photo of an electric bus driving up a hill. Electricity can be used as a transportation fuel to power battery electric vehicles (EVs). EVs store electricity in an energy storage device, such as a battery. The electricity powers the vehicle's wheels via an electric motor. EVs have limited energy storage capacity, which must be replenished by plugging into an electrical source. In an electric vehicle, a battery or other energy storage device is used to store the electricity that powers the motor. EV batteries must be replenished by plugging the vehicle to a power source. Some EVs have onboard chargers; others plug into a charger located outside the vehicle. Both types use electricity that comes from the power grid. Although

275

NREL: Learning - Fuel Cell Vehicle Basics  

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

then stored in a battery that powers the vehicle's electric motor and other electric-powered equipment. For more information about fuel cell vehicles, visit the U.S. Department...

276

VEHICLE SPECIFICATIONS  

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

VEHICLE SPECIFICATIONS 1 Vehicle Features Base Vehicle: 2011 Chevrolet Volt VIN: 1G1RD6E48BUI00815 Class: Compact Seatbelt Positions: 4 Type 2 : Multi-Mode PHEV (EV, Series, and Power-split) Motor Type: 12-pole permanent magnet AC synchronous Max. Power/Torque: 111 kW/370 Nm Max. Motor Speed: 9500 rpm Cooling: Active - Liquid cooled Generator Type: 16-pole permanent magnet AC synchronous Max. Power/Torque: 55 kW/200 Nm Max. Generator Speed: 6000 rpm Cooling: Active - Liquid cooled Battery Manufacturer: LG Chem Type: Lithium-ion Cathode/Anode Material: LiMn 2 O 4 /Hard Carbon Number of Cells: 288 Cell Config.: 3 parallel, 96 series Nominal Cell Voltage: 3.7 V Nominal System Voltage: 355.2 V Rated Pack Capacity: 45 Ah Rated Pack Energy: 16 kWh Weight of Pack: 435 lb

277

Temperature maintained battery system  

SciTech Connect

A chassis contains a battery charger connected to a multi-cell battery. The charger receives direct current from an external direct current power source and has means to automatically selectively charge the battery in accordance with a preselected charging program relating to temperature adjusted state of discharge of the battery. A heater device is positioned within the chassis which includes heater elements and a thermal switch which activates the heater elements to maintain the battery above a certain predetermined temperature in accordance with preselected temperature conditions occurring within the chassis. A cooling device within the chassis includes a cooler regulator, a temperature sensor, and peltier effect cooler elements. The cooler regulator activates and deactivates the peltier cooler elements in accordance with preselected temperature conditions within the chassis sensed by the temperature sensor. Various vehicle function circuitry may also be positioned within the chassis. The contents of the chassis are positioned to form a passage proximate the battery in communication with an inlet and outlet in the chassis to receive air for cooling purposes from an external source.

Newman, W.A.

1980-10-21T23:59:59.000Z

278

Thermal Modeling and Effects of Electrode Configuration on Thermal Behaviour of a LiFePO4 Battery  

Science Journals Connector (OSTI)

Li-ion battery has great application prospects on electric vehicles ... etc. For the performance of Li-ion battery is closely related to its operating temperature, the battery thermal management technique is cons...

Cheng Ruan; Kun Diao; Huajie Chen; Yan Zhou…

2013-01-01T23:59:59.000Z

279

Candidate Fuels for Vehicle Fuel Cell Power Systems  

E-Print Network (OSTI)

engine vehicle, HEV = hybrid (battery/ICE) electric vehicle, NG SR = natural gas steam reformer indicated that long-term operating costs for FCVs could be competitive with conventional vehicles... 0 1 ... but that ownership costs are much higher due to high vehicle purchase costs. Vehicle Ownership CostVehicle Ownership

280

Vehicle Technologies Office: Key Activities in Vehicles  

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

Activities in Vehicles Activities in Vehicles We conduct work in four key areas to develop and deploy vehicle technologies that reduce the use of petroleum while maintaining or improving performance, power, and comfort. Research and development (R&D); testing and analysis; government and community stakeholder support; and education help people access and use efficient, clean vehicles that meet their transportation needs. Researcher loads a sample mount of battery cathode materials for X-ray diffraction, an analysis tool for obtaining information on the crystallographic structure and composition of materials. Research and Development of New Technologies Develop durable and affordable advanced batteries as well as other forms of energy storage. Improve the efficiency of combustion engines.

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


281

Alternative Fuels Data Center: Hybrid Electric Vehicles  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Hybrid Electric Hybrid Electric Vehicles to someone by E-mail Share Alternative Fuels Data Center: Hybrid Electric Vehicles on Facebook Tweet about Alternative Fuels Data Center: Hybrid Electric Vehicles on Twitter Bookmark Alternative Fuels Data Center: Hybrid Electric Vehicles on Google Bookmark Alternative Fuels Data Center: Hybrid Electric Vehicles on Delicious Rank Alternative Fuels Data Center: Hybrid Electric Vehicles on Digg Find More places to share Alternative Fuels Data Center: Hybrid Electric Vehicles on AddThis.com... More in this section... Electricity Basics Benefits & Considerations Stations Vehicles Availability Conversions Emissions Batteries Deployment Maintenance & Safety Laws & Incentives Hybrids Plug-In Hybrids All-Electric Vehicles Hybrid Electric Vehicles

282

Fuel Cell Powered Vehicles Using Supercapacitors: Device Characteristics, Control Strategies, and Simulation Results  

E-Print Network (OSTI)

considered: (a) Direct hydrogen fuel cell vehicles (FCVs)has focused mainly on hydrogen fuel cells and batteries.are considered: Direct hydrogen fuel cell vehicles (FCVs)

Zhao, Hengbing; Burke, Andy

2010-01-01T23:59:59.000Z

283

Chongqing Wanli Storage Battery Co | Open Energy Information  

Open Energy Info (EERE)

Wanli Storage Battery Co Wanli Storage Battery Co Jump to: navigation, search Name Chongqing Wanli Storage Battery Co. Place Chongqing Municipality, China Sector Solar, Vehicles, Wind energy Product The scope of Wanli's power storage business includes batteries made for electric motorcycles and industrial vehicles, boats, and cars. It also includes batteries to store power from solar or wind power plants. References Chongqing Wanli Storage Battery Co.[1] LinkedIn Connections CrunchBase Profile No CrunchBase profile. Create one now! This article is a stub. You can help OpenEI by expanding it. Chongqing Wanli Storage Battery Co. is a company located in Chongqing Municipality, China . References ↑ "Chongqing Wanli Storage Battery Co." Retrieved from "http://en.openei.org/w/index.php?title=Chongqing_Wanli_Storage_Battery_Co&oldid=34358

284

Progress in research on the performance and service life of batteries membrane of new energy automotive  

Science Journals Connector (OSTI)

Batteries membrane materials are widely used in new energy automotives such as hybrid vehicles, fuel cell vehicles, and pure electric vehicles. Membrane consists of two categories: fuel cell membrane (power unit)...

Yong Li; Jian Song; Jie Yang

2012-11-01T23:59:59.000Z

285

Vehicle Technologies Office Merit Review 2014: Utilization of UV or EB Curing Technology to Significantly Reduce Costs and VOCs in the Manufacture of Lithium-Ion Battery Electrodes  

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

Presentation given by Miltec UV International at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about the utilization of UV...

286

Vehicle Technologies Office Merit Review 2014: Development of Cell/Pack Level Models for Automotive Li-Ion Batteries with Experimental Validation  

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

Presentation given by EC Power at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about evelopment of cell/pack level models...

287

Vehicle Technologies Office Merit Review 2014: Coupling of Mechanical Behavior of Cell Components to Electrochemical-Thermal Models for Computer-Aided Engineering of Batteries under Abuse  

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

Presentation given by NREL at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and Peer Evaluation Meeting about coupling of mechanical behavior of cell...

288

Boosting batteries | EMSL  

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

Boosting batteries Boosting batteries Broad use possible for lithium-silicon batteries Findings could pave the way for widespread adoption of lithium ion batteries for applications...

289

Advancing Next-Generation Vehicles  

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

the U.S. Department of Energy's (DOE's) lead laboratory for researching advanced vehicle technologies, including hy- the U.S. Department of Energy's (DOE's) lead laboratory for researching advanced vehicle technologies, including hy- brid, plug-in hybrid, battery electric, and alternative fuel vehicles, Argonne provides transportation research critical to advancing the development of next-generation vehicles. Central to this effort is the Lab's Advanced Powertrain Research Facility (APRF), an integrated four-wheel drive chassis dynamometer and component test facility.

290

Categorical Exclusion Determinations: Advanced Technology Vehicles  

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

Technology Vehicles Technology Vehicles Manufacturing Loan Program Categorical Exclusion Determinations: Advanced Technology Vehicles Manufacturing Loan Program Categorical Exclusion Determinations issued by Advanced Technology Vehicles Manufacturing Loan Program. DOCUMENTS AVAILABLE FOR DOWNLOAD May 29, 2012 CX-008810: Categorical Exclusion Determination One Nevada Optimization of Microwave Telecommunication System CX(s) Applied: B1.19, B4.6 Date: 05/29/2012 Location(s): Nevada, Nevada Offices(s): Advanced Technology Vehicles Manufacturing Loan Program January 24, 2012 CX-007677: Categorical Exclusion Determination Project Eagle Phase 1 Direct Wafer/Cell Solar Facility CX(s) Applied: B1.31 Date: 01/24/2012 Location(s): Massachusetts Offices(s): Advanced Technology Vehicles Manufacturing Loan Program

291

NREL: Vehicles and Fuels Research - Publications  

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

Publications Publications NREL researchers document their findings in technical reports, conference papers, journal articles, and fact sheets. Visit the following online resources to find publications about alternative and advanced transportation technologies and systems. NREL Publications Database This database features a wide variety of publications produced by NREL from 1977 to the present. Search the database or find publications according to these popular key words: Advanced vehicles and systems | Alternative fuels | Batteries | Electric vehicles | Energy storage | Fuel cell vehicles | Hybrid electric vehicles | Plug-in electric vehicles | Vehicle analysis | Vehicle modeling | Vehicle emissions Selected Publications Read selected publications related to our vehicles and fuels projects:

292

SECONDARY BATTERIES – LITHIUM RECHARGEABLE SYSTEMS | Overview  

Science Journals Connector (OSTI)

Rechargeable lithium batteries have conquered the markets for portable consumer electronics and, recently, for electric vehicles. Lithium, the lightest and one of the most reactive of metals, having the greatest electrochemical potential (E°=–3.045 V), provides very high energy and power densities in batteries. As lithium metal reacts violently with water and can ignite into flame, modern lithium-ion batteries use carbon negative electrode and lithium metal oxide positive electrode. The electrolyte is usually based on a lithium salt in organic solution. Thin-film batteries use solid oxide or polymer electrolytes. Rechargeable lithium-ion batteries (containing an intercalation negative electrode) should not be confused with nonrechargeable lithium primary batteries (containing metallic lithium). This article outlines energy storage in lithium batteries, basic cell chemistry, positive electrode materials, negative electrode materials, electrolytes, and state-of-charge (SoC) monitoring.

P. Kurzweil; K. Brandt

2009-01-01T23:59:59.000Z

293

Battery system including batteries that have a plurality of positive terminals and a plurality of negative terminals  

DOE Patents (OSTI)

A lithium battery for use in a vehicle includes a container, a plurality of positive terminals extending from a first end of the lithium battery, and a plurality of negative terminals extending from a second end of the lithium battery. The plurality of positive terminals are provided in a first configuration and the plurality of negative terminals are provided in a second configuration, the first configuration differing from the second configuration. A battery system for use in a vehicle may include a plurality of electrically connected lithium cells or batteries.

Dougherty, Thomas J; Symanski, James S; Kuempers, Joerg A; Miles, Ronald C; Hansen, Scott A; Smith, Nels R; Taghikhani, Majid; Mrotek, Edward N; Andrew, Michael G

2014-01-21T23:59:59.000Z

294

Vehicle Technologies Office Merit Review 2014: Post-Test Analysis...  

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

Post-Test Analysis of Lithium-Ion Battery Materials at Argonne National Laboratory Vehicle Technologies Office Merit Review 2014: Post-Test Analysis of Lithium-Ion Battery...

295

Advanced Battery Manufacturing Making Strides in Oregon | Department of  

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

Advanced Battery Manufacturing Making Strides in Oregon Advanced Battery Manufacturing Making Strides in Oregon Advanced Battery Manufacturing Making Strides in Oregon February 16, 2012 - 12:09pm Addthis EnerG2 Ribbon Cutting Ceremony for new battery materials plant in Albany, Oregon. Photo courtesy of the Vehicle Technologies Program EnerG2 Ribbon Cutting Ceremony for new battery materials plant in Albany, Oregon. Photo courtesy of the Vehicle Technologies Program Patrick B. Davis Patrick B. Davis Vehicle Technologies Program Manager What are the key facts? Through the Recovery Act, the Department has invested $2.4 billion dollars to help the U.S. compete in the electric drive vehicle and component manufacturing industry. The company EnerG2 is expected to produce enough material to support 60,000 electric drive vehicles per year for American families across the

296

NREL/CCSE PEV Battery Second Use Project (Presentation)  

SciTech Connect

This presentation describes the Battery Second Use Project. Preliminary analysis results show (1) the impact of competing technologies, (2) potential revenue generation, and (3) supply and demand of the second use of plug-in electric vehicle batteries. The impact of competing technologies are: maximum salve value of a used battery will be limited by future battery prices, under favorable conditions, second use can only discount today's battery prices by 12% or less, however, second use will offer batteries to second applications at reduced cost (typically < $170/kWh). Revenue streams are highly variable, allowable battery costs are highly sensitive to balance-of-system costs, and batteries need to be very cheap for these applications to be viable. Supply and demand show that high-value applications have both competition and small markets, and supply from plug-in electric vehicles has the potential to overwhelm many second use markets.

Neubauer, J.; Pesaran, A.

2011-09-01T23:59:59.000Z

297

EMSL - batteries  

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

batteries en Magnesium behavior and structural defects in Mg+ ion implanted silicon carbide. http:www.emsl.pnl.govemslwebpublicationsmagnesium-behavior-and-structural-defects-...

298

EVS-25 Shenzhen, China, Nov. 5-9, 2010 The 25th World Battery, Hybrid and Fuel Cell Electric Vehicle Symposium & Exhibition  

E-Print Network (OSTI)

and regional resolution the likely grid impacts of defensible penetration scenario in the US for the 2030 impacts of generating electricity, which then in turn has electric rate impacts to rate payers are the impacts of a plausible penetration of plug- in hybrid electric vehicles (PHEVs) on the electricity

299

DOE Issues Request for Information on Fuel Cells for Continuous On-Board Recharging for Battery Electric Light-Duty Vehicles  

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

The USDOE's Fuel Cell Technologies Office has issued an RFI seeking feedback from the research community and relevant stakeholders about fuel cell technology validation, commercial acceleration, and potential deployment strategies for continuous fuel cell rechargers on board light-duty electric vehicle fleets.

300

Comparative efficiency and driving range of light- and heavy-duty vehicles powered with biomass energy stored in liquid fuels or batteries  

Science Journals Connector (OSTI)

...L (6.8 mi/gal diesel...criteria pollutants is in general not a substantial...Medium- and Heavy-Duty Engines and Vehicles, A Proposed...and-heavy-duty-engines#p-401. Accessed June...the internal combustion engine...

Mark Laser; Lee R. Lynd

2014-01-01T23:59:59.000Z

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


301

BOOK CHAPTERS 1. B.Y. Liaw, M. Dubarry, "A roadmap to understand battery performance in electric and hybrid  

E-Print Network (OSTI)

and hybrid vehicle operation," in Electric and Hybrid Vehicles. Power Sources, Models, Sustainability and life prediction," in Industrial Applications of Batteries: From Electric Vehicles to Satellites, M, Estimation and Control of Hybrid Electrical Vehicles Batteries", in the Proceedings of the IEEE International

302

Construction of an Electric Vehicle Implemented in Egypt  

E-Print Network (OSTI)

The design and manufacture of electric vehicles is becoming important with the rising cost of petrol, and the effect of emissions from petrol powered vehicles on our environment. Operating a battery electric vehicle will eliminate emissions inside our cities and reduce our dependence on oil. The number of electric vehicles on the roads is increasing every year as people become more environmentally conscious and gasoline prices are volatile. This study produces a design and construction a battery electric vehicle, and describes the process of constructing and testing of an electric vehicle. This design comprises many steps from choosing the vehicle design, sizing a motor, and the type of batteries used. Finally, a set of experimental results which showing the performance of the designed electric vehicle under certain conditions were conducted. Key Words: electric vehicle, performance, experimental work, lead-acid battery and DC electric motor.

unknown authors

303

Argonne Transportation - Lithium Battery Technology Patents  

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

Awarded Lithium Battery Technology Patents Awarded Lithium Battery Technology Patents "Composite-structure" material is a promising battery electrode for electric vehicles Argonne National Laboratory has been granted two U.S. patents (U.S. Pat. 6,677,082 and U.S. Pat. 6,680,143) on new "composite-structure" electrode materials for rechargeable lithium-ion batteries. Electrode compositions of this type are receiving worldwide attention. Such electrodes offer superior cost and safety features over state-of-the-art LiCoO2 electrodes that power conventional lithium-ion batteries. Moreover, they demonstrate outstanding cycling stability and can be charged and discharged at high rates, making them excellent candidates to replace LiCoO2 for consumer electronic applications and hybrid electric vehicles.

