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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,
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We encourage you to perform a real-time search of NLEBeta
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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  

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

vehicles. In fact, every hybrid vehicle on the market currently uses Nickel-Metal-Hydride high-voltage batteries in its battery system. Lithium ion batteries appear to be the...

3

Vehicle Technologies Office: Battery Systems  

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

Battery Systems to someone by E-mail Share Vehicle Technologies Office: Battery Systems on Facebook Tweet about Vehicle Technologies Office: Battery Systems on Twitter Bookmark...

4

BEEST: Electric Vehicle Batteries  

SciTech Connect

BEEST Project: The U.S. spends nearly a $1 billion per day to import petroleum, but we need dramatically better batteries for electric and plug-in hybrid vehicles (EV/PHEV) to truly compete with gasoline-powered cars. The 10 projects in ARPA-E’s BEEST Project, short for “Batteries for Electrical Energy Storage in Transportation,” could make that happen by developing a variety of rechargeable battery technologies that would enable EV/PHEVs to meet or beat the price and performance of gasoline-powered cars, and enable mass production of electric vehicles that people will be excited to drive.

None

2010-07-01T23:59:59.000Z

5

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.

6

VEHICLE DETAILS, BATTERY DESCRIPTION AND SPECIFICATIONS Vehicle...  

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

Page 1 VEHICLE DETAILS, BATTERY DESCRIPTION AND SPECIFICATIONS Vehicle Details Base Vehicle: 2011 Nissan Leaf VIN: JN1AZ0CP5BT000356 Propulsion System: BEV Electric Machine: 80 kW...

7

Vehicle Technologies Office: Applied Battery Research  

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

Applied Battery Research to someone by E-mail Share Vehicle Technologies Office: Applied Battery Research on Facebook Tweet about Vehicle Technologies Office: Applied Battery...

8

Vehicle Technologies Office: Battery Systems  

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

Battery Systems A hybrid vehicle uses two or more forms of energy to propel the vehicle. Many hybrid electric vehicles (HEV) sold today are referred to as "hybrids" because it...

9

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

Page 1 of 6 VEHICLE DETAILS AND BATTERY SPECIFICATIONS 1 Vehicle Details Base Vehicle: 2013 Chevrolet Volt VIN: 1G1RA6E40DU103929 Propulsion System: Multi-Mode PHEV (EV, Series,...

10

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

Page 1 VEHICLE DETAILS AND BATTERY SPECIFICATIONS 1 Vehicle Details Base Vehicle: 2011 Chevrolet Volt VIN: 1G1RD6E48BU100815 Propulsion System: Multi-Mode PHEV (EV, Series, and...

11

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

voltage limits (see Note 2) at 50% depth of discharge (DOD). 2013 Chevrolet Malibu ECO Hybrid - VIN 3800 Advanced Vehicle Testing - Beginning-of-Test Battery Testing Results...

12

VEHICLE DETAILS AND BATTERY SPECIFICATIONS  

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

voltage limits (see Note 2) at 50% depth of discharge (DOD). 2013 Chevrolet Malibu ECO Hybrid - VIN 7249 Advanced Vehicle Testing - Beginning-of-Test Battery Testing Results...

13

Vehicle battery polarity indicator  

SciTech Connect

Battery jumper cables provide an effective means to connect a charged battery to a discharged battery. However, the electrodes of the batteries must be properly connected for charging to occur and to avoid damage to the batteries. A battery polarity indicator is interposed between a set of battery jumper cables to provide a visual/aural indication of relative battery polarity as well as a safety circuit to prevent electrical connection where polarities are reversed.

Cole, L.

1980-08-12T23:59:59.000Z

14

Advanced batteries for electric vehicles  

SciTech Connect

The idea of battery-powered vehicles is an old one that took on new importance during the oil crisis of 1973 and after California passed laws requiring vehicles that would produce no emissions (so-called zero-emission vehicles). In this overview of battery technologies, the authors review the major existing or near-term systems as well as advanced systems being developed for electric vehicle (EV) applications. However, this overview does not cover all the advanced batteries being developed currently throughout the world. Comparative characteristics for the following batteries are given: lead-acid; nickel/cadmium; nickel/iron; nickel/metal hydride; zinc/bromine; sodium/sulfur; sodium/nickel chloride; zinc/air; lithium/iron sulfide; and lithium-polymer.

Henriksen, G.L.; DeLuca, W.H.; Vissers, D.R. (Argonne National Lab., IL (United States))

1994-11-01T23:59:59.000Z

15

Batteries for Electric Drive Vehicles - Status 2005  

Science Conference Proceedings (OSTI)

Commercial availability of advanced battery systems that meet the cost, performance, and durability requirements of electric drive vehicles (EDVs) is a crucial challenge to the growth of markets for these vehicles. Hybrid electric vehicles (HEVs) are a subset of the family of EDVs, which include battery electric vehicles (BEVs), power assist hybrid electric vehicles, plug-in hybrid electric vehicles (PHEVs), and fuel cell vehicles. This study evaluates the state of advanced battery technology, presents u...

2005-11-29T23:59:59.000Z

16

Vehicle Battery Safety Roadmap Guidance  

SciTech Connect

The safety of electrified vehicles with high capacity energy storage devices creates challenges that must be met to assure commercial acceptance of EVs and HEVs. High performance vehicular traction energy storage systems must be intrinsically tolerant of abusive conditions: overcharge, short circuit, crush, fire exposure, overdischarge, and mechanical shock and vibration. Fail-safe responses to these conditions must be designed into the system, at the materials and the system level, through selection of materials and safety devices that will further reduce the probability of single cell failure and preclude propagation of failure to adjacent cells. One of the most important objectives of DOE's Office of Vehicle Technologies is to support the development of lithium ion batteries that are safe and abuse tolerant in electric drive vehicles. This Roadmap analyzes battery safety and failure modes of state-of-the-art cells and batteries and makes recommendations on future investments that would further DOE's mission.

Doughty, D. H.

2012-10-01T23:59:59.000Z

17

Microsoft Word - Vehicle Battery EA_BASF  

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

lithium-ion battery industry and, more specifically, the electric drive vehicle (EDV) and hybrid-electric vehicle industry (HEV). If approved, DOE would provide approximately 50...

18

Vehicle Battery Basics | Department of Energy  

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

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...