304

Alternative battery systems for transportation uses  

ScienceCinema (OSTI)

Argonne Distinguished Fellow Michael Thackeray highlights the need for alternative battery systems for transportation uses. Such systems will not only need to be smaller, lighter and more energy dense, but also able to make electric vehicles more competitive with internal combustion engine vehicles.

Michael Thackeray

2013-06-05T23:59:59.000Z

305

Batteries: Overview of Battery Cathodes  

E-Print Network (OSTI)

materials, although electro-active compounds containing these metals exist. Today’s technologically important cathodesactive field. Characteristics of battery cathode materials

Doeff, Marca M

2011-01-01T23:59:59.000Z

306

Vehicle Technologies Office Merit Review 2014: Innovative Manufacturin...  

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

Innovative Manufacturing and Materials for Low-Cost Lithium-Ion Batteries Vehicle Technologies Office Merit Review 2014: Innovative Manufacturing and Materials for Low-Cost...

307

Vehicle Technologies Office Merit Review 2014: Development of...  

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

Development of Computer-Aided Design Tools for Automotive Batteries Vehicle Technologies Office Merit Review 2014: Development of Computer-Aided Design Tools for Automotive...

308

Vehicle Technologies Office Merit Review 2014: Overcoming Processing...  

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

Office Merit Review 2014: Overcoming Processing Cost Barriers of High-Performance Lithium-Ion Battery Electrodes Vehicle Technologies Office Merit Review 2014: Overcoming...

309

Vehicle Technologies Office Merit Review 2014: Utilization of...  

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

or EB Curing Technology to Significantly Reduce Costs and VOCs in the Manufacture of Lithium-Ion Battery Electrodes Vehicle Technologies Office Merit Review 2014: Utilization of...

310

On Minimizing the Energy Consumption of an Electrical Vehicle  

E-Print Network (OSTI)

The electrical vehicle energy management can be expressed as a Bang-Bang .... reflects the losses due to the internal resistance of the battery. The system ...

2011-04-19T23:59:59.000Z

311

NREL: Vehicles and Fuels Research - Working with Us  

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

Researchers characterize the thermal properties of vehicle energy storage devices in the Battery Thermal and Test Life Facility. Photo by Dennis Schroeder. NREL offers industry,...

312

Electric Drive Vehicle Level Control Development Under Various...  

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

Under Various Thermal Conditions Advanced Technology Vehicle Lab Benchmarking - Level 2 (in-depth) Energy Management Strategies for Fast Battery Temperature Rise and...

313

Idaho National Laboratory Testing of Advanced Technology Vehicles  

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

(not modeled) instrumentation and data collection of vehicle charging demand and energy costs at Tacoma Power, in Tacoma Washington * Tested PHEVs with lithium batteries...

314

The Future is Now for Advanced Vehicles | Department of Energy  

Office of Environmental Management (EM)

key facts? Rechargeable batteries are 40% cheaper than just three years ago. Hydrogen fuel cells are 30% cheaper than in 2008. Workplace charging stations for electric vehicles...

315

Plug-In Electric Vehicle Handbook for Consumers (Brochure), Clean...  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

. Instead, the battery supplies electricity to the electric motor . Photo from Margaret Smith, DOEPIX 18215 Plug-In Electric Vehicle Handbook for Consumers 5 Factors That Affect...

316

Design of a Sustainable Electric Vehicle Charging Station:.  

E-Print Network (OSTI)

??Electric vehicles only become useful in reducing greenhouse gas emissions, if the electricity used to charge their batteries comes from renewable energy sources. This thesis… (more)

Bakolas, B.V.E.

2012-01-01T23:59:59.000Z

317

Implications of Rapid Charging and Chemo-Mechanical Degradation in Lithium-Ion Battery Electrodes  

E-Print Network (OSTI)

Li-ion batteries, owing to their unique characteristics with high power and energy density, are broadly considered a leading candidate for vehicle electrification. A pivotal performance drawback of the Li-ion batteries manifests in the lengthy...

Hasan, Mohammed Fouad

2014-04-23T23:59:59.000Z

318

Efficient Simulation and Reformulation of Lithium-Ion Battery Models for Enabling Electric Transportation  

E-Print Network (OSTI)

Improving the efficiency and utilization of battery systems can increase the viability and cost-effectiveness of existing technologies for electric vehicles (EVs). Developing smarter battery management systems and advanced ...

Northrop, Paul W. C.

319

Ab initio prediction of thermodynamics in alkali metal-air batteries  

E-Print Network (OSTI)

Electric vehicles ("EVs") require high-energy-density batteries with reliable cyclability and rate capability. However, the current state-of-the-art Li-ion batteries only exhibit energy densities near ~150 Wh/kg, limiting ...

Kang, ShinYoung

2014-01-01T23:59:59.000Z

320

Heat dissipation structure research for rectangle LiFePO4 power battery  

Science Journals Connector (OSTI)

Under hard acceleration or on a hill climb of (hybrid) electronic vehicles, the battery temperature would increase rapidly. High temperature decreases the battery cycle life, increases the thermal runaway, and ev...

Zhang Yunyun; Zhang Guoqing; Wu Weixiong; Liang Weixiong

2014-07-01T23:59:59.000Z

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


321

Advanced Li-Ion Polymer Battery Cell Manufacturing Plant in USA...  

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

Li-Ion Polymer Battery Cell Manufacturing Plant in USA Advanced Li-Ion Polymer Battery Cell Manufacturing Plant in USA 2012 DOE Hydrogen and Fuel Cells Program and Vehicle...

322

Technological assessment and evaluation of high power batteries and their commercial values  

E-Print Network (OSTI)

Lithium Ion (Li-ion) battery technology has the potential to compete with the more matured Nickel Metal Hydride (NiMH) battery technology in the Hybrid Electric Vehicle (HEV) energy storage market as it has higher specific ...

Teo, Seh Kiat

2006-01-01T23:59:59.000Z

323

Vehicle Technologies Office: 2008 Energy Storage R&D Annual Progress Report  

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

The energy storage research and development effort within the Vehicle Technologies Office is responsible for researching and improving advanced batteries and ultracapacitors for a wide range of vehicle applications, including HEVs, PHEVs, EVs, and fuel cell vehicles (FCVs).

324

MIT Electric Vehicle Team Porsche designing a cooling system for the AC24 electric motor  

E-Print Network (OSTI)

In this thesis I worked on the design and analysis of a cooling system for the electric motor of the MIT Electric Vehicle Team's Porsche 914 Battery Electric Vehicle. The vehicle's Azure Dynamics AC24 motor tended to ...

Meenen, Jordan N

2010-01-01T23:59:59.000Z

325

Vehicle Technologies Office: 2009 Energy Storage R&D Annual Progress Report  

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

The energy storage research and development effort within the Vehicle Technologies Office is responsible for researching and improving advanced batteries and ultracapacitors for a wide range of vehicle applications, including HEVs, PHEVs, EVs, and fuel cell vehicles (FCVs).

326

Project Information Form Project Title White Paper on Strategies for Transitioning to Zero-Emission Vehicles--  

E-Print Network (OSTI)

fuel-cell-electric vehicles (HFCVs). These technologies can be used in passenger cars, trucks (ZEVs) include battery-electric vehicles (BEVs), plug-in hybrid-electric vehicles (PHEVs), and hydrogen

California at Davis, University of

327

Zero-Emission Vehicle Scenario Cost Analysis Using A Fuzzy Set-Based Framework  

E-Print Network (OSTI)

Fuel Cell Vehicle Analysis of Energy Use, Emissions, and Cost,"Cost Analysis of Conventional and Fuel Cell/Battery Powered Urban Passenger Vehicles,cost analysis of several types of AFVs, but did not include fuel cell vehicles

Lipman, Timothy Edward

1999-01-01T23:59:59.000Z

328

Zero-Emission Vehicle Scenario Cost Analysis Using A Fuzzy Set-Based Framework  

E-Print Network (OSTI)

Fuel Cell Vehicle Analysis of Energy Use, Emissions, and Cost,&Cost Analysis of Conventional and Fuel Cell/Battery Powered Urban Passenger Vehicles,cost analysis of several types of AFV s, but did not include fuel cell vehicles

Lipman, Timothy E.

1999-01-01T23:59:59.000Z

329

Rechargeable Batteries, Photochromics, Electrochemical Lithography: From  

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

Rechargeable Batteries, Photochromics, Electrochemical Lithography: From Rechargeable Batteries, Photochromics, Electrochemical Lithography: From Interfacial Studies to Practical Applications Speaker(s): Robert Kostecki Date: January 11, 2001 - 12:00pm Location: Bldg 90 Seminar Host/Point of Contact: Satkartar K. Kinney The constantly growing power requirements of portable electronic devices and the need for high-power batteries for electric vehicles have created a strong demand for new batteries or substantial improvements of existing ones. Fundamental problems associated with complex interfacial processes in batteries must be resolved to enhance battery performance and lifetime. An overview of the principles of electrode-electrolyte interfacial studies, experimental methods, recent results, and potential applications will be presented. Advanced instrumental techniques and

330

Page 1 of 9 Vehicle Buyers' Guide  

E-Print Network (OSTI)

in Part 3 of the survey. We will discuss vehicles that can be powered by gasoline only, electricity only, or both. We will also discuss how the vehicles that are powered by electricity can be recharged. In Part 3: · With a fully charged battery, the vehicle is powered by electricity for the first 16 to 64 kilometres

331

2013 Chevrolet Volt - VIN 3929 - Advanced Vehicle Testing - Beginning...  

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

Voltage 3 : 3.00 V Thermal Management: Active - Liquid cooled BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle Odometer: 4,007 mi Date of...

332

2013 Chevrolet Malibu ECO Hybrid ? VIN 6605, Advanced Vehicle...  

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

2 : 3.00 V Thermal Management: Active - Forced air Pack Weight: 65 lb BEGINNING-OF-TEST: BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle...

333

2011 Hyundai Sonata Hybrid - vin 3539 Advanced Vehicle Testing...  

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

Pack Capacity: 5.3 Ah Cooling: ActiveCabin Air Pack Weight: 96 lb BATTERY LABORATORY TEST RESULTS SUMMARY Vehicle Mileage and Testing Date Vehicle Odometer: 5,730 mi Date of...

334

Hybrid Electric Vehicle Basics | Department of Energy  

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

Hybrid Electric Vehicle Basics Hybrid Electric Vehicle Basics Hybrid Electric Vehicle Basics August 20, 2013 - 9:13am Addthis Photo of hands holding a battery pack (grey rectangular box) for a hybrid electric vehicle. Hybrid electric vehicles (HEVs) combine the benefits of high fuel economy and low emissions with the power, range, and convenience of conventional diesel and gasoline fueling. HEV technologies also have potential to be combined with alternative fuels and fuel cells to provide additional benefits. Future offerings might also include plug-in hybrid electric vehicles. Hybrid electric vehicles typically combine the internal combustion engine of a conventional vehicle with the battery and electric motor of an electric vehicle. The combination offers low emissions and convenience-HEVs never need to be plugged in.

335

Hybrid Electric Vehicle Basics | Department of Energy  

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

Hybrid Electric Vehicle Basics Hybrid Electric Vehicle Basics Hybrid Electric Vehicle Basics August 20, 2013 - 9:13am Addthis Photo of hands holding a battery pack (grey rectangular box) for a hybrid electric vehicle. Hybrid electric vehicles (HEVs) combine the benefits of high fuel economy and low emissions with the power, range, and convenience of conventional diesel and gasoline fueling. HEV technologies also have potential to be combined with alternative fuels and fuel cells to provide additional benefits. Future offerings might also include plug-in hybrid electric vehicles. Hybrid electric vehicles typically combine the internal combustion engine of a conventional vehicle with the battery and electric motor of an electric vehicle. The combination offers low emissions and convenience-HEVs never need to be plugged in.

336

Advanced Battery Manufacturing (VA)  

SciTech Connect

LiFeBATT has concentrated its recent testing and evaluation on the safety of its batteries. There appears to be a good margin of safety with respect to overheating of the cells and the cases being utilized for the batteries are specifically designed to dissipate any heat built up during charging. This aspect of LiFeBATT’s products will be even more fully investigated, and assuming ongoing positive results, it will become a major component of marketing efforts for the batteries. LiFeBATT has continued to receive prismatic 20 Amp hour cells from Taiwan. Further testing continues to indicate significant advantages over the previously available 15 Ah cells. Battery packs are being assembled with battery management systems in the Danville facility. Comprehensive tests are underway at Sandia National Laboratory to provide further documentation of the advantages of these 20 Ah cells. The company is pursuing its work with Hybrid Vehicles of Danville to critically evaluate the 20 Ah cells in a hybrid, armored vehicle being developed for military and security applications. Results have been even more encouraging than they were initially. LiFeBATT is expanding its work with several OEM customers to build a worldwide distribution network. These customers include a major automotive consulting group in the U.K., an Australian maker of luxury off-road campers, and a number of makers of E-bikes and scooters. LiFeBATT continues to explore the possibility of working with nations that are woefully short of infrastructure. Negotiations are underway with Siemens to jointly develop a system for using photovoltaic generation and battery storage to supply electricity to communities that are not currently served adequately. The IDA has continued to monitor the progress of LiFeBATT’s work to ensure that all funds are being expended wisely and that matching funds will be generated as promised. The company has also remained current on all obligations for repayment of an IDA loan and lease payments for space to the IDA. A commercial venture is being formed to utilize the LiFeBATT product for consumer use in enabling photovoltaic powered boat lifts. Field tests of the system have proven to be very effective and commercially promising. This venture is expected to result in significant sales within the next six months.

Stratton, Jeremy

2012-09-30T23:59:59.000Z

337

US Advanced Battery Consortium USABC | Open Energy Information  

Open Energy Info (EERE)

US Advanced Battery Consortium USABC US Advanced Battery Consortium USABC Jump to: navigation, search Name US Advanced Battery Consortium (USABC) Place Southfield, Michigan Zip 48075 Sector Vehicles Product Michigan-based, research consortium focused on R&D of advanced energy systems for electric vehicles. References US Advanced Battery Consortium (USABC)[1] LinkedIn Connections CrunchBase Profile No CrunchBase profile. Create one now! This article is a stub. You can help OpenEI by expanding it. US Advanced Battery Consortium (USABC) is a company located in Southfield, Michigan . References ↑ "US Advanced Battery Consortium (USABC)" Retrieved from "http://en.openei.org/w/index.php?title=US_Advanced_Battery_Consortium_USABC&oldid=352587" Categories: Clean Energy Organizations

338

Transformative Battery Technology at the National Labs | Department of  

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

Transformative Battery Technology at the National Labs Transformative Battery Technology at the National Labs Transformative Battery Technology at the National Labs January 17, 2012 - 10:45am Addthis Vince Battaglia leads a behind-the-scenes tour of Berkeley Lab's Batteries for Advanced Transportation Technologies Program where researchers aim to improve batteries upon which the range, efficiency, and power of tomorrow's electric cars will depend. Michael Hess Michael Hess Former Digital Communications Specialist, Office of Public Affairs What are the key facts? Berkeley's Batteries for Advanced Transportation Technologies Program is developing lithium-ion technology to power a vehicle for 300 miles. Lithium-sulfur and lithium-air are "unknown known" technologies for the future of electric vehicle batteries.

339

Transformative Battery Technology at the National Labs | Department of  

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

Transformative Battery Technology at the National Labs Transformative Battery Technology at the National Labs Transformative Battery Technology at the National Labs January 17, 2012 - 10:45am Addthis Vince Battaglia leads a behind-the-scenes tour of Berkeley Lab's Batteries for Advanced Transportation Technologies Program where researchers aim to improve batteries upon which the range, efficiency, and power of tomorrow's electric cars will depend. Michael Hess Michael Hess Former Digital Communications Specialist, Office of Public Affairs What are the key facts? Berkeley's Batteries for Advanced Transportation Technologies Program is developing lithium-ion technology to power a vehicle for 300 miles. Lithium-sulfur and lithium-air are "unknown known" technologies for the future of electric vehicle batteries.

340

Advanced Wireless Power Transfer Vehicle and Infrastructure Analysis (Presentation)  

SciTech Connect

This presentation discusses current research at NREL on advanced wireless power transfer vehicle and infrastructure analysis. The potential benefits of E-roadway include more electrified driving miles from battery electric vehicles, plug-in hybrid electric vehicles, or even properly equipped hybrid electric vehicles (i.e., more electrified miles could be obtained from a given battery size, or electrified driving miles could be maintained while using smaller and less expensive batteries, thereby increasing cost competitiveness and potential market penetration). The system optimization aspect is key given the potential impact of this technology on the vehicles, the power grid and the road infrastructure.

Gonder, J.; Brooker, A.; Burton, E.; Wang, J.; Konan, A.

2014-06-01T23:59:59.000Z

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


341

Vehicle Technology and Alternative Fuel Basics | Department of Energy  

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

Vehicle Technology and Alternative Fuel Basics Vehicle Technology and Alternative Fuel Basics Vehicle Technology and Alternative Fuel Basics Photo of an electric car plugged in and charging. Learn more about exciting technologies and ongoing research in alternative and advanced vehicles-or vehicles that run on fuels other than traditional petroleum. Alternative Vehicles There are a variety of alternative vehicle fuels available. Learn more about: Electric Vehicles Flexible Fuel Vehicles Fuel Cell Vehicles Hybrid Electric Vehicles Natural Gas Vehicles Propane Vehicles Also learn about: Vehicle Battery Basics Vehicle Emissions Basics Alternative Fuels There are a number of alternative fuel and advanced technology vehicles. Learn more about the following types of vehicles: Biodiesel Electricity Ethanol Hydrogen Natural Gas

342

Battery SEAB Presentation  

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

The Parker Ranch installation in Hawaii The Parker Ranch installation in Hawaii US Department of Energy Vehicle Battery R&D: Current Scope and Future Directions January 31, 2012 * David Howell (EERE/VTP) * Pat Davis (EERE/VTP) * Dane Boysen (ARPA-E) * Dave Danielson (ARPA-E) * Linda Horton (BES) * John Vetrano (BES) 2 | Energy Efficiency and Renewable Energy eere.energy.gov U.S. Oil-dependence is Driven by Transportation Source: DOE/EIA Annual Energy Review, April 2010 Transportation Residential and Commercial 94% Oil-dependent Industry 41% Oil-dependent 17% Oil-dependent 72% 22% 1% 5% U.S. Oil Consumption by End-use Sector 19.1 Million Barrels per Day (2010) Electric Power 1% Oil-dependent * On-road vehicles are responsible for ~80% of transportation oil usage 3 | Energy Efficiency and Renewable Energy eere.energy.gov

343

DOE to Provide up to $14 Million to Develop Advanced Batteries...  

Office of Environmental Management (EM)

to Provide Nearly 20 Million to Further Development of Advanced Batteries for Plug-in Hybrid Electric Vehicles DOE Announces 17 Million to Promote Greater Automobile Efficiency...

344

E-Print Network 3.0 - advanced lithium-ion batteries Sample Search...  

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

being undertaken at ISEM... .isem.uow.edu.au 12;Project Lithium ion batteries for Electric Vehicles (EVs) Aims To provide novel solutions... to enhance the performance ......

345

E-Print Network 3.0 - annual battery conference Sample Search...  

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

Pennsylvania State University Collection: Engineering 30 BATTERY-POWERED, ELECTRIC-DRIVE VEHICLES PROVIDING BUFFER STORAGE FOR PV CAPACITY VALUE Summary: -powered EDVs...

346

Temperature-Dependent Battery Models for High-Power Lithium-Ion Batteries  

SciTech Connect

In this study, two battery models for a high-power lithium ion (Li-Ion) cell were compared for their use in hybrid electric vehicle simulations in support of the U.S. Department of Energy's Hybrid Electric Vehicle Program. Saft America developed the high-power Li-Ion cells as part of the U.S. Advanced Battery Consortium/U.S. Partnership for a New Generation of Vehicles programs. Based on test data, the National Renewable Energy Laboratory (NREL) developed a resistive equivalent circuit battery model for comparison with a 2-capacitance battery model from Saft. The Advanced Vehicle Simulator (ADVISOR) was used to compare the predictions of the two models over two different power cycles. The two models were also compared to and validated with experimental data for a US06 driving cycle. The experimental voltages on the US06 power cycle fell between the NREL resistive model and Saft capacitance model predictions. Generally, the predictions of the two models were reasonably close to th e experimental results; the capacitance model showed slightly better performance. Both battery models of high-power Li-Ion cells could be used in ADVISOR with confidence as accurate battery behavior is maintained during vehicle simulations.

Johnson, V.H.; Pesaran, A.A. (National Renewable Energy Laboratory); Sack, T. (Saft America)

2001-01-10T23:59:59.000Z

347

Why Some Vehicles Are Not Listed / 1  

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

Understanding the Guide Listings / 1 Understanding the Guide Listings / 1 * Why Some Vehicles Are Not Listed / 1 * Vehicle Classes Used in This Guide / 2 * Tax Incentives and Disincentives / 2 * Why Consider Fuel Economy / 2 * Fueling Options / 3 * Fuel Economy and Annual Fuel Cost Ranges for Vehicle Classes / 3 * Model Year 2011 Fuel Economy Leaders / 4 * 2011 Model Year Vehicles / 6 * Battery Electric Vehicles / 18 * Plug-in Hybrid Electric Vehicles / 19 * Hybrid Electric Vehicles / 20 * Compressed Natural Gas Vehicles / 22 * Diesel Vehicles / 22 * Ethanol Flexible Fuel Vehicles / 24 * Fuel Cell Vehicles / 28 * Index / 29 * USING THE FUEL ECONOMY GUIDE The U.S. Environmental Protection Agency (EPA) and U.S. Department of Energy (DOE) produce the Fuel Economy Guide to help car buyers choose the most fuel-efficient vehicle that meets their

348

Batteries: Overview of Battery Cathodes  

E-Print Network (OSTI)

and Titanates as High-Energy Cathode Materials for Li-IonI, Amine K (2009) High Energy Cathode Material for Long-LifeA New Cathode Material for Batteries of High Energy Density.

Doeff, Marca M

2011-01-01T23:59:59.000Z

349

Like this post? Subscribe to our RSS feed and stay up to date. Navy Develops Battery that Runs on Mud  

E-Print Network (OSTI)

by Joshua S Hill Published on April 20th, 2010 in Energy & Fuel 1 Comment 5/4/2010 Navy Develops Battery and efficient reliable alternative battery avoiding the harmful impact that standard batteries and fuels have underwater vehicle that will settle on the seafloor and recharge its batteries using this fuel cell approach

Lovley, Derek

350

Coda Battery Systems | Open Energy Information  

Open Energy Info (EERE)

Coda Battery Systems Coda Battery Systems Jump to: navigation, search Name Coda Battery Systems Place Enfield, Connecticut Sector Vehicles Product Connecticut-based joint venture producing lithium-ion batteries for electric vehicles. Coordinates 36.181032°, -77.662805° Loading map... {"minzoom":false,"mappingservice":"googlemaps3","type":"ROADMAP","zoom":14,"types":["ROADMAP","SATELLITE","HYBRID","TERRAIN"],"geoservice":"google","maxzoom":false,"width":"600px","height":"350px","centre":false,"title":"","label":"","icon":"","visitedicon":"","lines":[],"polygons":[],"circles":[],"rectangles":[],"copycoords":false,"static":false,"wmsoverlay":"","layers":[],"controls":["pan","zoom","type","scale","streetview"],"zoomstyle":"DEFAULT","typestyle":"DEFAULT","autoinfowindows":false,"kml":[],"gkml":[],"fusiontables":[],"resizable":false,"tilt":0,"kmlrezoom":false,"poi":true,"imageoverlays":[],"markercluster":false,"searchmarkers":"","locations":[{"text":"","title":"","link":null,"lat":36.181032,"lon":-77.662805,"alt":0,"address":"","icon":"","group":"","inlineLabel":"","visitedicon":""}]}

351

Technology Improvement Pathways to Cost-Effective Vehicle Electrification  

SciTech Connect

Electrifying transportation can reduce or eliminate dependence on foreign fuels, emission of green house gases, and emission of pollutants. One challenge is finding a pathway for vehicles that gains wide market acceptance to achieve a meaningful benefit. This paper evaluates several approaches aimed at making plug-in electric vehicles (EV) and plug-in hybrid electric vehicles (PHEVs) cost-effective including opportunity charging, replacing the battery over the vehicle life, improving battery life, reducing battery cost, and providing electric power directly to the vehicle during a portion of its travel. Many combinations of PHEV electric range and battery power are included. For each case, the model accounts for battery cycle life and the national distribution of driving distances to size the battery optimally. Using the current estimates of battery life and cost, only the dynamically plugged-in pathway was cost-effective to the consumer. Significant improvements in battery life and battery cost also made PHEVs more cost-effective than today's hybrid electric vehicles (HEVs) and conventional internal combustion engine vehicles (CVs).

Brooker, A.; Thornton, M.; Rugh, J. P.

2010-04-01T23:59:59.000Z

352

Li-Ion and Other Advanced Battery Technologies  

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

scientist viewing computer screen scientist viewing computer screen Li-Ion and Other Advanced Battery Technologies The research aims to overcome the fundamental chemical and mechanical instabilities that have impeded the development of batteries for vehicles with acceptable range, acceleration, costs, lifetime, and safety. Its aim is to identify and better understand cell performance and lifetime limitations. These batteries have many other applications, in mobile electronic devices, for example. The work addresses synthesis of components into battery cells with determination of failure modes, materials synthesis and evaluation, advanced diagnostics, and improved electrochemical model development. This research involves: Battery development and analysis; Mathematical modeling; Sophisticated diagnostics;

353

NREL Uses Fuel Cells to Increase the Range of Battery Electric...  

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

Range Limitation of Medium-Duty Battery Electric Vehicles through the Use of Hydrogen Fuel Cells." SAE Int.; DOI: 10.42712013-01-2471. Extrapolation from parcel delivery vehicle...

354

Reducing Emissions Associated with Electric Vehicles  

Science Journals Connector (OSTI)

A century ago the electric car (now more frequently called electric vehicle or ... development of lithium ion battery technology, the electric car once again offers to be the ideal ... transport pollution problem...

Laurence Sparke OAM

2012-01-01T23:59:59.000Z

355

The Evolution of Sustainable Personal Vehicles  

E-Print Network (OSTI)

from a direct hydrogen PEM fuel cell, both of which serverear), an auxiliary PEM fuel cell (removed from the vehiclePEM to temperature change. Illustration 16: Battery pack (left) and fuel cell

Jungers, Bryan D

2009-01-01T23:59:59.000Z

356

Special Feature: Reducing Energy Costs with Better Batteries  

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

Reducing Energy Costs with Better Batteries Reducing Energy Costs with Better Batteries Special Feature: Reducing Energy Costs with Better Batteries September 9, 2013 Contact: Linda Vu, +1 510 495 2402, lvu@lbl.gov Electricvehicles8331019248.jpg Electric vehicles lined up in Cascade Locks. Credit: Oregon Department of Transportation A better battery-one that is cheap and safe, but packs a lot of power-could lead to an electric vehicle that performs better than today's gasoline-powered cars, and costs about the same or less to consumers. Such a vehicle would reduce the United States' reliance on foreign oil and lower energy costs for the average American, so one of the Department of Energy's (DOE's) goals is to fund research that will revolutionize the performance of next-generation batteries. In honor of DOE's supercomputing month, we are highlighting some of the

357

Development of a constitutive model predicting the point of short-circuit within lithium-ion battery cells  

E-Print Network (OSTI)

The use of Lithium Ion batteries continues to grow in electronic devices, the automotive industry in hybrid and electric vehicles, as well as marine applications. Such batteries are the current best for these applications ...

Campbell, John Earl, Jr

2012-01-01T23:59:59.000Z

358

Electric Drive Vehicle Demonstration and Vehicle Infrastructure...  

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

Electric Drive Vehicle Demonstration and Vehicle Infrastructure Evaluation Electric Drive Vehicle Demonstration and Vehicle Infrastructure Evaluation 2010 DOE Vehicle Technologies...

359

Towards Safer Lithium-Ion Batteries  

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

Towards Safer Lithium-Ion Batteries Towards Safer Lithium-Ion Batteries Speaker(s): Guoying Chen Date: October 25, 2007 - 12:00pm Location: 90-3122 Seminar Host/Point of Contact: Venkat Srinivasan Safety problems associated with rechargeable lithium batteries are now well recognized. Recent spectacular fires involving cell phones, laptops, and (here at LBNL) AA cells have made the news. These events are generally caused by overcharging and subsequent development of internal shorts. Before these batteries can be used in vehicle applications, improvement in cell safety is a must. We have been active in the area of lithium battery safety for many years. For example, a versatile, inexpensive overcharge protection approach developed in our laboratory, uses an electroactive polymer to act as a reversible, self-actuating, low resistance internal

360

Overview of the Batteries for Advanced Transportation Technologies...  

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

in support of the DOEEERE FreedomCAR and Vehicle Technologies Program to develop batteries for vehicular applications (EV, HEV, and Plug-in hybrid) * Presently, the focus is...

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


361

Thermo-mechanical Behavior of Lithium-ion Battery Electrodes  

E-Print Network (OSTI)

Developing electric vehicles is widely considered as a direct approach to resolve the energy and environmental challenges faced by the human race. As one of the most promising power solutions to electric cars, the lithium ion battery is expected...

An, Kai

2013-11-25T23:59:59.000Z

362

EV Everywhere Battery Workshop: Preliminary Target-Setting Framework  

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

Presentation given by Vehicle Technologies Office analyst Jacob Ward at the EV Everywhere Grand Challenge: Battery Workshop on July 26, 2012 held at the Doubletree O'Hare, Chicago, IL.

363

Rubber meets the road with new ORNL carbon, battery technologies...  

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

batteries that provide power to plug-in electric vehicles and store energy produced by wind and solar, say researchers at the Department of Energy's Oak Ridge National Laboratory....

364

Numerical Simulation of the Thermal Management for Traction Batteries  

Science Journals Connector (OSTI)

The electrification of vehicle powertrains is a rapidly developing technology. Especially for the development of the used high-voltage batteries, an elaborated thermal management is needed to secure their perform...

Xiao Hu

2012-02-01T23:59:59.000Z

365

Nonflammable perfluoropolyether-based electrolytes for lithium batteries  

Science Journals Connector (OSTI)

...to power zero-emission electric vehicles, but they currently are gaining traction as backup power in aircraft and smart grid applications (3, 4). The electrolyte used in these batteries, however, hinders their use in large-scale applications...

Dominica H. C. Wong; Jacob L. Thelen; Yanbao Fu; Didier Devaux; Ashish A. Pandya; Vincent S. Battaglia; Nitash P. Balsara; Joseph M. DeSimone

2014-01-01T23:59:59.000Z

366

High Voltage Electrolytes for Li-ion Batteries | Department of...  

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

in Support of 5 V Li-ion Chemistries Vehicle Technologies Office Merit Review 2014: Fluorinated Electrolyte for 5-V Li-Ion Chemistry High Voltage Electrolyte for Lithium Batteries...

367

Definition: Electric Vehicle Charging Station | Open Energy Information  

Open Energy Info (EERE)

Vehicle Charging Station Vehicle Charging Station Jump to: navigation, search Dictionary.png Electric Vehicle Charging Station An electric vehicle charging station that uses communications technology to enable it to intelligently integrate two-way power flow enabling electric vehicle batteries to become a useful utility asset.[1] View on Wikipedia Wikipedia Definition An electric vehicle charging station, also called EV charging station, electric recharging point, charging point and EVSE (Electric Vehicle Supply Equipment), is an element in an infrastructure that supplies electric energy for the recharging of plug-in electric vehicles, including all-electric cars, neighborhood electric vehicles and plug-in hybrids. As plug-in hybrid electric vehicles and battery electric vehicle ownership is

368

Vehicles News | Department of Energy  

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

July 14, 2010 July 14, 2010 Department of Energy Releases New Report on Economic Impact of Recovery Act Advanced Vehicle Investments Report Finds Recovery Act Advanced Vehicle Projects Are Creating Jobs, Spurring Private Capital Investment and Cutting Electric Vehicle Cost May 26, 2010 Deputy Secretary Poneman Attends Ground Breaking at Tennessee Advanced Vehicle Battery Plant Smyrna Electric Vehicle Project Expected to provide up to 1,500 Jobs in Tennessee March 31, 2010 GSA Doubles the Federal Hybrid Fleet, DOE Takes the Lead in Updating to Hybrids Agencies Move to Increase Energy Security and Fuel Efficiency January 11, 2010 Secretary Chu Announces $187 Million to Improve Vehicle Efficiency for Heavy-Duty Trucks and Passenger Vehicles October 15, 2009 2010 Annual Fuel Economy Guide Now Available

369

Optimal routes for electric vehicles facing uncertainty, congestion, and energy constraints  

E-Print Network (OSTI)

There are many benefits of owning a battery electric vehicle, including zero tailpipe emissions, potential independence from oil, lower fuel costs, and the option to recharge the battery at home. However, a significant ...

Fontana, Matthew William

2013-01-01T23:59:59.000Z

370

Polymeric batteries. (Latest citations from the INSPEC database). Published Search  

SciTech Connect

The bibliography contains citations concerning the development, models, and evaluation of polymer electrolyte batteries and fuel cells. The design and fabrication of polymeric materials for lithium and solid-state batteries are discussed. Applications in marine electric propulsion, electric vehicles, and microelectronics are examined. (Contains 250 citations and includes a subject term index and title list.)