19

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

DOE Patents (OSTI)

A battery control system for hybrid vehicle includes a hybrid powertrain battery, a vehicle accessory battery, and a prime mover driven generator adapted to charge the vehicle accessory battery. A detecting arrangement is configured to monitor the vehicle accessory battery's state of charge. A controller is configured to activate the prime mover to drive the generator and recharge the vehicle accessory battery in response to the vehicle accessory battery's state of charge falling below a first predetermined level, or transfer electrical power from the hybrid powertrain battery to the vehicle accessory battery in response to the vehicle accessory battery's state of charge falling below a second predetermined level. The invention further includes a method for controlling a hybrid vehicle powertrain system.

Bockelmann, Thomas R. (Battle Creek, MI); Hope, Mark E. (Marshall, MI); Zou, Zhanjiang (Battle Creek, MI); Kang, Xiaosong (Battle Creek, MI)

2009-02-10T23:59:59.000Z

20

VEHICLE AND BATTERY DESCRIPTIONS AND SPECIFICATIONS Vehicle Details  

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

Page 1 VEHICLE AND BATTERY DESCRIPTIONS AND SPECIFICATIONS Vehicle Details Base Vehicle: 2011 Honda CR-Z VIN: JHMZF1C67BS004466 Electric Machine 1 : 10 kW (peak), permanent magnet...

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

VEHICLE AND BATTERY DESCRIPTIONS AND SPECIFICATIONS Vehicle Details  

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

Page 1 VEHICLE AND BATTERY DESCRIPTIONS AND SPECIFICATIONS Vehicle Details Base Vehicle: 2011 Honda CR-Z VIN: JHMZF1C64BS002982 Electric Machine 1 : 10 kW (peak), permanent magnet...

22

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

23

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

24

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

25

Ultracapacitors and Batteries in Hybrid Vehicles  

DOE Green Energy (OSTI)

Using an ultracapacitor in conjunction with a battery in a hybrid vehicle combines the power performance of the former with the greater energy storage capability of the latter.

Pesaran, A.; Markel, T.; Zolot, M.; Sprik, S.

2005-08-01T23:59:59.000Z

26

US advanced battery consortium in-vehicle battery testing procedure  

DOE Green Energy (OSTI)

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

27

Vehicle Specifications Battery Type: Li-Ion  

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

1 All-Electric Conversion of the USPS Long Life Vehicle (LLV) Vehicle Specifications Battery Type: Li-Ion Pack Locations: Underbody (inboard of frame rails) Nominal System Voltage:...

28

Hybrid Electric Vehicles - HEV Batteries  

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

and component levels. A very detailed battery design model is used to establish these costs for different Li-Ion battery chemistries. The battery design model considers the...

29

An Economic Analysis of Used Electric Vehicle Batteries Integrated...  

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

Analysis of Used Electric Vehicle Batteries Integrated into Commercial Building Microgrids Title An Economic Analysis of Used Electric Vehicle Batteries Integrated into...

30

U.S.-China Electric Vehicle and Battery Technology Workshop ...  

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

Administration Other Agencies You are here Home U.S.-China Electric Vehicle and Battery Technology Workshop U.S.-China Electric Vehicle and Battery Technology Workshop...

31

Battery Technology for Hybrid Vehicles Marshall Miller  

E-Print Network (OSTI)

Battery Technology for Hybrid Vehicles Marshall Miller May 13, 2008 H2 #12;Energy Storage Lithium-ion Batteries Battery manufact. Electrode chemistry Voltage range Ah Resist. mOhm Wh/kg W/kg 95 hydride 7.2-5.4 6.5 11.4 46 208 1.04 1.8 #12;Comparisons of Lithium Battery Chemistries Technology type

California at Davis, University of

32

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

33

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

34

Battery driven vehicle and recharging system  

SciTech Connect

A battery-driven car which has an electrical system including a minimum number of electric storage batteries as the power source, a high-voltage converter with a high-voltage capacitor bank for driving a direct current impulse motor combined with a generator for supplying current to motor/generator sets respectively integrated with the wheels of the vehicle to drive the same or for recharging the batteries in accordance with a microprocessor control system, the wheel-actuated generators providing recharging current for the batteries whenever the motor component is not being energized and in addition, said electrical system also including an air-driven turbine generator component for recharging the batteries when the vehicle reaches a predetermined speed in accordance with the microprocessor controls.

Arbisi, D. S.

1985-02-12T23:59:59.000Z

35

Energy and Materials Issues That Affect Electric Vehicle Batteries  

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

leaching processes on the spent battery (without smelting). Argonne has published several papers on Ni-MH batteries. Energy and Materials Issues That Affect Electric Vehicle...

36

NREL Evaluates Secondary Uses for Lithium Ion Vehicle Batteries  

NREL Evaluates Secondary Uses for Lithium Ion Vehicle Batteries ... of PHEVs and EVs is limited by the current high cost of Li-ion batteries.

37

Design of Electric Drive Vehicle Batteries for Long Life and...  

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

Kandler Smith, NREL EDV Battery Robust Design - 1 Design of Electric Drive Vehicle Batteries for Long Life and Low Cost Robustness to Geographic and Consumer-Usage Variation...

38

Battery management system for Li-Ion batteries in hybrid electric vehicles.  

E-Print Network (OSTI)

??The Battery Management System (BMS) is the component responsible for the effcient and safe usage of a Hybrid Electric Vehicle (HEV) battery pack. Its main… (more)

Marangoni, Giacomo

2010-01-01T23:59:59.000Z

39

Battery charging control methods, electric vehicle charging methods, battery charging apparatuses and rechargeable battery systems  

DOE Patents (OSTI)

Battery charging control methods, electric vehicle charging methods, battery charging apparatuses and rechargeable battery systems. According to one aspect, a battery charging control method includes accessing information regarding a presence of at least one of a surplus and a deficiency of electrical energy upon an electrical power distribution system at a plurality of different moments in time, and using the information, controlling an adjustment of an amount of the electrical energy provided from the electrical power distribution system to a rechargeable battery to charge the rechargeable battery.

Tuffner, Francis K. (Richland, WA); Kintner-Meyer, Michael C. W. (Richland, WA); Hammerstrom, Donald J. (West Richland, WA); Pratt, Richard M. (Richland, WA)

2012-05-22T23:59:59.000Z

40

Management of electric vehicle battery charging in distribution networks.  

E-Print Network (OSTI)

??This thesis investigated the management of electric vehicle battery charging in distribution networks. Different electric vehicle fleet sizes and network locations were considered. The energy… (more)

Grau, Iñaki

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.


41

Thermal control of electric vehicle batteries  

DOE Green Energy (OSTI)

The need to operate electric vehicles in warm, summer conditions and also provide for long periods of standby in cold climates is a challenging problem for any battery system. All advanced batteries of high specific energy require active cooling systems because adiabatic heating will raise the temperature to a level that is deleterious to cycle life. This cooling requires efficient paths for escape of heat to cooled surfaces; cooling the exterior of modules is insufficient. If a battery is heated by its own energy, and insulated to withstand exposure to a cold climate, only vacuum insulation will afford an appreciable reduction (>10{degrees}C) in the ambient temperature that can be tolerated. Standard insulations are of little use for this purpose because the heat loss rate causes too high a drain on the battery energy even for near-ambient temperature batteries.

Nelson, P.A.; Battaglia, V.S.; Henriksen, G.L.

1995-07-01T23:59:59.000Z

42

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

43

ESS 2012 Peer Review - Secondary Use of Vehicle Batteries in...  

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

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...

44

Learning policies for battery usage optimization in electric vehicles  

Science Conference Proceedings (OSTI)

The high cost, limited capacity, and long recharge time of batteries pose a number of obstacles for the widespread adoption of electric vehicles. Multi-battery systems that combine a standard battery with supercapacitors are currently one of the most ...

Stefano Ermon; Yexiang Xue; Carla Gomes; Bart Selman

2012-09-01T23:59:59.000Z

45

Thermal Batteries for Electric Vehicles  

Science Conference Proceedings (OSTI)

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

46

Near-term batteries for electric vehicles  

SciTech Connect

Major progress has been achieved in the lead-acid , nickel/iron and nickel/zinc battery technology development since the initiation of the Near-Term eV Battery Project in 1978. Against the specific energy goal of 56 wh/kg the demonstrated specific energies are 41 wh/kg for the improved lead-acid batteries, 48 wh/kg for the improved nickel/iron batteries, and 68 wh/kg for the improved nickel/zinc batteries. These specific energy values would allow an ETV-1 vehicle to have an urban range of 80 miles in the case of the improved lead-acid batteries, 96 miles for the improved nickel/zinc batteries, and 138 miles for the improved lead-acid batteries. All represent a significant improvement over the state-of-the-art lead-acid battery capability of about 30 wh/kg with approximately a 51 mile urban range for the ETV-1 vehicle. The project goal for specific power of 104 w/kg for 30 seconds at a 50% depth of discharge has been achieved for all of the technologies with the improved lead-acid demonstrating 111 w/kg, the improved nickel/iron demonstrating 103 w/kg, and the improved nickel/zinc demonstrating 131 w/kg. Again this is a significant improvement over the state-of-the-art lead-acid battery capability of 70 w/kg. Substantial progress has been made against the life cycle goal of 800 cycles as evidenced by the demonstrated lead-acid battery achievement of > 295 cycles in ongoing tests, the nickel/iron demonstrated capability of > 515 cycles in ongoing tests, and the nickel/zinc demonstrated capability of 179 cycles. Except for the nickel/zinc batteries, the demonstrated cycle life is better than the state-of-the-art lead-acid battery cycle life of about 250 cycles. Future program emphases will be on improving cycle life and further reductions in cost.

Christianson, C.C.; Yao, N.P.; Hornstra, F.

1981-01-01T23:59:59.000Z

47

Advanced Battery Testing for Plug-in Hybrid Electric Vehicles  

Science Conference Proceedings (OSTI)

The Sprinter van is a Plug-in Hybrid-Electric Vehicle (PHEV) developed by EPRI and Daimler for use in delivering cargo, carrying passengers, or fulfilling a variety of specialty applications. This report provides details of testing conducted on two different types of batteries used in these vehicles: VARTA nickel-metal hydride batteries and SAFT lithium ion batteries. Testing focused on long-term battery durability, using a test profile developed to simulate the battery duty cycle of a PHEV Sprinter

2008-12-18T23:59:59.000Z

48

Failure modes in high-power lithium-ion batteries for use in hybrid electric vehicles  

E-Print Network (OSTI)

BATTERIES FOR USE IN HYBRID ELECTRIC VEHICLES R. Kostecki,ion batteries for hybrid electric vehicles. Nine 18650-sizebatteries for hybrid electric vehicle (HEV) applications.

2001-01-01T23:59:59.000Z

49

A DC CIRCUIT BREAKER FOR AN ELECTRIC VEHICLE BATTERY PACK  

E-Print Network (OSTI)

A DC CIRCUIT BREAKER FOR AN ELECTRIC VEHICLE BATTERY PACK Geoff Walker Dept of Computer Science vehicle battery packs require DC circuit breakers for safety. These must break thousands of Amps DC at hundreds of Volts. The Sunshark solar racing car has a 140V 17Ahr battery box which needs such a breaker

Walker, Geoff

50

Recycling of Advanced Batteries for Electric Vehicles  

DOE Green Energy (OSTI)

The pace of development and fielding of electric vehicles is briefly described and the principal advanced battery chemistries expected to be used in the EV application are identified as Ni/MH in the near term and Li-ion/Li-polymer in the intermediate to long term. The status of recycling process development is reviewed for each of the two chemistries and future research needs are discussed.

JUNGST,RUDOLPH G.

1999-10-06T23:59:59.000Z

51

Plug-In Electric Vehicle Lithium-Ion Battery Cost and Advanced Battery Technologies Forecasts  

Science Conference Proceedings (OSTI)

Batteries are a critical cost factor for plug-in electric vehicles, and the current high cost of lithium ion batteries poses a serious challenge for the competitiveness of Plug-In Electric Vehicles (PEVs). Because the market penetration of PEVs will depend heavily on future battery costs, determining the direction of battery costs is very important. This report examines the cost drivers for lithium-ion PEV batteries and also presents an assessment of recent advancements in the growing attempts to ...

2012-12-12T23:59:59.000Z

52

Battery Electric Vehicle Driving and Charging Behavior Observed...  

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

Battery Electric Vehicle Driving and Charging Behavior Observed Early in The EV Project The EV Project John Smart, Idaho National Laboratory Stephen Schey, ECOtality North America...

53

An Ultracapacitor - Battery Energy Storage System for Hybrid Electric Vehicles.  