NONE

1995-03-01T23:59:59.000Z

371

Polymeric batteries. (Latest citations from the INSPEC database). Published Search  

SciTech Connect

The bibliography contains citations concerning the development, models, and evaluation of polymer electrolyte batteries and fuel cells. The design and fabrication of polymeric materials for lithium and solid-state batteries are discussed. Applications in marine electric propulsion, electric vehicles, and microelectronics are examined. (Contains 50-250 citations and includes a subject term index and title list.) (Copyright NERAC, Inc. 1995)

NONE

1996-09-01T23:59:59.000Z

372

NREL: Learning - Advanced Vehicle Systems and Components  

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

Advanced Vehicle Systems and Components Advanced Vehicle Systems and Components Photo of a man checking out an advanced battery using testing equipment that includes a long metal tube on a table top. NREL's researchers test new batteries developed for hybrid electric vehicles. Credit: Warren Gretz Researchers and engineers at the NREL work closely with those in the automotive industry to develop new technologies, such as advanced batteries, for storing energy in cars, trucks, and buses. They also help to develop and test new technologies for using that energy more efficiently. And they work on finding new, energy-efficient ways to reduce the amount of fuel needed to heat and cool the interiors, or cabins, of vehicles. To help develop these new technologies, NREL's researchers are improving the efficiency of vehicle systems and components like these:

373

Carbonophosphates: A New Family of Cathode Materials for Li-Ion Batteries Identified Computationally  

E-Print Network (OSTI)

Carbonophosphates: A New Family of Cathode Materials for Li-Ion Batteries Identified ABSTRACT: The tremendous growth of Li-ion batteries into a wide variety of applications is setting new applications from portable electronics to electric vehicles. A critical element of a Li-ion battery is the Li

Ceder, Gerbrand

374

Journal of Power Sources xxx (2005) xxxxxx Vehicle-to-grid power fundamentals: Calculating capacity  

E-Print Network (OSTI)

; Vehicle-to-grid power; Ancillary services; V2G 1. Introduction The electric power grid and light vehicle-drive vehicles (EDVs), that is, vehicles with an electric-drive motor powered by batteries, a fuel cellJournal of Power Sources xxx (2005) xxx­xxx Vehicle-to-grid power fundamentals: Calculating

Firestone, Jeremy

375

DOE to Provide up to $14 Million to Develop Advanced Batteries for Plug-in  

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

to Provide up to $14 Million to Develop Advanced Batteries for to Provide up to $14 Million to Develop Advanced Batteries for Plug-in Hybrid Electric Vehicles DOE to Provide up to $14 Million to Develop Advanced Batteries for Plug-in Hybrid Electric Vehicles April 5, 2007 - 12:17pm Addthis WASHINGTON, DC - The U.S. Department of Energy (DOE) today announced that it will provide up to $14 million in funding for a $28 million cost-shared solicitation by the United States Advanced Battery Consortium (USABC), for plug-in hybrid electric vehicle (PHEV) battery development. This research aims to find solutions to improving battery performance so vehicles can deliver up to 40 miles of electric range without recharging. This would include most roundtrip daily commutes. "President Bush is committed to developing alternative fuels and

376

Metal-Air Batteries  

SciTech Connect

Metal-air batteries have much higher specific energies than most currently available primary and rechargeable batteries. Recent advances in electrode materials and electrolytes, as well as new designs on metal-air batteries, have attracted intensive effort in recent years, especially in the development of lithium-air batteries. The general principle in metal-air batteries will be reviewed in this chapter. The materials, preparation methods, and performances of metal-air batteries will be discussed. Two main metal-air batteries, Zn-air and Li-air batteries will be discussed in detail. Other type of metal-air batteries will also be described.

Zhang, Jiguang; Bruce, Peter G.; Zhang, Gregory

2011-08-01T23:59:59.000Z

377

Two Studies Reveal Details of Lithium-Battery Function  

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

Two Studies Reveal Details of Lithium-Battery Function Print Two Studies Reveal Details of Lithium-Battery Function Print Our way of life is deeply intertwined with battery technologies that have enabled a mobile revolution powering cell phones, laptops, medical devices, and cars. As conventional lithium-ion batteries approach their theoretical energy-storage limits, new technologies are emerging to address the long-term energy-storage improvements needed for mobile systems, electric vehicles in particular. Battery performance depends on the dynamics of evolving electronic and chemical states that, despite advances in material synthesis and structural probes, remain elusive and largely unexplored. At Beamlines 8.0.1 and 9.3.2, researchers studied lithium-ion and lithium-air batteries, respectively, using soft x-ray spectroscopy techniques. The detailed information they obtained about the evolution of electronic and chemical states will be indispensable for understanding and optimizing better battery materials.

378

TransForum - Special Issue: Batteries - August 2010  

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

Special Issue: Batteries-August 2010 Special Issue: Batteries-August 2010 RESEARCH REVIEWS 2 China's Minister of Science and Technology Visits Argonne 3 Testing the Tesla 4 Six Myths about Plug-in Hybrid Electric Vehicles 6 Charging Ahead: Taking PHEVs Farther on a Single Battery Charge 7 Argonne to Explore Lithium-air Battery 8 Argonne's Lithium-ion Battery Research Produces New Materials and Technology Transfer Successes 11 New Battery Facilities Will Help Accelerate Commercialization of Technologies 12 Argonne Charges Ahead with Smart Grid Research 14 Center for Electrical Energy Storage Promises Advances in Transportation Technologies 15 PHEVs Need Further Research for Acceptable Payback 16 PUTTING ARGONNE'S RESOURCES TO WORK FOR YOU Lithium-ion Battery Research page 8 Minister of Science and

379

SECONDARY BATTERIES – LITHIUM RECHARGEABLE SYSTEMS – LITHIUM-ION | Overview  

Science Journals Connector (OSTI)

The need to increase the specific energy and energy density of secondary batteries has become more urgent as a result of the recent rapid development of new applications, such as electric vehicles (EVs), load leveling, and various types of portable equipments, including cellular phones, personal computers, camcorders, and digital cameras. Among various types of secondary batteries, rechargeable lithium-ion batteries have been used in a wide variety of portable equipments due to their high energy density. Many researchers have contributed to develop lithium-ion batteries, and their contributions are reviewed from historical aspects onward, including the researches in primary battery with metal lithium anode, and secondary battery with metal lithium negative electrode. Researches of new materials are still very active to develop new lithium-ion batteries with higher performances. The researches of positive and negative electrode active materials and electrolytes are also reviewed historically.

J. Yamaki

2009-01-01T23:59:59.000Z

380

Two Studies Reveal Details of Lithium-Battery Function  

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

Two Studies Reveal Details of Lithium-Battery Function Print Two Studies Reveal Details of Lithium-Battery Function Print Our way of life is deeply intertwined with battery technologies that have enabled a mobile revolution powering cell phones, laptops, medical devices, and cars. As conventional lithium-ion batteries approach their theoretical energy-storage limits, new technologies are emerging to address the long-term energy-storage improvements needed for mobile systems, electric vehicles in particular. Battery performance depends on the dynamics of evolving electronic and chemical states that, despite advances in material synthesis and structural probes, remain elusive and largely unexplored. At Beamlines 8.0.1 and 9.3.2, researchers studied lithium-ion and lithium-air batteries, respectively, using soft x-ray spectroscopy techniques. The detailed information they obtained about the evolution of electronic and chemical states will be indispensable for understanding and optimizing better battery materials.

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


381

Battery business boost  

Science Journals Connector (OSTI)

... year, A123 formed deals with the US car manufacturer Chrysler to make batteries for its electric cars. Other applications for A123 products include batteries for portable power tools and huge batteries ... batteries are not yet developed enough to be considered for use in its Prius hybrid electric car, preferring instead to keep using nickel metal hydride batteries. ...

Katharine Sanderson

2009-09-24T23:59:59.000Z

382

Vehicle Technologies Office Merit Review 2014: Roll-to-Roll Electrode...  

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

Roll-to-Roll Electrode Processing NDE for Advanced Lithium Secondary Batteries Vehicle Technologies Office Merit Review 2014: Roll-to-Roll Electrode Processing NDE for Advanced...

383

Minimum Cost Path Problem for Plug-in Hybrid Electric Vehicles  

E-Print Network (OSTI)

Modeling grid-connected hybrid electric vehicles using advisor, in: Applications and Advances, 2001. The Sixteenth Annual Battery Con- ference on, IEEE. pp.

2014-07-22T23:59:59.000Z

384

Emission control cost-effectiveness of alternative-fuel vehicles  

SciTech Connect

Although various legislation and regulations have been adopted to promote the use of alternative-fuel vehicles for curbing urban air pollution problems, there is a lack of systematic comparisons of emission control cost-effectiveness among various alternative-fuel vehicle types. In this paper, life-cycle emission reductions and life-cycle costs were estimated for passenger cars fueled with methanol, ethanol, liquefied petroleum gas, compressed natural gas, and electricity. Vehicle emission estimates included both exhaust and evaporative emissions for air pollutants of hydrocarbon, carbon monoxide, nitrogen oxides, and air-toxic pollutants of benzene, formaldehyde, 1,3-butadiene, and acetaldehyde. Vehicle life-cycle cost estimates accounted for vehicle purchase prices, vehicle life, fuel costs, and vehicle maintenance costs. Emission control cost-effectiveness presented in dollars per ton of emission reduction was calculated for each alternative-fuel vehicle types from the estimated vehicle life-cycle emission reductions and costs. Among various alternative-fuel vehicle types, compressed natural gas vehicles are the most cost-effective vehicle type in controlling vehicle emissions. Dedicated methanol vehicles are the next most cost-effective vehicle type. The cost-effectiveness of electric vehicles depends on improvements in electric vehicle battery technology. With low-cost, high-performance batteries, electric vehicles are more cost-effective than methanol, ethanol, and liquified petroleum gas vehicles.

Wang, Q. [Argonne National Lab., IL (United States); Sperling, D.; Olmstead, J. [California Univ., Davis, CA (United States). Inst. of Transportation Studies

1993-06-14T23:59:59.000Z

385

Washington: Battery Manufacturer Brings Material Production Home  

Office of Energy Efficiency and Renewable Energy (EERE)

EERE-supported company, EnerG2, built a new plant to produce nano-engineered carbon materials for batteries and other energy storage devices that can be used in hybrid, electric, plug-in hybrid, and all-electric vehicles.

386

Iron-air battery development program  

SciTech Connect

The progress and status of the research and development program on the iron-air advanced technology battery system at the Westinghouse Electric Corporation during the period June 1978-December 1979 are described. This advanced battery system is being developed for electric vehicle propulsion applications. Testing and evaluation of 100 cm/sup 2/ size cells was undertaken while individual iron and air electrode programs continued. Progress is reported in a number of these study areas. Results of the improvements made in the utilization of the iron electrode active material coupled with manufacturing and processing studies related to improved air electrodes continue to indicate that a fully developed iron-air battery system will be capable of fulfilling the performance requirements for commuter electric vehicles.

Buzzelli, E.S.; Liu, C.T.; Bryant, W.A.

1980-05-01T23:59:59.000Z

387

The development of a computerized battery simulator optimized for use in the ELPH 2.0 simulation environment  

E-Print Network (OSTI)

is an interactive computer simulation environment that has been developed for the prediction and evaluation of performance of electric vehicles (EVs) and hybrid electric vehicles (HEVs). A battery simulator was developed that conforms to the ELPH computing...

Moore, Stephen W

1996-01-01T23:59:59.000Z

388

Vehicle Technologies Office: Long-Term Exploratory Research  

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

Long-Term Exploratory Long-Term Exploratory Research to someone by E-mail Share Vehicle Technologies Office: Long-Term Exploratory Research on Facebook Tweet about Vehicle Technologies Office: Long-Term Exploratory Research on Twitter Bookmark Vehicle Technologies Office: Long-Term Exploratory Research on Google Bookmark Vehicle Technologies Office: Long-Term Exploratory Research on Delicious Rank Vehicle Technologies Office: Long-Term Exploratory Research on Digg Find More places to share Vehicle Technologies Office: Long-Term Exploratory Research on AddThis.com... Just the Basics Hybrid & Vehicle Systems Energy Storage Batteries Battery Systems Applied Battery Research Long-Term Exploratory Research Ultracapacitors Advanced Power Electronics & Electrical Machines Advanced Combustion Engines

389

hybrid electric vehicle and lithium polymer nev testing  

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

P1.2 - Hybrid Electric Vehicle and Lithium Polymer NEV Testing P1.2 - Hybrid Electric Vehicle and Lithium Polymer NEV Testing James Edward Francfort Advanced Vehicle Testing Activity Idaho National Laboratory P.O. Box 1625, Idaho Falls, ID. 83415-3830 james.francfort@inl.gov Abstract: The U.S. Department of Energy's Advanced Vehicle Testing Activity tests hybrid electric, pure electric, and other advanced technology vehicles. As part of this testing, 28 hybrid electric vehicles (HEV) are being tested in fleet, dynamometer, and closed track environments. This paper discusses some of the HEV test results, with an emphasis on the battery performance of the HEVs. It also discusses the testing results for a small electric vehicle with a lithium polymer traction battery. Keywords: hybrid; neighborhood; electric; battery; fuel;

390

Plug-In Hybrid Electric Vehicle  

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

* Batteries * Batteries * Downloadable Dynanometer Database (D3) * Modeling * Prototypes * Testing * Assessment PSAT Smart Grid Student Competitions Technology Analysis Transportation Research and Analysis Computing Center Working With Argonne Contact TTRDC Argonne Leads DOE's Effort to Evaluate Plug-in Hybrid Technology aprf testing Argonne's Advanced Powertrain Research Facility (APRF) enables researchers to conduct vehicle benchmarking and testing activities that provide data critical to the development and commercialization of next-generation vehicles such as PHEVs. Argonne's Research Argonne National Laboratory is the U.S. Department of Energy's lead national laboratory for the simulation, validation and laboratory evaluation of plug-in hybrid electric vehicles and the advanced

391

Battery Safety Testing  

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

mechanical modeling battery crash worthiness for USCAR Abuse tolerance evaluation of cells, batteries, and systems Milestones Demonstrate improved abuse tolerant cells and...

392

Fuel Economy of Hybrids, Diesels, and Alternative Fuel Vehicles  

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

You are here: Find a Car - Home > Hybrids, Diesels, and Alternative Fuel You are here: Find a Car - Home > Hybrids, Diesels, and Alternative Fuel Vehicles Hybrids, Diesels, and Alternative Fuel Vehicles Search by Vehicle Type 2014 2013 2012 2011 2010 2009 2008 2007 2006 2005 2004 2003 2002 2001 2000 Select Vehicle Type Diesel Electric Ethanol-Gasoline Hybrid Plug-in Hybrid Natural Gas Bifuel Natural Gas Bifuel Propane Go More Search Options Browse New Cars Hybrid Vehicles Plug-in Hybrid Vehicles Battery Electric Vehicles Diesel Vehicles Flex-Fuel Vehicles CNG Vehicles Related Information How Hybrid Vehicles Work How Fuel Cell Vehicles Work MotorWeek Videos Compare Hybrids Compare Diesels Extreme MPG Tax Incentive Information Center Alternative Fuel Station Locator Alternative Fuel and Advanced Vehicle Data Center | Share I want to... Compare Side-by-Side

393

Battery Jobs Coming to Michigan | Department of Energy  

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

Jobs Coming to Michigan Jobs Coming to Michigan Battery Jobs Coming to Michigan March 22, 2010 - 3:01pm Addthis Advanced batteries will enable electricity generated through renewable energy sources to be used in plug-in vehicles. | File photo Advanced batteries will enable electricity generated through renewable energy sources to be used in plug-in vehicles. | File photo Joshua DeLung A123 Systems, of Watertown, Mass., was awarded a $249 million Recovery Act grant from the U.S. Department of Energy in August that will help implement the company's strategy for the construction of lithium-ion battery manufacturing facilities in the U.S., with the first location being constructed in Livonia, Mich. This is the first step in the company's overarching goal of creating a complete battery manufacturing industry in

394

Recycling of Li-Ion Batteries  

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

1 1 Linda Gaines Center for Transportation Research Argonne National Laboratory Recycling of Li-Ion Batteries Illinois Sustainable Technology Center University of Illinois We don't want to trade one crisis for another!  Battery material shortages are unlikely - We demonstrated that lithium demand can be met - Recycling mitigates potential scarcity  Life-cycle analysis checks for unforeseen impacts  We need to find something to do with the used materials - Safe - Economical 2 We answer these questions to address material supply issues  How many electric-drive vehicles will be sold in the US and world-wide?  What kind of batteries might they use? - How much lithium would each battery use?  How much lithium would be needed each year?

395

Smith Electric Vehicles: Advanced Vehicle Electrification + Transporta...  

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

Smith Electric Vehicles: Advanced Vehicle Electrification + Transportation Sector Electrification Smith Electric Vehicles: Advanced Vehicle Electrification + Transportation Sector...