E-Print Network (OSTI)

??The nickel metal hydride (NiMH) batteries used in most hybrid electric vehicles (HEVs) provide satisfactory performance but are quite expensive. In spite of their lower… (more)

Stienecker, Adam W

2005-01-01T23:59:59.000Z

54

Optimal charging scheduling for battery electric vehicles under smart grid.  

E-Print Network (OSTI)

??M.S. A projected high penetration of battery electric vehicles (BEV s) in the market will introduce an additional load in the electricity grid. Furthermore, uncontrolled… (more)

Abd Rahman, Nur Dayana

2011-01-01T23:59:59.000Z

55

Electric Vehicle Battery Thermal Issues and Thermal Management Techniques (Presentation)  

SciTech Connect

This presentation examines the issues concerning thermal management in electric drive vehicles and management techniques for improving the life of a Li-ion battery in an EDV.

Rugh, J. P.; Pesaran, A.; Smith, K.

2013-07-01T23:59:59.000Z

56

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

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

You are here Home EA-1851: Delphi Automotive Systems Electric Drive Vehicle Battery and Component Manufacturing Initiative EA-1851: Delphi Automotive Systems Electric...

57

EA-1722: Toxco, Inc. Electric Drive Vehicle Battery and Component...  

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

Other Agencies You are here Home EA-1722: Toxco, Inc. Electric Drive Vehicle Battery and Component Manufacturing Initiative, Lancaster, OH EA-1722: Toxco, Inc. Electric...

58

Plug-in hybrid electric vehicles: battery degradation, grid support, emissions, and battery size tradeoffs  

E-Print Network (OSTI)

with 85% ethanol EIA ­ Energy Information Administration EVSE ­ Electric vehicle supply equipment gPlug-in hybrid electric vehicles: battery degradation, grid support, emissions, and battery size to get this thesis finished. #12;iv Intentionally blank #12;v Abstract Plug-in hybrid electric vehicles

59

2007 Nissan Altima-7982 Hybrid Electric Vehicle Battery Test Results  

DOE Green Energy (OSTI)

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Nissan Altima hybrid electric vehicle (Vin Number 1N4CL21E27C177982). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Grey; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

60

2007 Toyota Camry-7129 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Camry hybrid electric vehicle (Vin Number JTNBB46K773007129). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

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.


61

2006 Toyota Highlander-6395 Hyrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Highlander hybrid electric vehicle (Vin Number JTEDW21A160006395). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

62

2006 Toyota Highlander-5681 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Highlander hybrid electric vehicle (Vin Number JTEDW21A860005681). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

63

2006 Toyota Highlander-5681 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Highlander hybrid electric vehicle (Vin Number JTEDW21A860005681). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

64

2006 Toyota Highlander-6395 Hyrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Highlander hybrid electric vehicle (Vin Number JTEDW21A160006395). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

65

2007 Nissan Altima-7982 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Nissan Altima hybrid electric vehicle (Vin Number 1N4CL21E27C177982). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Grey; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

66

2007 Toyota Camry-7129 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Camry hybrid electric vehicle (Vin Number JTNBB46K773007129). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

67

Comparison of advanced battery technologies for electric vehicles  

DOE Green Energy (OSTI)

Battery technologies of different chemistries, manufacture and geometry were evaluated as candidates for use in Electric Vehicles (EV). The candidate batteries that were evaluated include four single cell and seven multi-cell modules representing 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 battery types were used in the evaluations. The batteries were evaluated by conducting performance tests, and by subjecting them to cyclical loading, using a computer controlled charge--discharge cycler, to simulate typical EV driving cycles. Criteria for comparison of batteries were: performance, projected vehicle range, cost, and applicability to various types of EVs. The four battery technologies have individual strengths and weaknesses and each is suited to fill a particular application. None of the batteries tested can fill every EV application.

Dickinson, B.E.; Lalk, T.R. [Texas A and M Univ., College Station, TX (United States). Mechanical Engineering Dept.; Swan, D.H. [Univ. of California, Davis, CA (United States). Inst. of Transportation Studies

1993-12-31T23:59:59.000Z

68

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,

69

Comparison of various battery technologies for electric vehicles  

E-Print Network (OSTI)

Battery technologies of different chemistries, manufacture and geometry were evaluated as candidates for use in Electric Vehicles (EV). The candidate batteries that were evaluated include four single cell and seven multi-cell modules representing 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 battery types were used in the evaluations. The batteries were evaluated by conducting performance tests, and by subjecting them to cyclical loading, using a computer controlled charge - discharge cycler, to simulate typical EV driving cycles. Criteria for comparison of batteries were: performance, projected vehicle range, cost, and applicability to various types of EVs. The four battery technologies have individual strengths and weaknesses and each is suited to fill a particular application. None of the batteries tested can fill every EV application.

Dickinson, Blake Edward

1993-01-01T23:59:59.000Z

70

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

71

Assessment of battery technologies for electric vehicles  

SciTech Connect

This document, Part 2 of Volume 2, provides appendices to this report and includes the following technologies, zinc/air battery; lithium/molybdenum disulfide battery; sodium/sulfur battery; nickel/cadmium battery; nickel/iron battery; iron/oxygen battery and iron/air battery. (FI)

Ratner, E.Z. (Sheladia Associates, Inc., Rockville, MD (USA)); Henriksen, G.L. (ed.) (EG and G Idaho, Inc., Idaho Falls, ID (USA))

1990-02-01T23:59:59.000Z

72

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

73

Potential use of battery packs from NCAP tested vehicles.  

Science Conference Proceedings (OSTI)

Several large electric vehicle batteries available to the National Highway Traffic Safety Administration are candidates for use in future safety testing programs. The batteries, from vehicles subjected to NCAP crashworthiness testing, are considered potentially damaged due to the nature of testing their associated vehicles have been subjected to. Criteria for safe shipping to Sandia is discussed, as well as condition the batteries must be in to perform testing work. Also discussed are potential tests that could be performed under a variety of conditions. The ultimate value of potential testing performed on these cells will rest on the level of access available to the battery pack, i.e. external access only, access to the on board monitoring system/CAN port or internal electrical access to the battery. Greater access to the battery than external visual and temperature monitoring would likely require input from the battery manufacturer.

Lamb, Joshua; Orendorff, Christopher J.

2013-10-01T23:59:59.000Z

74

2011 Hyundai Sonata 4932 - Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV 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 HEV (VIN KMHEC4A43BA004932). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the AVTA for the Vehicle Technologies Program of the DOE.

Tyler Gray; Matthew Shirk; Jeffrey Wishart

2013-07-01T23:59:59.000Z

75

2010 Honda Civic Hybrid UltraBattery Conversion 5577 - Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV batteries when both the vehicles and batteries are new and at the conclusion of on-road fleet testing. This report documents battery testing performed for the 2010 Honda Civic HEV UltraBattery Conversion (VIN JHMFA3F24AS005577). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the AVTA for the Vehicle Technologies Program of the DOE.

Tyler Gray; Matthew Shirk; Jeffrey Wishart

2013-07-01T23:59:59.000Z

76

2007 Toyota Camry-6330 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity (AVTA) conducts several different types of tests on hybrid electric vehicles (HEVs), including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Camry hybrid electric vehicle (Vin Number JTNBB46K673006330). Testing was performed by the Electric Transportation Engineering Corporation. The AVTA is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct AVTA for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

77

2007 Toyota Camry-6330 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity (AVTA) conducts several different types of tests on hybrid electric vehicles (HEVs), including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Toyota Camry hybrid electric vehicle (Vin Number JTNBB46K673006330). Testing was performed by the Electric Transportation Engineering Corporation. The AVTA is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct AVTA for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

78

Recycling readiness of advanced batteries for electric vehicles  

SciTech Connect

Maximizing the reclamation/recycle of electric-vehicle (EV) batteries is considered to be essential for the successful commercialization of this technology. Since the early 1990s, the US Department of Energy has sponsored the ad hoc advanced battery readiness working group to review this and other possible barriers to the widespread use of EVs, such as battery shipping and in-vehicle safety. Regulation is currently the main force for growth in EV numbers and projections for the states that have zero-emission vehicle (ZEV) programs indicate about 200,000 of these vehicles would be offered to the public in 2003 to meet those requirements. The ad hoc Advanced Battery Readiness Working Group has identified a matrix of battery technologies that could see use in EVs and has been tracking the state of readiness of recycling processes for each of them. Lead-acid, nickel/metal hydride, and lithium-ion are the three EV battery technologies proposed by the major automotive manufacturers affected by ZEV requirements. Recycling approaches for the two advanced battery systems on this list are partly defined, but could be modified to recover more value from end-of-life batteries. The processes being used or planned to treat these batteries are reviewed, as well as those being considered for other longer-term technologies in the battery recycling readiness matrix. Development efforts needed to prepare for recycling the batteries from a much larger EV population than exists today are identified.

Jungst, R.G.

1997-09-01T23:59:59.000Z

79

Battery availability for near-term (1998) electric vehicles  

SciTech Connect

Battery Requirements were determined for a wide spectrum of electric vehicles ranging from 2-passenger sports cars and microvans to full-size vans with a payload of 500 kg. All the vehicles utilize ac, high voltage (340--360 V) powertrains and have acceleration performance (0--80 km/h in less than 15 seconds) expected to be the norm in 1988 electric vehicles. Battery packs were configured for each of the vehicles using families of sealed lead-acid and nickel-cadmium modules which are either presently available in limited quantities or are being developed by battery companies which market a similar battery technology. It was found that the battery families available encompass the Ah cell sizes required for the various vehicles and that they could be packaged in the space available in each vehicle. The acceleration performance and range of the vehicles were calculated using the SIMPLEV simulation program. The results showed that all the vehicles had the required acceleration characteristics and ranges between 80--160 km (50--100 miles) with the ranges using nickel-cadmium batteries being 40--60% greater than those using lead-acid batteries. Significant changes in the design of electric vehicles over the last fifteen years are noted. These changes make the design of the batteries more difficult by increasing the peak power density required from about 60 W/kg to 100--150 W/kg and by reducing the Ah cell size needed from about 150 Ah to 30--70 Ah. Both of these changes in battery specifications increase the difficulty of achieving low $/kWh cost and long cycle life. This true for both lead-acid and nickel-cadmium batteries. 25 refs., 6 figs., 16 tabs.

Burke, A.F.

1991-06-01T23:59:59.000Z

80

Costs of lithium-ion batteries for vehicles  

DOE Green Energy (OSTI)

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

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

2007 Nissan Altima-2351 Hybrid Electric Vehicle Battery Test Results  

DOE Green Energy (OSTI)

The U.S. Department of Energy's (DOE) Advanced Vehicle Testing Activity (AVTA) conducts several different types of tests on hybrid electric vehicles (HEVs), including testing the HEV batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of on-road accelerated testing. This report documents the battery testing performed and the battery testing results for the 2007 Nissan Altima HEV, number 2351 (VIN 1N4CL21E87C172351). The battery testing was performed by the Electric Transportation Engineering Corporation (eTec). The Idaho National Laboratory and eTec conduct the AVTA for DOE’s Vehicle Technologies Program.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

82

2007 Nissan Altima-2351 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's (DOE) Advanced Vehicle Testing Activity (AVTA) conducts several different types of tests on hybrid electric vehicles (HEVs), including testing the HEV batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of on-road accelerated testing. This report documents the battery testing performed and the battery testing results for the 2007 Nissan Altima HEV, number 2351 (VIN 1N4CL21E87C172351). The battery testing was performed by the Electric Transportation Engineering Corporation (eTec). The Idaho National Laboratory and eTec conduct the AVTA for DOE’s Vehicle Technologies Program.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

83

Zinc air battery development for electric vehicles  

DOE Green Energy (OSTI)

This report summarizes the results of research conducted during the sixteen month continuation of a program to develop rechargeable zinc-air batteries for electric vehicles. The zinc-air technology under development incorporates a metal foam substrate for the zinc electrode, with flow of electrolyte through the foam during battery operation. In this soluble'' zinc electrode the zincate discharge product dissolves completely in the electrolyte stream. Cycle testing at Lawrence Berkeley Laboratory, where the electrode was invented, and at MATSI showed that this approach avoids the zinc electrode shape change phenomenon. Further, electrolyte flow has been shown to be necessary to achieve significant cycle life (> 25 cycles) in this open system. Without it, water loss through the oxygen electrode results in high-resistance failure of the cell. The Phase I program, which focused entirely on the zinc electrode, elucidated the conditions necessary to increase electrode capacity from 75 to as much as 300 mAh/cm{sup 2}. By the end of the Phase I program over 500 cycles had accrued on one of the zinc-zinc half cells undergoing continuous cycle testing. The Phase II program continued the half cell cycle testing and separator development, further refined the foam preplate process, and launched into performance and cycle life testing of zinc-air cells.