396

An Energy Transmission and Distribution Network Using Electric Vehicles  

E-Print Network (OSTI)

An Energy Transmission and Distribution Network Using Electric Vehicles Ping Yi, Ting Zhu, Bo Jiang-to-grid provides a viable approach that feeds the battery energy stored in electric vehicles (EVs) back biggest greenhouse gas producer in the world [1]. Many countries have been developing electric vehicles

Wang, Bing

397

Design of a fuzzy controller for energy management of a parallel hybrid electric vehicle  

E-Print Network (OSTI)

This thesis addresses the design of a control scheme based on Fuzzy Logic to minimize automobile fuel consumption and exhaust emissions while maximizing battery state of charge (SOC) for hybrid vehicles. The advantages the hybrid vehicle has over...

Estrada Gutierrez, Pedro Cuauhtemoc

1997-01-01T23:59:59.000Z

398

Vehicle Technologies Office: 2010 Energy Storage R&D Annual Progress Report  

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

The energy storage research and development effort within the Vehicle Technologies Office (VTO) is responsible for researching and improving advanced batteries and ultracapacitors for a wide range of vehicleapplications, including HEVs, PHEVs, EVs, and fuel cell vehicles (FCVs).

399

Vehicle Specifications Battery Type: Li-Ion  

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

Under hood above powertrain Under hood above powertrain Nominal System Voltage: 333 V Rated Capacity (C/3): 40 Ah Cooling Method: Glycol / Water mix Powertrain Motor Type: DC Brushless Number of Motors: One Motor Cooling Type: Glycol / Water mix Drive Wheels: Rear Wheel Drive Transmission: None (gear ratio only in rear axle) Charger Location: Underhood Charger Port: Driver's side, front quarter panel Type: Conductive (J1772 connector) Input Voltage(s): 120 or 240 VAC Chassis Aluminum Body on Steel Frame Rear Suspension: Solid Axle with Leaf Springs Front Suspension: Dual A-arm with Coil Springs Weights Design Curb Weight: 3250 lbs Delivered Curb Weight: 3310 lbs 7 Distribution F/R: 55.2/44.8% GVWR: 4450 lbs Max Payload: 940 lbs + 200 lbs driver 1 Performance Goal Payload: 1000 lbs + 200 lbs driver

400

Fuel Cell and Battery Electric Vehicles Compared  

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

2.2 Storage Volume Some analysts are concerned about the volume required for compressed gas hydrogen tanks. They do indeed take up more space than a gasoline tank, but compressed...

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


401

Li Storage and Impedance Spectroscopy Studies on Co3O4, CoO, and CoN for Li-Ion Batteries  

Science Journals Connector (OSTI)

Urea act as an oxidising fuel. ... vehicles (EV) or for large-scale batteries for electricity power storage, has made lithium ion rechargeable battery development into a growth area which has gained high momentum for its research activities. ...

M. V. Reddy; Gundlapalli Prithvi; Kian Ping Loh; B. V. R. Chowdari

2013-12-10T23:59:59.000Z

402

Membranes and separators for flowing electrolyte batteries-a review  

SciTech Connect

Flowing electrolyte batteries are rechargeable electrochemical storage devices in which externally stored electrolytes are circulated through the cell stack during charge or discharge. The potential advantages that flow batteries offer compared to other secondary batteries include: 1) ease of thermal and electrolyte management, 2) simple electrochemistry, 3) deep cycling capability, and 4) minimal loss of capacity with cycling. However, flow batteries are more complex than other secondary batteries and consequently may cost more and may be less reliable. Flow batteries are being developed for utility load leveling, electric vehicles, solar photovoltaic and wind turbine application. The status of flow batteries has recently been reviewed by Clark et al. The flowing electrolyte batteries place rigorous demands on the performance of separators and membranes. The operating characteristics of the iron/chromium redox battery were changed in order to accommodate the limitations in membrane performance. Low cost alternatives to the presently used membrane must be found before the zinc/ferricyanide battery can be economically feasible. The zinc/bromine battery's efficiency could be improved if a suitably selective membrane were available. It is anticipated that better and less costly membranes to meet these needs will be developed as more is learned about their preparation and performance.

Arnold, C.; Assink, R.A.

1983-01-01T23:59:59.000Z

403

Hardware Architecture for Measurements for 50-V Battery Modules  

SciTech Connect

Energy storage devices, especially batteries, have become critical for several industries including automotive, electric utilities, military and consumer electronics. With the increasing demand for electric and hybrid electric vehicles and the explosion in popularity of mobile and portable electronic devices such as laptops, cell phones, e-readers, tablet computers and the like, reliance on portable energy storage devices such as batteries has likewise increased. Because many of the systems these batteries integrated into are critical, there is an increased need for an accurate in-situ method of monitoring battery state-of-health. Over the past decade the Idaho National Laboratory (INL), Montana Tech of the University of Montana (Tech), and Qualtech Systems, Inc. (QSI) have been developing the Smart Battery Status Monitor (SBSM), an integrated battery management system designed to monitor battery health, performance and degradation and use this knowledge for effective battery management and increased battery life. Key to the success of the SBSM is an in-situ impedance measurement system called the Impedance Measurement Box (IMB). One of the challenges encountered has been development of a compact IMB system that will perform rapid accurate measurements of a battery impedance spectrum working with higher voltage batteries of up to 300 volts. This paper discusses the successful realization of a system that will work up to 50 volts.

Patrick Bald; Evan Juras; Jon P. Christophersen; William Morrison

2012-06-01T23:59:59.000Z

404

Battery Lifetime Analysis and Simulation Tool (BLAST) Documentation  

SciTech Connect

The deployment and use of lithium-ion batteries in automotive and stationary energy storage applications must be optimized to justify their high up-front costs. Given that batteries degrade with use and storage, such optimizations must evaluate many years of operation. As the degradation mechanisms are sensitive to temperature, state-of-charge histories, current levels, and cycle depth and frequency, it is important to model both the battery and the application to a high level of detail to ensure battery response is accurately predicted. To address these issues, the National Renewable Energy Laboratory has developed the Battery Lifetime Analysis and Simulation Tool (BLAST) suite of tools. This suite of tools pairs NREL's high-fidelity battery degradation model with a battery electrical and thermal performance model, application-specific electrical and thermal performance models of the larger system (e.g., an electric vehicle), application-specific system use data (e.g., vehicle travel patterns and driving data), and historic climate data from cities across the United States. This provides highly realistic, long-term predictions of battery response and thereby enables quantitative comparisons of varied battery use strategies.

Neubauer, J.

2014-12-01T23:59:59.000Z

405

Google+ virtual field trip: "Vehicle Electrification" (11/18/13) | Argonne  

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

Google+ virtual field trip: "Vehicle Electrification" (11/18/13) Google+ virtual field trip: "Vehicle Electrification" (11/18/13) Share Topic Energy Energy efficiency Vehicles Electric drive technology Browse By - Any - Energy -Energy efficiency --Vehicles ---Alternative fuels ---Automotive engineering ---Diesel ---Electric drive technology ---Hybrid & electric vehicles ---Powertrain research --Building design ---Construction --Manufacturing -Energy sources --Renewable energy ---Bioenergy ---Solar energy --Fossil fuels ---Natural Gas --Nuclear energy ---Nuclear energy modeling & simulation ---Nuclear fuel cycle ---Reactors -Energy usage --Energy storage ---Batteries ----Lithium-ion batteries ----Lithium-air batteries --Electricity transmission --Smart Grid Environment -Biology --Computational biology --Environmental biology

406

P1.2 -- Hybrid Electric Vehicle and Lithium Polymer NEV Testing  

SciTech Connect

The U.S. Department of Energy’s Advanced Vehicle Testing Activity tests hybrid electric, pure electric, and other advanced technology vehicles. As part of this testing, 28 hybrid electric vehicles (HEV) are being tested in fleet, dynamometer, and closed track environments. This paper discusses some of the HEV test results, with an emphasis on the battery performance of the HEVs. It also discusses the testing results for a small electric vehicle with a lithium polymer traction battery.

J. Francfort

2006-06-01T23:59:59.000Z

407

FY14 Milestone: Simulated Impacts of Life-Like Fast Charging on BEV Batteries (Management Publication)  

SciTech Connect

Fast charging is attractive to battery electric vehicle (BEV) drivers for its ability to enable long-distance travel and quickly recharge depleted batteries on short notice. However, such aggressive charging and the sustained vehicle operation that results could lead to excessive battery temperatures and degradation. Properly assessing the consequences of fast charging requires accounting for disparate cycling, heating, and aging of individual cells in large BEV packs when subjected to realistic travel patterns, usage of fast chargers, and climates over long durations (i.e., years). The U.S. Department of Energy's Vehicle Technologies Office has supported NREL's development of BLAST-V 'the Battery Lifetime Analysis and Simulation Tool for Vehicles' to create a tool capable of accounting for all of these factors. The authors present on the findings of applying this tool to realistic fast charge scenarios. The effects of different travel patterns, climates, battery sizes, battery thermal management systems, and other factors on battery performance and degradation are presented. The primary challenge for BEV batteries operated in the presence of fast charging is controlling maximum battery temperature, which can be achieved with active battery cooling systems.

Neubauer, J.; Wood, E.; Burton, E.; Smith, K.; Pesaran, A.

2014-09-01T23:59:59.000Z

408

Safety Hazards of Batteries  

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

Safety Hazards of Batteries Safety Hazards of Batteries Battery technology is at the heart of much of our technological revolution. One of the most prevalent rechargeable batteries in use today is the Lithium-ion battery. Cell phones, laptop computers, GPS systems, iPods, and even cars are now using lithium- ion rechargeable battery technology. In fact, you probably have a lithium-ion battery in your pocket or purse right now! Although lithium-ion batteries are very common there are some inherent dangers when using ANY battery. Lithium cells are like any other technology - if they are abused and not used for their intended purpose catastrophic results may occur, such as: first-, second-, and third-degree burns, respiratory problems, fires, explosions, and even death. Please handle the lithium-ion batteries with care and respect.

409

Abstract--This paper examines the impact of battery sizing on the performance and efficiency of power management  

E-Print Network (OSTI)

Abstract--This paper examines the impact of battery sizing on the performance and efficiency paper examines plug-in hybrid electric vehicles (PHEVs), which typically utilize onboard battery storage and efficiency characteristics of these algorithms are compared for different battery sizes over stochastic

Krstic, Miroslav

410

2000-01-1556 Life-Cycle Cost Sensitivity to Battery-Pack Voltage of an HEV  

E-Print Network (OSTI)

defined the peak power ratings for each HEV drive system's electric components: batteries, battery cables. This affects the material and manufacturing costs of the battery, electric motor, and controller. *Prepared performance, ratings, and cost study was conducted on series and parallel hybrid electric vehicle (HEV

Tolbert, Leon M.

411

Applied Surface Science 266 (2013) 516 Interphase chemistry of Si electrodes used as anodes in Li-ion batteries  

E-Print Network (OSTI)

in Li-ion batteries Catarina Pereira-Nabaisa,b , Jolanta S´wiatowskaa, , Alexandre Chagnesb, , Franc made to increase the energy density of lithium-ion batteries (LiB), namely for electric vehicle applications. One way to improve the energy density of a battery is to use high specific capacity materials, e

Boyer, Edmond

412

IEEE TRANSACTIONS ON VEHICULAR TECHNOLOGY, VOL. 61, NO. 7, SEPTEMBER 2012 2925 Battery Cell Identification and SOC Estimation Using  

E-Print Network (OSTI)

battery technology employs cell- or module-level voltage sensors, with high costs for sensors observability for battery cell subsystems. Control strategies, estimation algorithms, and their key properties for electric vehicles (including hybrid electric, plug-in hybrid, fuel cell, and solar vehicles), renewable

Mi, Chunting "Chris"

413

Electric Automobile Ni-MH Battery Investigation in Diverse Situations  

Science Journals Connector (OSTI)

Abstract The electronic differential system ensures the robust control of the vehicle comportment on the road. This paper focuses Ni-MH Battery controlled by Buck Boost DC-DC converter power supply for EV. Sliding mode control based on space vector modulation (SVM-SMC) is proposed to achieve the tow rear driving wheel control. The performances of the proposed strategy controller give a satisfactory simulation results. The proposed control law increases the utility EV autonomous under several speed variations. Moreover, the future industrial's vehicle must take into considerations the battery material choice into design steps. The battery material model choice is a crucial item, and thanks to an increasing emphasis on vehicle range and performance, the Ni-MH battery could become a viable candidate that's our proposal battery model in the present work, in this way the present paper show a novel strategy of electric automobile (EA) power electronics studies when the current battery take into account the impact of the sliding mode control based onspace vector machine technique in the several speed variations using the primitive battery SOC of 60% state.

Brahim Mebarki; Belkacem Draoui; Lakhdar Rahmani; Boumediène Allaoua

2013-01-01T23:59:59.000Z

414

Optima Batteries | Open Energy Information  

Open Energy Info (EERE)

Optima Batteries Jump to: navigation, search Name: Optima Batteries Place: Milwaukee, WI Website: http:www.optimabatteries.com References: Optima Batteries1 Information About...

415

Hybrid and Plug-In Electric Vehicles (Brochure), Vehicle Technologies Program (VTP)  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Hybrid and plug-in electric vehicles Hybrid and plug-in electric vehicles use electricity as their primary fuel or to improve the efficiency of conventional vehicle designs. This new generation of vehicles, often called electric drive vehicles, can be divided into three cat- egories: hybrid electric vehicles (HEVs), plug-in hybrid electric vehicles (PHEVs), and all-electric vehicles (EVs). Together, they have great potential to reduce U.S. petroleum use. Hybrid Electric Vehicles HEVs are powered by an internal combus- tion engine or other propulsion source that runs on conventional or alternative fuel and an electric motor that uses energy stored in a battery. The extra power provided by the electric motor allows for a smaller engine, resulting in better fuel

416

NREL: Vehicles and Fuels Research - News  

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

Vehicles and Fuels Research News Vehicles and Fuels Research News The following news stories highlight vehicles and fuels research at NREL. December 23, 2013 NREL and Thought Leaders Gather at Electric Vehicle Battery Management Summit NREL researchers will gather with U.S. Department of Energy program directors and technology managers, and other thought leaders to exchange strategies for maximizing the performance, safety, and lifespan of electric-drive vehicle batteries. November 7, 2013 NREL Developed Mobile App for Alternative Fueling Station Locations Released iPhone users now have access to a free application that locates fueling stations offering alternative fuels, including electricity, natural gas, biodiesel, e85 Ethanol, propane and hydrogen. The Energy Department's (DOE) National Renewable Energy Laboratory (NREL) developed the new mobile

417

Reactive Power Operation Analysis of a Single-Phase EV/PHEV Bidirectional Battery Charger  

E-Print Network (OSTI)

--More battery powered electric vehicles (EVs) and plug-in hybrid electric vehicles (PHEVs) will be introduced, charger, electric vehicle, EV, PHEV, reactive power, V2G. I. INTRODUCTION According to the international of the electric grid by supplying ancillary services such as reactive power compensation, voltage regulation

Tolbert, Leon M.

418

EMISSIONS OF NITROUS OXIDE AND METHANE FROM CONVENTIONAL AND ALTERNATIVE FUEL MOTOR VEHICLES  

E-Print Network (OSTI)

-produced electricity for battery electric vehicles. Already, vehicles powered by compressed natural gas, propane. LIPMAN AND MARK A. DELUCCHI example, promising strategies for powering motor vehicles with reduced GHGEMISSIONS OF NITROUS OXIDE AND METHANE FROM CONVENTIONAL AND ALTERNATIVE FUEL MOTOR VEHICLES

Kammen, Daniel M.

419

Microsoft PowerPoint - Progress in Battery Swapping Technology and Demonstration in China  

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

ProgressinBatterySwapping ProgressinBatterySwapping TechnologyandDemonstrationinChina Jianfeng Hua Email: huajf@tsinghua.edu.cn Tel: 010-62789570 2 Outline Background Battery Swapping Demonstration in China Conclusion 3 HowtorefuelforElectricalVehicle? AC Charging DC Charging Battery Swapping  Duetothelimiteddrivingrangeofelectricalvehicle, therefuelforalongdistancedrivingisanessential

420

Comparative analysis of selected fuel cell vehicles  

SciTech Connect

Vehicles powered by fuel cells operate more efficiently, more quietly, and more cleanly than internal combustion engines (ICEs). Furthermore, methanol-fueled fuel cell vehicles (FCVs) can utilize major elements of the existing fueling infrastructure of present-day liquid-fueled ICE vehicles (ICEVs). DOE has maintained an active program to stimulate the development and demonstration o fuel cell technologies in conjunction with rechargeable batteries in road vehicles. The purpose of this study is to identify and assess the availability of data on FCVs, and to develop a vehicle subsystem structure that can be used to compare both FCVs and ICEV, from a number of perspectives--environmental impacts, energy utilization, materials usage, and life cycle costs. This report focuses on methanol-fueled FCVs fueled by gasoline, methanol, and diesel fuel that are likely to be demonstratable by the year 2000. The comparative analysis presented covers four vehicles--two passenger vehicles and two urban transit buses. The passenger vehicles include an ICEV using either gasoline or methanol and an FCV using methanol. The FCV uses a Proton Exchange Membrane (PEM) fuel cell, an on-board methanol reformer, mid-term batteries, and an AC motor. The transit bus ICEV was evaluated for both diesel and methanol fuels. The transit bus FCV runs on methanol and uses a Phosphoric Acid Fuel Cell (PAFC) fuel cell, near-term batteries, a DC motor, and an on-board methanol reformer. 75 refs.