Putt, R.A.; Merry, G.W. (MATSI, Inc., Atlanta, GA (United States))

1991-07-01T23:59:59.000Z

84

Hybrid energy storage systems and battery management for electric vehicles  

Science Conference Proceedings (OSTI)

Electric vehicles (EV) are considered as a strong alternative of internal combustion engine vehicles expecting lower carbon emission. However, their actual benefits are not yet clearly verified while the energy efficiency can be improved in many ways. ... Keywords: battery-supercapacitor hybrid, charging/discharging asymmetry, electric vehicle, regenerative braking

Sangyoung Park, Younghyun Kim, Naehyuck Chang

2013-05-01T23:59:59.000Z

85

Battery modeling for electric vehicle applications using neural networks  

SciTech Connect

Neural networking is a new approach to modeling batteries for electric vehicle applications. This modeling technique is much less complex then a first principles model but can consider more parameters then classic empirical modeling. Test data indicates that individual cell size and geometry and operating conditions affect a battery performance (energy density, power density and life). Given sufficient battery data, system parameters and operating conditions a neural network model could be used to interpolate and perhaps even extrapolate battery performance under wide variety of operating conditions. As a result the method could be a valuable design tool for electric vehicle battery design and application. This paper describes the on going modeling method at Texas A and M University and presents preliminary results of a tubular lead acid battery model. The ultimate goal of this modeling effort is to develop the values necessary to be able to predict performance for batteries as wide ranging as sodium sulfur to zinc bromine.

Swan, D.H.; Arikara, M.P.; Patton, A.D.

1993-12-31T23:59:59.000Z

86

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

87

Vehicle Technologies Office: Applied Battery Research  

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

Applied Battery Research Applied battery research addresses the barriers facing the lithium-ion systems that are closest to meeting the technical energy and power requirements for...

88

Progress and forecast in electric-vehicle batteries  

SciTech Connect

With impetus provided by US Public Law 94-413 (Electric and Hybrid Vehicle Research, Development, and Demonstration Act of 1976), the Department of Energy (DOE) launched a major battery development program early in 1978 for near-term electric vehicles. The program's overall objective is to develop commercially viable batteries for commuter vehicles (with an urban driving range of 100 miles) and for vans and trucks (with a range of 50 miles) by the mid-1980's. Three near-term battery candidates are receiving major developmental emphasis - improved lead-acid, nickel/iron and nickel/zinc systems. Sharing the cost with the government, nine industrial firms (battery developers) are participating in the DOE battery project. They are Eltra Corp., Exide Management and Technology Co., and Globe-Union Inc., for the lead-acid battery; Eagle-Picher Industries, Inc., and Westinghouse Electric Corp. for the nickel/iron battery; and Energy Research Corp., Exide Management and Technology Co., and Gould Inc., for the nickel/zinc battery. Good progress has been made in improving the specific energy, specific power, and manufacturing processes of these three battery technologies. Current emphasis is directed toward reduction of manufacturing cost and enhancement of battery cycle life and reliability. Recently, the zinc-chloride battery was added as the fourth candidate to the near-term battery list. Testing of the zinc-chloride battery in a vehicle and evaluation of its operating characteristics are currently under way. This paper presents the development goals, the status, and the outlook for the near-term battery program.

Webster, W.H. Jr.; Yao, N.P.

1980-01-01T23:59:59.000Z

89

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

DOE Green Energy (OSTI)

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

Pesaran, A. A.

2011-05-01T23:59:59.000Z

90

Advanced Batteries for Electric-Drive Vehicles: A Technology and Cost-Effectiveness Assessment for Battery Electric Vehicles, Power Assist Hybrid Electric Vehicles, and Plug-In Hybrid Electric Vehicles  

Science Conference Proceedings (OSTI)

Availability of affordable advanced battery technology is a crucial challenge to the growth of the electric-drive vehicle (EDV) market. This study assesses the state of advanced battery technology for EDVs, which include battery electric vehicles (BEVs), power assist hybrid electric vehicles (HEV 0s -- hybrids without electric driving range), plug-in hybrid electric vehicles (PHEVs), and fuel cell vehicles. The first part of this study presents assessments of current battery performance and cycle life ca...

2004-05-31T23:59:59.000Z

91

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

supervises testing in the Hybrid Vehicle Propulsion SystemsChemistries for Plug-in Hybrid Vehicles Andrew Burke,batteries, plug-in hybrid vehicles, energy density, pulse

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

92

Impact of increased electric vehicle use on battery recycling infrastructure  

DOE Green Energy (OSTI)

State and Federal regulations have been implemented that are intended to encourage more widespread use of low-emission vehicles. These regulations include requirements of the California Air Resources Board (CARB) and regulations pursuant to the Clean Air Act Amendments of 1990 and the Energy Policy Act. If the market share of electric vehicles increases in response to these initiatives, corresponding growth will occur in quantities of spent electric vehicle batteries for disposal. Electric vehicle battery recycling infrastructure must be adequate to support collection, transportation, recovery, and disposal stages of waste battery handling. For some battery types, such as lead-acid, a recycling infrastructure is well established; for others, little exists. This paper examines implications of increasing electric vehicle use for lead recovery infrastructure. Secondary lead recovery facilities can be expected to have adequate capacity to accommodate lead-acid electric vehicle battery recycling. However, they face stringent environmental constraints that may curtail capacity use or new capacity installation. Advanced technologies help address these environmental constraints. For example, this paper describes using backup power to avoid air emissions that could occur if electric utility power outages disable emissions control equipment. This approach has been implemented by GNB Technologies, a major manufacturer and recycler of lead-acid batteries. Secondary lead recovery facilities appear to have adequate capacity to accommodate lead waste from electric vehicles, but growth in that capacity could be constrained by environmental regulations. Advances in lead recovery technologies may alleviate possible environmental constraints on capacity growth.

Vimmerstedt, L.; Hammel, C. [National Renewable Energy Lab., Golden, CO (United States); Jungst, R. [Sandia National Labs., Albuquerque, NM (United States)

1996-12-01T23:59:59.000Z

93

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

94

Battery Test Manual For Plug-In Hybrid Electric Vehicles  

DOE Green Energy (OSTI)

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.

Not Available

2008-03-01T23:59:59.000Z

95

Battery Test Manual For Plug-In Hybrid Electric Vehicles  

DOE Green Energy (OSTI)

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

2010-09-01T23:59:59.000Z

96

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

97

The lithium-ion battery industry for electric vehicles  

E-Print Network (OSTI)

Electric vehicles have reemerged as a viable alternative means of transportation, driven by energy security concerns, pressures to mitigate climate change, and soaring energy demand. The battery component will play a key ...