NONE

1993-05-07T23:59:59.000Z

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


421

Cost-Effective Design of a Hybrid Electrical Energy Storage System for Electric Vehicles  

E-Print Network (OSTI)

of the battery cycle efficiency and state of health, characteristics of the supercapacitor bank, and dynamics energy storage system comprised of Li-ion batteries only. 1. INTRODUCTION Electric vehicles (EVs) have highly dependent on the intrinsic characteristics of Li-ion batteries. The cycle efficiency degradation

Pedram, Massoud

422

Entering a New Stage of Learning from the U.S. Fuel Cell Electric Vehicle Demonstration Project: Preprint  

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

To be Presented at 25th World Battery, Hybrid and Fuel Cell Electric Vehicle Symposium & Exhibition; Shenzhen, China; November 5-9, 2010

423

A rule-based energy management strategy for plug-in hybrid electric vehicle (PHEV)  

Science Journals Connector (OSTI)

Hybrid Electric Vehicles (HEV) combine the power from an electric motor with that from an internal combustion engine to propel the vehicle. The HEV electric motor is typically powered by a battery pack through power electronics. The HEV battery is recharged ...

Harpreetsingh Banvait; Sohel Anwar; Yaobin Chen

2009-06-01T23:59:59.000Z

424

A Control Strategy Scheme for Fuel Cell-Vehicle Based on Frequency Hamza Alloui  

E-Print Network (OSTI)

A Control Strategy Scheme for Fuel Cell-Vehicle Based on Frequency Separation Hamza Alloui based on frequency-separation for Fuel cell-Battery Hybrid Electric Vehicle (HEV), using a Fuel cell (FC of this strategy. Keywords ­ Fuel cell, hybrid source, battery, DC-DC Boost converter, Buck-boost converter

Boyer, Edmond

425

Optimized control studies of a parallel hybrid electric vehicle  

E-Print Network (OSTI)

This thesis addresses the development of a control scheme to maximize automobile fuel economy and battery state-of-charge (SOC) while meeting exhaust emission standards for parallel hybrid electric vehicles, which are an alternative to conventional...

Bougler, Benedicte Bernadette

1995-01-01T23:59:59.000Z

426

Vehicle Technologies Office Merit Review 2014: Overview of the...  

Energy Savers (EERE)

Advanced Battery R&D Program Presentation given by U.S. Department of Energy at 2014 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Office Annual Merit Review and...

427

Recent advances in lithium–sulfur batteries  

Science Journals Connector (OSTI)

Abstract Lithium–sulfur (Li–S) batteries have attracted much attention lately because they have very high theoretical specific energy (2500 Wh kg?1), five times higher than that of the commercial LiCoO2/graphite batteries. As a result, they are strong contenders for next-generation energy storage in the areas of portable electronics, electric vehicles, and storage systems for renewable energy such as wind power and solar energy. However, poor cycling life and low capacity retention are main factors limiting their commercialization. To date, a large number of electrode and electrolyte materials to address these challenges have been investigated. In this review, we present the latest fundamental studies and technological development of various nanostructured cathode materials for Li–S batteries, including their preparation approaches, structure, morphology and battery performance. Furthermore, the development of other significant components of Li–S batteries including anodes, electrolytes, additives, binders and separators are also highlighted. Not only does the intention of our review article comprise the summary of recent advances in Li–S cells, but also we cover some of our proposals for engineering of Li–S cell configurations. These systematic discussion and proposed directions can enlighten ideas and offer avenues in the rational design of durable and high performance Li–S batteries in the near future.

Lin Chen; Leon L. Shaw

2014-01-01T23:59:59.000Z

428

Infrastructure, Components and System Level Testing and Analysis of Electric Vehicles: Cooperative Research and Development Final Report, CRADA Number CRD-09-353  

SciTech Connect

Battery technology is critical for the development of innovative electric vehicle networks, which can enhance transportation sustainability and reduce dependence on petroleum. This cooperative research proposed by Better Place and NREL will focus on predicting the life-cycle economics of batteries, characterizing battery technologies under various operating and usage conditions, and designing optimal usage profiles for battery recharging and use.

Neubauer, J.

2013-05-01T23:59:59.000Z

429

Blog Feed: Vehicles | Department of Energy  

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

July 20, 2010 July 20, 2010 Eco-Driving: An Everyday Way to Reduce Our Oil Dependence Global warming and oil dependence are on the front burner for good, and for good reason. Thankfully, there is something we can all do today. July 15, 2010 VP 100: President Obama Hails Electric-Vehicle Battery Plant President Obama visits Compact Power in Holland, Michigan -- one of nine new battery plants under construction as a result of the $2.4 billion in Recovery Act advanced battery and electric vehicle awards the President announced last August. July 15, 2010 UQM will manufacture electric vehicle propulsion systems like this at its new facility in Longmont, Colo. | Photo courtesy of UQ VP 100: UQM revving up electric motor production How UQM Technologies, a Colorado-based manufacturer and developer of

430

Blog Feed: Vehicles | Department of Energy  

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

August 11, 2010 August 11, 2010 Cody Friesen and his team at Arizona State University | Photo Credit Arizona State University The Future of Electric Vehicles and Arizona State University's MAIL Battery Building cost-effective EVs just got a little easier. August 11, 2010 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 Novolyte Charging Up Electric Vehicle Sector Just outside Baton Rouge in Zachary, Louisiana, sits Novolyte Technologies, a battery component manufacturer in business since the early 1970s, making components for batteries used in everything from calculators to hearing

431

Alternative Fuels Data Center: All-Electric Vehicles  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

All-Electric Vehicles All-Electric Vehicles to someone by E-mail Share Alternative Fuels Data Center: All-Electric Vehicles on Facebook Tweet about Alternative Fuels Data Center: All-Electric Vehicles on Twitter Bookmark Alternative Fuels Data Center: All-Electric Vehicles on Google Bookmark Alternative Fuels Data Center: All-Electric Vehicles on Delicious Rank Alternative Fuels Data Center: All-Electric Vehicles on Digg Find More places to share Alternative Fuels Data Center: All-Electric Vehicles on AddThis.com... More in this section... Electricity Basics Benefits & Considerations Stations Vehicles Availability Conversions Emissions Batteries Deployment Maintenance & Safety Laws & Incentives Hybrids Plug-In Hybrids All-Electric Vehicles All-Electric Vehicles Content on this page requires a newer version of Adobe Flash Player.

432

Saft America Advanced Batteries Plant Celebrates Grand Opening in  

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

Saft America Advanced Batteries Plant Celebrates Grand Opening in Saft America Advanced Batteries Plant Celebrates Grand Opening in Jacksonville Saft America Advanced Batteries Plant Celebrates Grand Opening in Jacksonville September 16, 2011 - 12:30pm Addthis Department of Energy Investment Helps Support Job Creation, U.S. Economic Competitiveness and Advanced Vehicle Industry WASHINGTON, D.C. - Today, Secretary Steven Chu joined with Saft America to announce the grand opening of the company's Jacksonville, Florida, factory, which will produce advanced lithium-ion batteries to power electric vehicles and other applications. Saft America estimates it will create nearly 280 permanent jobs at the factory, and the city of Jacksonville expects an additional 800 indirect jobs to be created within its community. The project has created or preserved an estimated 300

433

A Comparison of US and Chinese EV Battery Testing Protocols  

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

US and Chinese EV US and Chinese EV Battery Testing Protocols: Results D. Robertson, 1 J. Christophersen, 2 Fang Wang, 3 Fan Bin, 3 I. Bloom 1 US/China Electric Vehicle Initiative Meeting August 23-24, 2012 Boston, MA 1 Argonne National Laboratory 2 Idaho National Laboratory 3 CATARC A Comparison of US and Chinese Battery Testing Protocols  Battery testing is a time-consuming and costly process  There are parallel testing efforts, such as those in the US and China  These efforts may be better leveraged through international collaboration  The collaboration may establish standardized, accelerated testing procedures and will allow battery testing organizations to cooperate in the analysis of the resulting data  In turn, the collaboration may accelerate electric vehicle development and

434

Wireless Power Transfer for Electric Vehicles  

SciTech Connect

As Electric and Hybrid Electric Vehicles (EVs and HEVs) become more prevalent, there is a need to change the power source from gasoline on the vehicle to electricity from the grid in order to mitigate requirements for onboard energy storage (battery weight) as well as to reduce dependency on oil by increasing dependency on the grid (our coal, gas, and renewable energy instead of their oil). Traditional systems for trains and buses rely on physical contact to transfer electrical energy to vehicles in motion. Until recently, conventional magnetically coupled systems required a gap of less than a centimeter. This is not practical for vehicles of the future.

Scudiere, Matthew B [ORNL; McKeever, John W [ORNL

2011-01-01T23:59:59.000Z

435

Batteries and Fuel Cells  

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

Collage of electric cars, plug, battery research lab Collage of electric cars, plug, battery research lab Batteries and Fuel Cells EETD researchers study the basic science and development of advanced batteries and fuel cells for transportation, electric grid storage, and other stationary applications. This research is aimed at developing more environmentally friendly technologies for generating and storing energy, including better batteries and fuel cells. Li-Ion and Other Advanced Battery Technologies Research conducted here on battery technology is aimed at developing low-cost rechargeable advanced electrochemical batteries for both automotive and stationary applications. The goal of fuel cell research is to provide the technologies for the successful commercialization of polymer-electrolyte and solid oxide fuel

436

Battery cell feedthrough apparatus  

DOE Patents (OSTI)

A compact, hermetic feedthrough apparatus is described comprising interfitting sleeve portions constructed of chemically-stable materials to permit unique battery designs and increase battery life and performance. 8 figs.

Kaun, T.D.

1995-03-14T23:59:59.000Z

437

Batteries and Fuel Cells  

Science Journals Connector (OSTI)

A battery is a device which can store chemical energy and, on demand, convert it into electrical energy to drive an external circuit. The importance of batteries to modern life surely requires no emphasis. Eve...

Derek Pletcher

1984-01-01T23:59:59.000Z

438

Batteries and fuel cells  

Science Journals Connector (OSTI)

A battery is a device which can store chemical energy and, on demand, convert it into electrical energy to drive an external circuit. The importance of batteries to modern life surely requires no emphasis. Eve...

Derek Pletcher; Frank C. Walsh

1993-01-01T23:59:59.000Z

439

Batteries and Energy Storage | Argonne National Laboratory  

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

The Joint Center for Energy Storage Research (JCESR) is a major research The Joint Center for Energy Storage Research (JCESR) is a major research partnership that integrates government, academic and industrial researchers from many disciplines to overcome critical scientific and technical barriers and create new breakthrough energy storage technology. Batteries and Energy Storage Argonne's all- encompassing battery research program spans the continuum from basic materials research and diagnostics to scale-up processes and ultimate deployment by industry. At Argonne, our multidisciplinary team of world-renowned researchers are working in overdrive to develop advanced energy storage technologies to aid the growth of the U.S. battery manufacturing industry, transition the U.S. automotive fleet to plug-in hybrid and electric vehicles, and enable

440

Composite Battery Boost | Advanced Photon Source  

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

Water-Like Properties of Soft Nanoparticle Suspensions Water-Like Properties of Soft Nanoparticle Suspensions Real-Time Capture of Intermediates in Enzymatic Reactions A New Multilayer-Based Grating for Hard X-ray Grating Interferometry The Most Detailed Picture Yet of a Key AIDS Protein Superconductivity with Stripes Science Highlights Archives: 2013 | 2012 | 2011 | 2010 2009 | 2008 | 2007 | 2006 2005 | 2004 | 2003 | 2002 2001 | 2000 | 1998 | Subscribe to APS Science Highlights rss feed Composite Battery Boost December 2, 2013 Bookmark and Share Normalized XANES spectra of Li/Se cell during cycling. Black line is the battery voltage profile. New composite materials based on selenium (Se) sulfides that act as the positive electrode in a rechargeable lithium-ion (Li-ion) battery could boost the range of electric vehicles by up to five times, according to

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


441

Vehicle Technologies Office: Maximizing Alternative Fuel Vehicle...  

Energy Savers (EERE)

Maximizing Alternative Fuel Vehicle Efficiency Vehicle Technologies Office: Maximizing Alternative Fuel Vehicle Efficiency Besides their energy security and environmental benefits,...

442

Smith Electric Vehicles: Advanced Vehicle Electrification + Transporta...  

Energy Savers (EERE)

Confidential, 4222013 2013 DOE VEHICLE TECHNOLOGIES PROGRAM REVIEW PRESENTATION Smith Electric Vehicles: Advanced Vehicle Electrification + Transportation Sector Electrification...

443

Innovation in Electric Vehicle Technology? Easy as A123 | Department of  

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

in Electric Vehicle Technology? Easy as A123 in Electric Vehicle Technology? Easy as A123 Innovation in Electric Vehicle Technology? Easy as A123 May 2, 2011 - 3:45pm Addthis A123 battery in passenger vehicle application | Photo Courtesy of A123 Systems A123 battery in passenger vehicle application | Photo Courtesy of A123 Systems Connie Bezanson Education & Outreach Manager, Vehicle Technologies Program Two weeks ago, I had the pleasure of visiting the great state of Michigan to participate in a two-day workshop entitled, "Electrifying the Economy - Educating the Workforce: Taking Charge of the Electric Vehicle Industry's Educational Needs." In addition to an exciting exchange on promoting innovation in the electric vehicle industry, I had the opportunity to see this innovation first-hand when I visited A123 Systems Livonia, MI battery

444

Secretary Chu's Remarks at a Batteries Announcement in North Carolina |  

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

a Batteries Announcement in North a Batteries Announcement in North Carolina Secretary Chu's Remarks at a Batteries Announcement in North Carolina August 5, 2009 - 12:00am Addthis I want to thank President Toth and everyone here at Polypore's Celgard subsidiary for welcoming me today. It is always a pleasure to be with the innovators and entrepreneurs who are rebuilding this economy from the ground up. Your work here at Celgard not only powers our computers, cameras, and cars - it will power our future prosperity. Today in Indiana, President Obama made an exciting announcement. The President announced $2.4 billion in funding through the American Recovery and Reinvestment Act for 48 advanced battery and electric vehicle projects. This is the single largest investment ever made in advanced battery

445

An Update on Advanced Battery Manufacturing | Department of Energy  

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

An Update on Advanced Battery Manufacturing An Update on Advanced Battery Manufacturing An Update on Advanced Battery Manufacturing October 16, 2012 - 9:41am Addthis Dan Leistikow Dan Leistikow Former Director, Office of Public Affairs What are the key facts? The advanced battery market is expanding dramatically in the U.S. and around the world -- from $5 billion in 2010 to nearly $50 billion in 2020, an average annual growth rate of roughly 25 percent. The Department of Energy, with strong bipartisan support, awarded $2 billion in grants to 29 companies to build or retool 45 manufacturing facilities spread across 20 states to build advanced batteries, engines, drive trains and other key components for electric vehicles. More than 30 of these plants are already in operation, employing thousands of American workers, and our grants were matched dollar for

446

Driving Battery Production in Ohio | Department of Energy  

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

Battery Production in Ohio Battery Production in Ohio Driving Battery Production in Ohio November 1, 2010 - 6:19pm Addthis Randy Turk, Elyria Site Manager; Rep. Betty Sutton (OH); Frank Bozich, President Catalysts, BASF and Patrick Davis, DOE Program Manager participate in groundbreaking ceremony for BASF battery materials plant in Elyria, Ohio | Photo Courtesy of Nat Clymer Photography, LLC | Randy Turk, Elyria Site Manager; Rep. Betty Sutton (OH); Frank Bozich, President Catalysts, BASF and Patrick Davis, DOE Program Manager participate in groundbreaking ceremony for BASF battery materials plant in Elyria, Ohio | Photo Courtesy of Nat Clymer Photography, LLC | Patrick B. Davis Patrick B. Davis Vehicle Technologies Program Manager Last week, I traveled to Elyria, Ohio (not far from Cleveland and the Rock

447

Update on the Battery Projects at NREL (Presentation)  

SciTech Connect

NREL collaborates with industry, universities, and other national laboratories as part of the DOE integrated Energy Storage Program to develop advanced batteries for vehicle applications. Our efforts are focused in the following areas: thermal characterization and analysis, evaluation of thermal abuse tolerance via modeling and experimental analysis, and implications on battery life and cost. Our activities support DOE goals, FreedomCAR targets, the USABC Tech Team, and battery developers. We develop tools to support the industry, both through one-on-one collaborations and by dissemination of information in the form of presentations in conferences and journal publications.