Kassatly, Sherif (Sherif Nabil)

2010-01-01T23:59:59.000Z

98

An analysis of battery electric vehicle production projections  

E-Print Network (OSTI)

In mid 2008 and early 2009 Deutsche Bank and The Boston Consulting Group each released separate reports detailing projected Battery Electric Vehicle production through 2020. These reports both outlined scenarios in which ...

Cunningham, John Shamus

2009-01-01T23:59:59.000Z

99

Evaluation of Near-Term Electric Vehicle Battery Systems through In-Vehicle Testing  

Science Conference Proceedings (OSTI)

Electric vehicles (EVs) using today's technology are suitable for certain commercial fleets. Yet expanding the EV market largely depends on developing and marketing batteries with performance characteristics superior to those already commercially available. The in-vehicle test results summarized in this report provide valuable information on the performance, life, and maintenance of 10 new batteries under real-world operating conditions.

1986-12-01T23:59:59.000Z

100

High power battery test methods for hybrid vehicle applications  

DOE Green Energy (OSTI)

Commonly used EV battery tests are not very suitable for testing hybrid vehicle batteries, which may be primarily intended to supply vehicle acceleration power. The capacity of hybrid vehicle batteries will be relatively small, they will typically operate over a restricted range of states-of-charge, and they may seldom if ever be fully recharged. Further, hybrid propulsion system designs will commonly impose a higher regeneration content than is typical for electric vehicles. New test methods have been developed for use in characterizing battery performance and life for hybrid vehicle use. The procedures described in this paper were developed from the requirements of the government-industry cooperative Partnership for A New Generation of Vehicles (PNGV) program; however, they are expected to have broad application to the testing of energy storage devices for hybrid vehicles. The most important performance measure for a high power battery is its pulse power capability as a function of state-of-charge for both discharge and regeneration pulses. It is also important to characterize cycle life, although the {open_quote}cycles{close_quote} involved are quite different from the conventional full-discharge, full-recharge cycle commonly used for EV batteries, This paper illustrates in detail several test profiles which have been selected for PNGV battery testing, along with some sample results and lessons learned to date from the use of these test profiles. The relationship between the PNGV energy storage requirements and these tests is described so that application of the test methods can be made to other hybrid vehicle performance requirements as well. The resulting test procedures can be used to characterize the pulse power capability of high power energy storage devices including batteries and ultracapacitors, as well as the life expectancy of such devices, for either power assist or dual mode hybrid propulsion system designs.

Hunt, G.L.; Haskins, H.; Heinrich, B.; Sutula, R.

1997-11-01T23:59:59.000Z

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.


101

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

102

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.

103

The Potential of Plug-in Hybrid and Battery Electric Vehicles as Grid Resources: the Case of a Gas and Petroleum Oriented Elecricity Generation System  

E-Print Network (OSTI)

than the vehicle’s battery capacity will allow. Previousowner selling vehicle battery capacity into the market forusing an EDV’s battery and electronics capacity in segments

Greer, Mark R

2012-01-01T23:59:59.000Z

104

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

105

Overview of Sandia`s Electric Vehicle Battery Program  

DOE Green Energy (OSTI)

Sandia National Laboratories is actively involved several projects which are part of an overall Electric Vehicle Battery Program. Part of this effort is funded by the United States Department of Energy/Office of Transportation Technologies (DOE/OTT) and the remainder is funded through the United States Advanced Battery Consortium (USABC). DOE/OTT supported activities include research and development of zinc/air and sodium/sulfur battery technologies as well as double layer capacitor (DLC) R&D. Projects in the USABC funded work include lithium/polymer electrolyte (LPE) R&D, sodium/sulfur activities and battery test and evaluation.

Clark, R.P.

1993-12-31T23:59:59.000Z

106

Evaluation of near-term electric vehicle battery systems through in-vehicle testing: Interim report  

SciTech Connect

EVTF personnel tested 10 batteries, including lead-acid (flat plate and tubular design), Gel Cell III, advanced lead-acid, nickel iron, nickel zinc, nickel cadmium, and zinc chloride systems. The assessment encompassed the following tasks: initial acceptance testing of battery components and systems, daily in-vehicle operation of the batteries, monthly in-vehicle driving range tests, and periodic static discharge tests under computer control. Performance data were based on specific energy versus accumulated vehicle mileage and vehicle driving range over a fixed operating cycle at 35-mph constant speed and the SAE J227a C cycle. A battery's life cycle was terminated when its measured capacity dropped below 60% of the rating, at a 2-h rate, after 25% of the battery modules had been replaced. The EVs used for the tests were 10 Volkswagen vans and 2 General Motors Griffin vans.

Blickwedel, T.W.

1986-12-01T23:59:59.000Z

107

Sensitivity of Battery Electric Vehicle Economics to Drive Patterns, Vehicle Range, and Charge Strategies  

Science Conference Proceedings (OSTI)

Battery electric vehicles (BEVs) offer the potential to reduce both oil imports and greenhouse gas emissions, but high upfront costs discourage many potential purchasers. Making an economic comparison with conventional alternatives is complicated in part by strong sensitivity to drive patterns, vehicle range, and charge strategies that affect vehicle utilization and battery wear. Identifying justifiable battery replacement schedules and sufficiently accounting for the limited range of a BEV add further complexity to the issue. The National Renewable Energy Laboratory developed the Battery Ownership Model to address these and related questions. The Battery Ownership Model is applied here to examine the sensitivity of BEV economics to drive patterns, vehicle range, and charge strategies when a high-fidelity battery degradation model, financially justified battery replacement schedules, and two different means of accounting for a BEV's unachievable vehicle miles traveled (VMT) are employed. We find that the value of unachievable VMT with a BEV has a strong impact on the cost-optimal range, charge strategy, and battery replacement schedule; that the overall cost competitiveness of a BEV is highly sensitive to vehicle-specific drive patterns; and that common cross-sectional drive patterns do not provide consistent representation of the relative cost of a BEV.

Neubauer, J.; Brooker, A.; Wood, E.

2012-07-01T23:59:59.000Z

108

Battery Requirements for Plug-In Hybrid Electric Vehicles -- Analysis and Rationale  

DOE Green Energy (OSTI)

Presents analysis, discussions, and resulting requirements for plug-in hybrid electric vehicle batteries adopted by the US Advanced Battery Consortium.