Santhanagopalan, S.; Pesaran, A.

2010-10-01T23:59:59.000Z

448

Vehicle Technologies Office: Hybrid and Vehicle Systems  

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

Hybrid and Vehicle Hybrid and Vehicle Systems to someone by E-mail Share Vehicle Technologies Office: Hybrid and Vehicle Systems on Facebook Tweet about Vehicle Technologies Office: Hybrid and Vehicle Systems on Twitter Bookmark Vehicle Technologies Office: Hybrid and Vehicle Systems on Google Bookmark Vehicle Technologies Office: Hybrid and Vehicle Systems on Delicious Rank Vehicle Technologies Office: Hybrid and Vehicle Systems on Digg Find More places to share Vehicle Technologies Office: Hybrid and Vehicle Systems on AddThis.com... Just the Basics Hybrid & Vehicle Systems Modeling & Simulation Integration & Validation Benchmarking Parasitic Loss Reduction Propulsion Systems Advanced Vehicle Evaluations Energy Storage Advanced Power Electronics & Electrical Machines

449

Vehicle Technologies Office: 2009 Advanced Vehicle Technology...  

Office of Environmental Management (EM)

Vehicle Technologies Office: 2009 Advanced Vehicle Technology Analysis and Evaluation Activities and Heavy Vehicle Systems Optimization Program Annual Progress Report Vehicle...

450

Argonne TTRDC - TransForum v10n1 - Taking PHEVs Farther on a Single Battery  

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

Charging Ahead: Taking PHEVs Farther on a Single Battery Charge Charging Ahead: Taking PHEVs Farther on a Single Battery Charge Ultracapacitors Ultracapacitors will dramatically boost the power of lithium-ion batteries, enabling plug-in vehicles to travel much further on a single charge. Every six months, we're reminded to change the batteries in our household appliances: smoke alarms, flashlights and radios. But what if you had to change the battery in your plugin hybrid electric vehicle (PHEV) just as often? Fortunately, researchers at Argonne may have found a way to exponentially increase the calendar and cycle lifetimes of lithium-ion batteries. Electric double-layer capacitors- typically referred to as ultracapacitors-have an energy density thousands of times greater than conventional capacitors and a power density hundreds of times greater than

451

Plug-In Hybrid Electric Vehicles - Prototypes  

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

Prototypes Prototypes A PHEV prototype being prepared for testing. A plug-in electric vehicle (PHEV) prototype is prepared for testing at Argonne National Laboratory. What is a PHEV? A plug-in hybrid electric vehicle, or PHEV, is similar to today's hybrid electric vehicles on the market today, but with a larger battery that is charged both by the vehicle's gasoline engine and from plugging into a standard 110 V electrical outlet for a few hours each day. PHEVs and HEVs both use battery-powered motors and gasoline-powered engines for high fuel efficiency, but PHEVs can further reduce fuel usage by employing electrical energy captured through daily charging. Prototype as Rolling Test Bed As part of Argonne's multifaceted PHEV research program, Argonne researchers have constructed a PHEV prototype that serves as a rolling test

452

Second-Use Li-Ion Batteries to Aid Automotive and Utility Industries (Fact Sheet)  

SciTech Connect

Repurposing Li-ion batteries at the end of useful life in electric drive vehicles could eliminate owners' disposal concerns and offer low-cost energy storage for certain applications.

Not Available

2014-01-01T23:59:59.000Z

453

Battery Charge Depletion Prediction on an Electric Aircraft Quach Cuong Chi1  

E-Print Network (OSTI)

(EOD) prediction is described in Section 3. Battery state of charge (SOC) estimation and EOD prediction. Uncertain EOD pre- dictions made over a sample flight of the unmanned aerial vehicle (UAV) are presented

Daigle, Matthew

454

Development of Novel Nanomaterials for Lithium-Air and Sodium-Air Batteries.  

E-Print Network (OSTI)

??Lithium-air and sodium-air batteries are promising energy storage systems for future smart grids and electric vehicles due to their extremely high theoretical energy densities. However,… (more)

Li, Yongliang

2013-01-01T23:59:59.000Z

455

Techno-Economic Analysis of BEV Service Providers Offering Battery Swapping Services (Presentation)  

SciTech Connect

Battery electric vehicles (BEVs) could significantly reduce the nation's gasoline consumption and greenhouse gas emissions rates. However, both the upfront cost and the limited range of the vehicle are perceived to be deterrents to the widespread adoption of BEVs. A service provider approach to marketing BEVs, coupled with a battery swapping infrastructure deployment could address both issues and accelerate BEV adoption. This presentation examines customer selection, service usage statistics, service plan fees and driver economics. Our results show it is unlikely that a battery swapping service plan will be more cost-effective than ownership of a conventional vehicle. A battery swapping service plan may be a more cost-effective solution than a directly owned BEV for some single-vehicle, high-mileage consumers. However, other factors not considered in this analysis could decrease the viability of such a service.

Neubauer, J.; Pesaran, A.

2013-05-01T23:59:59.000Z

456

Power Capability Estimation Accounting for Thermal and Electical Contraints of Lithium-Ion Batteries.  

E-Print Network (OSTI)

??Lithium-ion (Li-ion) batteries have become one of the most critical components in vehicle electrification due to their high specific power and energy density. The performance… (more)

Kim, Youngki

2014-01-01T23:59:59.000Z

457

B-Doped Graphene as Catalyst To Improve Charge Rate of Lithium–Air Battery  

Science Journals Connector (OSTI)

B-Doped Graphene as Catalyst To Improve Charge Rate of Lithium–Air Battery ... The lithium–air battery as an energy storage technology can be used in electric vehicles due to its large energy density, while its poor rate capability limits its practical usage under large current density. ... According to first-principles thermodynamics calculation, we predict B-doped graphene can be a potential catalyst to improve the charge rate of lithium–air battery. ...

Xiaodong Ren; Jinzhen Zhu; Fuming Du; Jianjun Liu; Wenqing Zhang

2014-09-10T23:59:59.000Z

458

Laboratory testing of Saft SEH-5-200 6 volt traction battery  

SciTech Connect

The purpose of this report is to describe the testing performed on the Saft SEH-5-200 flooded nickel cadmium traction battery by the INEL Electric Vehicle Battery Laboratory, to present the results and conclusions of this testing, and to make appropriate recommendations. 17 figs., 3 tabs.

Hardin, J.E.

1989-12-01T23:59:59.000Z

459

Influence of driving patterns on life cycle cost and emissions of hybrid and plug-in electric vehicle powertrains  

E-Print Network (OSTI)

that could be powered entirely by electricity using plug- in vehicles. Thus, plug-in vehicles have assessment Plug-in hybrid electric vehicles a b s t r a c t We compare the potential of hybrid, extended-range plug-in hybrid, and battery electric vehicles to reduce lifetime cost and life cycle greenhouse gas

Michalek, Jeremy J.

460

246 Int. J. Electric and Hybrid Vehicles, Vol. 3, No. 3, 2011 Copyright 2011 Inderscience Enterprises Ltd.  

E-Print Network (OSTI)

@ieee.org *Corresponding author Abstract: This paper studies the power management of a plug-in hybrid electric vehicle vehicles and plug-in hybrid electric vehicles. #12;Power management of PHEV using quadratic programming 247. Pure battery powered electric vehicle (EV) is considered as the future because it does not rely

Mi, Chunting "Chris"

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


461

Vehicle Technologies Office Merit Review 2013: Abuse Tolerance Improvements  

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

Presentation given by Sandia National Laboratory (SNL) at the 2013 DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting on improving the tolerance of batteries for plug-in electric vehicles under abusive conditions.

462

Vehicle Technologies Office: Modeling, Testing and Analysis  

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

Modeling, Testing and Analysis Modeling, Testing and Analysis The Vehicle Technologies Office's robust portfolio is supported by modeling, testing, and analysis. This work complements the research on batteries, power electronics, and materials, helping researchers integrate these components and ensure the whole vehicle meets consumer and commercial needs. Modeling allows researchers to build "virtual vehicles" that simulate fuel economy, emissions and performance of a potential vehicle. The Office has supported the development of several software-based analytic tools that researchers can use or license. Integration and Validation allows researchers to test physical component and subsystem prototypes as if they are in a real vehicle. Laboratory and Fleet Testing provides data on PEVs through both dynamometer and on-the-road testing. Researchers use the data to benchmark current vehicles, as well as validate the accuracy of software models.

463

Modeling of Transport in Lithium Ion Battery Electrodes  

E-Print Network (OSTI)

, such as batteries and fuel cells, versus other devices like capacitors and internal combustion (IC) engines. The goals for current hybrid and all electric vehicles are also illustrated. Adapted from (2... other devices like capacitors and internal combustion (IC) engines. The goals for current hybrid and all electric vehicles are also illustrated. Adapted from (2). The dashed lines in the above plot indicate discharge rates, where very short...

Martin, Michael

2012-07-16T23:59:59.000Z

464

SOLAR-POWERED AUTONOMOUS UNDERWATER VEHICLE DEVELOPMENT James Jalbert, John Baker, John Duchesney, Paul Pietryka, William Dalton  

E-Print Network (OSTI)

batteries daily using solar panels to convert solar energy to electrical energy. #12;· Operate at depthsSOLAR-POWERED AUTONOMOUS UNDERWATER VEHICLE DEVELOPMENT James Jalbert, John Baker, John Duchesney in such applications. The concept of a vehicle that would allow on-station recharging of batteries, using solar cells

465

Vehicle Technologies Office: Vehicle Technologies Office Recognizes  

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

Vehicle Technologies Vehicle Technologies Office Recognizes Outstanding Researchers to someone by E-mail Share Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on Facebook Tweet about Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on Twitter Bookmark Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on Google Bookmark Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on Delicious Rank Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on Digg Find More places to share Vehicle Technologies Office: Vehicle Technologies Office Recognizes Outstanding Researchers on AddThis.com...

466

Scientists Create Worlds Smallest Battery | U.S. DOE Office of Science (SC)  

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

Scientists Create World's Smallest Battery Scientists Create World's Smallest Battery Stories of Discovery & Innovation Scientists Create World's Smallest Battery Enlarge Photo Image shows distortion of nanowire electrode during charging. Researchers were able to observe charging and discharging in real time at atomic-level resolution. 05.16.11 Scientists Create World's Smallest Battery Effort yields insights that could improve battery performance. Rechargeable lithium-ion (Li-ion) batteries have become the workhorse of the contemporary electronic age, powering everything from cell phones and laptop computers to hybrid electric vehicles. But while superior to many alternatives for electrical energy storage, Li-ion batteries are not optimal in every respect. Despite much progress over the years, their

467

10 Questions for a Batteries Expert: Daniel Abraham | Department of Energy  

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

10 Questions for a Batteries Expert: Daniel Abraham 10 Questions for a Batteries Expert: Daniel Abraham 10 Questions for a Batteries Expert: Daniel Abraham August 11, 2011 - 3:56pm Addthis Dan Abraham | Image Courtesy of Argonne National Laboratory Dan Abraham | Image Courtesy of Argonne National Laboratory Angela Hardin Media Specialist at Argonne National Laboratory "Almost every cell phone contains a lithium-ion battery; they are also in our cameras, camcorders, and computers. Our goal is to get the batteries into our cars - into the next generation of plug-in hybrid and electric vehicles." Dan Abraham, Batteries Expert Ed. note: This is a cross-post from Argonne National Laboratory. In the latest 10 Questions, Daniel Abraham, a leading scientist at Argonne National Laboratory, shares his work on lithium-ion batteries and why he

468

New Energy 101 Video: Electric Vehicles | Department of Energy  

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

New Energy 101 Video: Electric Vehicles New Energy 101 Video: Electric Vehicles New Energy 101 Video: Electric Vehicles January 17, 2012 - 5:15am Addthis Eric Barendsen Energy Technology Program Specialist, Office of Energy Efficiency and Renewable Energy Electric vehicles, sometimes called EVs, can give drivers like you a convenient way to get around, while saving you money on fuel, reducing emissions, and supporting the nation's energy security. Learn about the advantages of electric vehicles, see EVs in action, and find out how they work by checking out DOE's new Electric Vehicle 101 video. The basics principles behind this technology are this: the EV's battery transfers energy to an electric motor, the motor turns a drive train, which then turns the wheels. Up to 80% of the energy in the battery is

469

Ramping-up Investments in Advanced Vehicle Technologies | Department of  

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

Ramping-up Investments in Advanced Vehicle Technologies Ramping-up Investments in Advanced Vehicle Technologies Ramping-up Investments in Advanced Vehicle Technologies August 10, 2011 - 5:06pm Addthis John Schueler John Schueler Former New Media Specialist, Office of Public Affairs What does this project do? Accelerates the development and deployment of next-generation vehicle technologies. Helps improve vehicle fuel efficiency and create quality jobs. Today, Secretary Chu announced the selection of 40 projects across 15 states to receive more than $175 million to accelerate the development and deployment of next-generation vehicle technologies. From state-of-the-art electric drive batteries to light-weight vehicles, these projects will help improve vehicle fuel efficiency and create quality jobs. The selected projects focus on eight key approaches to improving vehicle

470

Ramping-up Investments in Advanced Vehicle Technologies | Department of  

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

Ramping-up Investments in Advanced Vehicle Technologies Ramping-up Investments in Advanced Vehicle Technologies Ramping-up Investments in Advanced Vehicle Technologies August 10, 2011 - 5:06pm Addthis John Schueler John Schueler Former New Media Specialist, Office of Public Affairs What does this project do? Accelerates the development and deployment of next-generation vehicle technologies. Helps improve vehicle fuel efficiency and create quality jobs. Today, Secretary Chu announced the selection of 40 projects across 15 states to receive more than $175 million to accelerate the development and deployment of next-generation vehicle technologies. From state-of-the-art electric drive batteries to light-weight vehicles, these projects will help improve vehicle fuel efficiency and create quality jobs. The selected projects focus on eight key approaches to improving vehicle

471

The Future of Electric Vehicles and Arizona State University's MAIL  

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

The Future of Electric Vehicles and Arizona State University's The Future of Electric Vehicles and Arizona State University's MAIL Battery The Future of Electric Vehicles and Arizona State University's MAIL Battery August 11, 2010 - 4:26pm Addthis Cody Friesen and his team at Arizona State University | Photo Credit Arizona State University Cody Friesen and his team at Arizona State University | Photo Credit Arizona State University Andy Oare Andy Oare Former New Media Strategist, Office of Public Affairs What does this mean for me? EV batteries will have the ability to recharge at least 1000 times at a low cost due to its composition of only domestically-sourced, earth abundant material Electric Vehicles are becoming a reality. Last month, the President got behind the wheel of a Chevy Volt in Michigan, and traveled to Smith

472

Argonne Lab's Breakthrough Cathode Technology Powers Electric Vehicles of  

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

Argonne Lab's Breakthrough Cathode Technology Powers Electric Argonne Lab's Breakthrough Cathode Technology Powers Electric Vehicles of Today Argonne Lab's Breakthrough Cathode Technology Powers Electric Vehicles of Today February 14, 2011 - 6:15pm Addthis Jeff Chamberlain Speaks at Brookings Battery Forum | Photo Courtesy of Audra Capas, 5StarPR Jeff Chamberlain Speaks at Brookings Battery Forum | Photo Courtesy of Audra Capas, 5StarPR David Moore Presidential Management Fellow, Office of Energy Efficiency & Renewable Energy The Department of Energy has been investing in vehicle electrification for more than a decade, with results that speak for themselves: The battery technologies in almost all of the electric vehicles and hybrids on the road today were developed with support from the Department. As you may have read

473

Impact of SiC Devices on Hybrid Electric and Plug-in Hybrid Electric Vehicles  

E-Print Network (OSTI)

Impact of SiC Devices on Hybrid Electric and Plug-in Hybrid Electric Vehicles Hui Zhang1 , Leon M -- The application of SiC devices (as battery interface, motor controller, etc.) in a hybrid electric vehicle (HEV, vehicle simulation software). Power loss models of a SiC inverter are incorporated into PSAT powertrain

Tolbert, Leon M.

474

The Canadian Plug-in Electric Vehicle Survey (CPEVS 2013): Anticipating Purchase, Use, and Grid Interactions  

E-Print Network (OSTI)

electric vehicles (PHEVs) that can be powered by grid electricity for an initial distance, say 60 km, but are otherwise powered by gasoline until the battery is recharged (e.g. the Chevrolet Volt) and Electric vehiclesThe Canadian Plug-in Electric Vehicle Survey (CPEVS 2013): Anticipating Purchase, Use, and Grid

475

Monitoring System for Testing the Performance of an Electric Vehicle Using Ultracapacitors  

E-Print Network (OSTI)

Monitoring System for Testing the Performance of an Electric Vehicle Using Ultracapacitors Juan W. Dixon, Micah Ortúzar and Jorge Moreno Abstract A monitoring system for an Electric Vehicle, which uses of ultracapacitors in combination with batteries in electric vehicles. The efficiency gain is being monitored

Catholic University of Chile (Universidad Católica de Chile)

476

Use of a thermophotovoltaic generator in a hybrid electric vehicle  

Science Journals Connector (OSTI)

Viking 29 is the World’s first thermophotovoltaic (TPV) powered automobile. The prototype was funded by the Department of Energy and designed and built by students and faculty at the Vehicle Research Institute (VRI) at Western Washington University. Viking 29 is a series hybrid electric vehicle that utilizes TPV generators to charge its battery pack. Acceleration speed and handling compare to modern high performance sports cars while emissions are cleaner than current internal combustion engine vehicles.

Orion Morrison; Michael Seal; Edward West; William Connelly

1999-01-01T23:59:59.000Z

477

battery2.indd  

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

High Power Battery Systems Company 5 Silkin Street, Apt. 40 Sarov, Nizhny Novgorod Russia, 607190 Alexander A. Potanin 7-(83130)-43701 (phonefax), potanin@hpbs.ru General...

478

EMSL - battery materials  

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

battery-materials en Measuring Spatial Variability of Vapor Flux to Characterize Vadose-zone VOC Sources: Flow-cell Experiments. http:www.emsl.pnl.govemslwebpublications...

479

GBP Battery | Open Energy Information  

Open Energy Info (EERE)

GBP Battery Place: China Product: Shenzhen-China-based maker of Li-Poly and Li-ion batteries suitable for EVs and other applications. References: GBP Battery1 This article is...

480

Electric Vehicles  

ScienceCinema (OSTI)

Burak Ozpineci sees a future where electric vehicles charge while we drive them down the road, thanks in part to research under way at ORNL.

Ozpineci, Burak

2014-07-23T23:59:59.000Z

Note: This page contains sample records for the topic "vehicle batteries cxs" from the National Library of EnergyBeta (NLEBeta).
While these samples are representative of the content of NLEBeta,
they are not comprehensive nor are they the most current set.
We encourage you to perform a real-time search of NLEBeta
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481

Electric Vehicles  

SciTech Connect

Burak Ozpineci sees a future where electric vehicles charge while we drive them down the road, thanks in part to research under way at ORNL.

Ozpineci, Burak

2014-05-02T23:59:59.000Z

482

Prieto Battery | Open Energy Information  

Open Energy Info (EERE)

Colorado-based startup company that is developing lithium ion batteries based on nano-structured materials. References: Prieto Battery1 This article is a stub. You can...

483

Blog Feed: Vehicles | Department of Energy  

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

January 18, 2011 January 18, 2011 Fuel Economy on the Fly If you're in the market for a new car, FuelEconomy.gov can help you pick the most fuel-efficient vehicle for your needs. January 12, 2011 A Look Inside the Detroit Auto Show A first hand perspective from the floor of the North American International Auto Show. January 11, 2011 Chevy Volt and replica battery | Photo Courtesy of Argonne Lab's Flickr The Department of Energy's Innovation in GM's Chevrolet Volt Argonne National Laboratory's breakthrough battery technology makes its way into the Chevy Volt. January 3, 2011 10 Ways to Save Money and Energy in the New Year These easy tips are great way to save money and energy throughout the New Year. December 22, 2010 The Facts On Electric Vehicles: Interview with Pat Davis Pat Davis, the Director of our Vehicle Technologies Program, doles out the

484

Differential thermal voltammetry for tracking of degradation in lithium-ion batteries  

Science Journals Connector (OSTI)

Abstract Monitoring of lithium-ion batteries is of critical importance in electric vehicle applications in order to manage the operational condition of the cells. Measurements on a vehicle often involve current, voltage and temperature which enable in-situ diagnostic techniques. This paper presents a novel diagnostic technique, termed differential thermal voltammetry, which is capable of monitoring the state of the battery using voltage and temperature measurements in galvanostatic operating modes. This tracks battery degradation through phase transitions, and the resulting entropic heat, occurring in the electrodes. Experiments to monitor battery degradation using the new technique are compared with a pseudo-2D cell model. Results show that the differential thermal voltammetry technique provides information comparable to that of slow rate cyclic voltammetry at shorter timescale and with load conditions easier to replicate in a vehicle.

Billy Wu; Vladimir Yufit; Yu Merla; Ricardo F. Martinez-Botas; Nigel P. Brandon; Gregory J. Offer

2015-01-01T23:59:59.000Z

485

Materials as a Key to Electro-Mobility with Rechargeable LI Batteries  

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

Materials as a Key to Electro-Mobility with Rechargeable LI Batteries Materials as a Key to Electro-Mobility with Rechargeable LI Batteries Speaker(s): Martin Winter Date: February 11, 2013 - 12:00pm Location: 90-3122 Seminar Host/Point of Contact: Robert Kostecki The lithium ion technology is playing a key role in the electrification of the propulsion system in hybrid electric vehicles (HEVs) and in pure electric vehicles (EVs). The chemist and materials scientists faces this challenge, which derives from the demands for large-scale energy storage and conversion devices for electric propulsion purposes, by development and application of innovative battery components and concepts. The lithium ion battery has been introduced into the market by 1990/1991 and only by the mid 1990ies significant numbers of batteries have been produced. Within a

486

Advanced High Energy and High Power Battery Systems for Automotive Applications Khalil Amine  

E-Print Network (OSTI)

Geothermal 2.5 Wind 0.22 Solar 0.02 Coal 110 Natural Gas 107 Residential 50 Vehicle 39 Freight 40 Air 129.30am Advanced High Energy and High Power Battery Systems for Automotive Applications Khalil Amine electric drive Plug in Hybrid Electric Vehicle (P-HEVs), long range electric vehi cle (EV) and sm art grid

Levi, Anthony F. J.

487

Electromechanical battery research and development at the Lawrence Livermore National Laboratory  

SciTech Connect

The concepts undergirding a funded program to develop a modular electromechanical battery (EMB) at the Lawrence Livermore National Laboratory are described. Example parameters for EMBs for electric and hybrid-electric vehicles are given, and the importance of the high energy recovery efficiency of EMBs in increasing vehicle range in urban driving is shown.

Post, R.F.; Baldwin, D.E.; Bender, D.A.; Fowler, T.K.

1993-06-01T23:59:59.000Z

488

ABAA - 6th International Conference on Advanced Lithium Batteries for  

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

Conference Information Conference Information About ABAA6 We cordially invite you to the 6th International Conference on Advanced Lithium Batteries for Automobile Applications (ABAA6) to be held in Chicago, Illinois, USA on September 9-11, 2013. The ABAA6 Organizing Committee is busy creating various scientific programs, as well as social activities, to advance battery knowledge with the purpose of expanding vehicle electrification. We hope you will join us at ABAA6 and have a meaningful time interacting with your fellow global experts. Previous Conferences 2008 Chicago 2009 Tokyo 2010 Seoul 2011 Beijing 2012 Istanbul Conference At-A-Glance Title 6th International Conference on Advanced Lithium Batteries for Automobile Applications (ABAA6) Theme Advanced Battery Technologies for Automotive Applications

489

Success Stories: Solid Electrolyte Lithium Ion Batteries - Seeo, Inc.  

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

Solid Electrolyte May Usher in a New Generation of Solid Electrolyte May Usher in a New Generation of Rechargeable Lithium Batteries For Vehicles With sky rocketing gasoline prices and exploding laptops, there could not have been a better time for a new rechargeable battery breakthrough. Enter Lawrence Berkeley National Laboratory's (LBNL) nanostructured polymer electrolyte (NPE). NPE is a solid electrolyte designed for use in rechargeable lithium batteries. The unique material was developed by LBNL researchers Nitash Balsara, Hany Eitouni, Enrique Gomez, and Mohit Singh and licensed to startup company Seeo Inc. in 2007. With solid financial backing from Khosla Ventures, located in Menlo Park, California, and an impressive scientific team recruited from LBNL, University of California, Berkeley, and the battery industry, Seeo is now

490

Vehicle Technologies Office: 2008 Advanced Vehicle Technology...  

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

8 Advanced Vehicle Technology Analysis and Evaluation Activities and Heavy Vehicle Systems Optimization Program Annual Progress Report Vehicle Technologies Office: 2008 Advanced...

491

Tanks for the Batteries  

Science Journals Connector (OSTI)

...kg), in the most common flow batteries that number ranges from 20 to 50 Wh/kg. Most modular units now under development range in size from refrigerators to railcars. A flow battery in Osaka, Japan, that's capable of storing a megawatt...

Robert F. Service

2014-04-25T23:59:59.000Z

492

Techno-Economic Analysis of BEV Service Providers Offering Battery Swapping Services  

SciTech Connect

Battery electric vehicles (BEVs) offer the potential to reduce both oil imports and greenhouse gas emissions, but high upfront costs, battery-limited vehicle range, and concern over high battery replacement costs may discourage potential buyers. A subscription model in which a service provider owns the battery and supplies access to battery swapping infrastructure could reduce upfront and replacement costs for batteries with a predictable monthly fee, while expanding BEV range. Assessing the costs and benefits of such a proposal are complicated by many factors, including customer drive patterns, the amount of required infrastructure, battery life, etc. The National Renewable Energy Laboratory has applied its Battery Ownership Model to compare the economics and utility of BEV battery swapping service plan options to more traditional direct ownership options. Our evaluation process followed four steps: (1) identifying drive patterns best suited to battery swapping service plans, (2) modeling service usage statistics for the selected drive patterns, (3) calculating the cost-of-service plan options, and (4) evaluating the economics of individual drivers under realistically priced service plans. A service plan option can be more cost-effective than direct ownership for drivers who wish to operate a BEV as their primary vehicle where alternative options for travel beyond the single-charge range are expensive, and a full-coverage-yet-cost-effective regional infrastructure network can be deployed. However, when assumed cost of gasoline, tax structure, and absence of purchase incentives are factored in, our calculations show the service plan BEV is rarely more cost-effective than direct ownership of a conventional vehicle.

Neubauer, J. S.; Pesaran, A.

2013-01-01T23:59:59.000Z

493

Blog Feed: Vehicles | Department of Energy  

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

Blog Feed: Vehicles Blog Feed: Vehicles Blog Feed: Vehicles RSS September 11, 2013 Dr. Michael Knotek, Deputy Undersecretary for Science and Energy at the Energy Department, delivers remarks at the NASCAR Green Summit in Chicago, where the DOE-NASCAR MOU was announced. | Photo courtesy of NASCAR. New DOE-NASCAR Partnership Revs Deployment of Pollution Reducing Technologies From the electricity that powers race-day broadcasts to the fuel in the cars themselves, a new DOE-NASCAR Memorandum of Understanding pinpoints transformative energy technologies that will benefit NASCAR and its fans. September 4, 2013 Dr. Ping Liu of ARPA-E discusses the RANGE program and its innovative approach to energy storage for electric vehicles. | Photo courtesy of ARPA-E. ARPA-E Program Takes an Innovative Approach to Electric Vehicle Batteries

494

Advanced Vehicle Technologies Awards Table | Department of Energy  

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

Vehicle Technologies Awards Table Vehicle Technologies Awards Table Advanced Vehicle Technologies Awards Table The table contains a listing of the applicants, their locations, the amounts of the awards, and description of each project. The sub-categories of the table include: Advanced fuels and lubricants Light-weighting materials Demonstration Project for a Multi-Material Light-Weight Prototype Vehicle Advanced cells and design technology for electric drive batteries Advanced power electronics and electric motor technology Solid State Thermoelectric Energy Conversion Devices Fleet Efficiency Advanced Vehicle Testing and Evaluation Microsoft Word - VTP $175 Advanced Vehicle Tech project descriptions draft v5 8-2-11 More Documents & Publications Advanced Vehicle Technologies Awards advanced vehicle technologies awards table

495

Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Plug-In Hybrid Plug-In Hybrid Electric Vehicles to someone by E-mail Share Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on Facebook Tweet about Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on Twitter Bookmark Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on Google Bookmark Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on Delicious Rank Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on Digg Find More places to share Alternative Fuels Data Center: Plug-In Hybrid Electric Vehicles on AddThis.com... More in this section... Electricity Basics Benefits & Considerations Stations Vehicles Availability Conversions Emissions Batteries Deployment Maintenance & Safety Laws & Incentives Hybrids

496

Diesel Vehicles  

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

Vehicles Vehicles Audi A3 Diesel vehicles may be making a comeback. Diesel engines are more powerful and fuel-efficient than similar-sized gasoline engines (about 30-35% more fuel efficient). Plus, today's diesel vehicles are much improved over diesels of the past. Better Performance Improved fuel injection and electronic engine control technologies have Increased power Improved acceleration Increased efficiency New engine designs, along with noise- and vibration-damping technologies, have made them quieter and smoother. Cold-weather starting has been improved also. Cleaner Mercedes ML320 BlueTEC Today's diesels must meet the same emissions standards as gasoline vehicles. Advances in engine technologies, ultra-low sulfur diesel fuel, and improved exhaust treatment have made this possible.

497

Improving Vehicle Efficiency, Reducing Dependence on Foreign Oil (Fact Sheet)  

SciTech Connect

This fact sheet provides an overview of the U.S. Department of Energy's Vehicle Technologies Program. Today, the United States spends about $400 billion each year on imported oil. To realize a secure energy future, America must break its dependence on imported oil and its volatile costs. The transportation sector accounts for about 70% of U.S. oil demand and holds tremendous opportunity to increase America's energy security by reducing oil consumption. That's why the U.S. Department of Energy (DOE) conducts research and development (R and D) on vehicle technologies which can stem America's dependence on oil, strengthen the economy, and protect the environment. Hybrid-electric and plug-in hybrid-electric vehicles can significantly improve fuel economy, displacing petroleum. Researchers are making batteries more affordable and recyclable, while enhancing battery range, performance, and life. This research supports President Obama's goal of putting 1 million electric vehicles on the road by 2015. The program is also working with businesses to develop domestic battery and electric-drive component plants to improve America's economic competitiveness globally. The program facilitates deployment of alternative fuels (ethanol, biodiesel, hydrogen, electricity, propane, and natural gas) and fuel infrastructures by partnering with state and local governments, universities, and industry. Reducing vehicle weight directly improves vehicle efficiency and fuel economy, and can potentially reduce vehicle operating costs. Cost-effective, lightweight, high-strength materials can significantly reduce vehicle weight without compromising safety. Improved combustion technologies and optimized fuel systems can improve near-and mid-term fuel economy by 25% for passenger vehicles and 20% for commercial vehicles by 2015, compared to 2009 vehicles. Reducing the use of oil-based fuels and lubricants in vehicles has more potential to improve the nation's energy security than any other action; even a 1% improvement in vehicle fuel efficiency would save consumers more than $4 billion annually.

Not Available

2012-03-01T23:59:59.000Z

498

Electric Vehicle Preparedness Task 3: Detailed Assessment of Target Electrification Vehicles at Joint Base Lewis McChord Utilization  

SciTech Connect

Task 2 involved identifying daily operational characteristics of select vehicles and initiating data logging of vehicle movements in order to characterize the vehicle’s mission. Individual observations of these selected vehicles provide the basis for recommendations related to PEV adoption and whether a battery electric vehicle (BEV) or plug-in hybrid electric vehicle (PHEV) (collectively PEVs) can fulfill the mission requirements and provides observations related to placement of PEV charging infrastructure. This report provides the results of the data analysis and observations related to the replacement of current vehicles with PEVs. This fulfills part of the Task 3 requirements. Task 3 also includes an assessment of charging infrastructure required to support this replacement. That is the subject of a separate report.

Stephen Schey; Jim Francfort

2014-08-01T23:59:59.000Z

499

Evaluation of a Current Source Active Power Filter to Reduce the DC Bus Capacitor in a Hybrid Electric Vehicle Traction Drive  

E-Print Network (OSTI)

Electric Vehicle Traction Drive Shengnan Li Student Member, IEEE The University of Tennessee Department Science Knoxville, TN, 37996, USA tolbert@utk.edu Abstract ­ In hybrid electric vehicles (HEV), a battery-source inverter, dc bus capacitor, Electric vehicle, Harmonic current, Hybrid electric vehicle. I. INTRODUCTION

Tolbert, Leon M.

500

NREL: Vehicles and Fuels Research - NREL and Thought Leaders Gather at  

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

NREL and Thought Leaders Gather at Electric Vehicle Battery Management NREL and Thought Leaders Gather at Electric Vehicle Battery Management Summit Battery cyclers in NREL's Thermal Test Facility. The January 10 tour will feature NREL's Thermal Test Facility, which houses equipment including these battery cyclers used in AMPED research. Photo by Dennis Schroeder, NREL December 23, 2013 From January 8 to 10, 2014, National Renewable Energy Laboratory (NREL) researchers, U.S. Department of Energy (DOE) program directors and technology managers, and other thought leaders will gather in Denver, Colorado, to exchange strategies for maximizing the performance, safety, and lifespan of the next generation of electric-drive vehicle (EDV) batteries. This annual review of DOE Advanced Research Projects Agency-Energy's (ARPA-E's) Advanced Management and Protection of Energy