Pesaran, A. A.; Markel, T.; Tataria, H. S.; Howell, D.

2009-07-01T23:59:59.000Z

109

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 and torque ripples. Keywords- Electric Vehicle, Plug-in Hybrid Vehicle, On-board Battery Charger, H on an original electric drive [1]-[3] dedicated to the vehicle traction and configurable as a battery charger

Paris-Sud XI, Université de

110

A smart control system for electric vehicle batteries  

SciTech Connect

A smart control system for electric vehicle (EV) batteries was designed and its performance was evaluated. The hardware for the system was based on the Motorola MC68HC11ENB micro controller. A zinc bromide (Zn/Br{sub 2}) battery was chosen since it is a good candidate as an EV battery and has a large number of user variable parameters that affect its performance. The flexibility of the system arises from the fact that the system can be programmed to do a wide variety of jobs. The use of real time interrupts and other features makes the system safe for use along with the battery systems. Test data indicates that real time control of the different parameters can increase the performance of the battery by 15%. In addition to optimizing the performance of the battery the control system incorporates essential safety features.

Arikara, M.P.; Dickinson, B.E.; Branum, B. [Texas A and M Univ., College Station, TX (United States). Texas Engineering Experiment Station

1993-12-31T23:59:59.000Z

111

Real-time prediction of battery power requirements for electric vehicles  

Science Conference Proceedings (OSTI)

A battery management system (BMS) is responsible for protecting the battery from damage, predicting battery life, and maintaining the battery in an operational condition. In this paper, we propose an efficient way of predicting the power requirements ... Keywords: acceleration prediction, battery management system (BMS), electric vehicles (EVs), prediction of battery power requirement

Eugene Kim, Jinkyu Lee, Kang G. Shin

2013-04-01T23:59:59.000Z

112

Application of the GSFUDS to advanced batteries and vehicles  

DOE Green Energy (OSTI)

The GSFUDS approach to determining appropriate battery test power profiles is applied to various combinations of advanced batteries and electric vehicles. Computer simulations are used to show that the SFUDS velocity driving profile developed for the IDSEP electric vehicle also yielded energy consumption (Wh/km) and peak power values for other vehicles of greatly different characteristics that are in good agreement with the corresponding values for the same vehicles on the FUDS driving cycle. The computer results also showed that the GSFUDS power steps expressed as multiples of the average power, Pav are applicable to electric vehicles in general for the SFUDS driving profile if the peak power step is altered to reflect the changes in the vehicle design. A general procedure is given for presenting battery test data in terms of the constant power and GSFUDS Ragone curves from which the vehicle range can be determined for the FUDS and other driving cycles for different vehicle designs. 5 refs., 6 figs., 6 tabs.

Burke, A.F.; Cole, G.H.

1990-01-01T23:59:59.000Z

113

Evaluation of electric vehicle battery systems through in-vehicle testing: Third annual report, April 1989  

SciTech Connect

This third annual summary report documents the performance from October 1986 through September 1987 of the Tennessee Valley Authority's ongoing project to evaluate near-term electric vehicle traction battery packs. Detailed test procedures and test data are available from EPRI in an informal data report. The purpose of this field test activity is to provide an impartial life evaluation and comparison of the performance of various battery systems in a real-world operating environment. Testing includes initial acceptance testing of battery components and systems, daily in-vehicle operation of the batteries, monthly in-vehicle driving range tests, and periodic static (constant current) discharge tests under computer control. This year's report gives the final results on a NiZn, NiCd, Gel Cell, and two lead-acid battery packs. Specific energy and monthly driving ranges (SAE J227a ''C'' cycle and 35 mi/h constant speed cycles) are maintained throughout battery life. Vehicle range test data is analyzed statistically and variable conditions are normalized for comparative purposes. Battery modules in the pack are replaced when their measured ampere-hour capacity at a fixed discharge rate drops to 60 percent of the manufacturer's rated value. The life of a test battery pack is terminated when 25 percent of the modules in the pack have been replaced or require replacement. 26 figs., 8 tabs.

Blickwedel, T.W.; Thomas, W.A.; Whitehead, G.D.

1989-04-01T23:59:59.000Z

114

Results of advanced battery technology evaluations for electric vehicle applications  

SciTech Connect

Advanced battery technology evaluations are performed under simulated electric-vehicle operating conditions at the Analysis & Diagnostic Laboratory (ADL) of Argonne National Laboratory. The ADL results provide insight Into those factors that limit battery performance and life. The ADL facilities include a test laboratory to conduct battery experimental evaluations under simulated application conditions and a post-test analysis laboratory to determine, In a protected atmosphere if needed, component compositional changes and failure mechanisms. This paper summarizes the performance characterizations and life evaluations conducted during 1991--1992 on both single cells and multi-cell modules that encompass eight battery technologies [Na/S, Li/MS (M=metal), Ni/MH, Ni/Cd, Ni/Zn, Ni/Fe, Zn/Br, and Pb-acid]. These evaluations were performed for the Department of Energy, Office of Transportation Technologies, Electric and Hybrid Propulsion Division, and the Electric Power Research Institute. The ADL provides a common basis for battery performance characterization and life evaluations with unbiased application of tests and analyses. The results help identify the most-promising R&D approaches for overcoming battery limitations, and provide battery users, developers, and program managers with a measure of the progress being made in battery R&D programs, a comparison of battery technologies, and basic data for modeling.

DeLuca, W.H.; Gillie, K.R.; Kulaga, J.E.; Smaga, J.A.; Tummillo, A.F.; Webster, C.E.

1992-09-01T23:59:59.000Z

115

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

E-Print Network (OSTI)

of advanced batteries for plug-in hybrid electric vehicle (Advanced Lithium-Ion Batteries for Plug- in Hybrid-Electric Vehicles,

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

2008-01-01T23:59:59.000Z

116

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

for vehicle applications. 2 Lithium-ion battery chemistriesThe lithium-ion battery technology used for consumerfrom EIG Figure 4: Lithium-ion battery modules for testing

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

117

Thermal Characteristic Analysis of Power Lithium-ion Battery System for Electric Vehicle  

Science Conference Proceedings (OSTI)

With the electric vehicles used lithium manganese lithium-ion power battery (LiMn2O4 power battery) as the research object, the paper researched on the parameter identification of battery cell, has built the finite element model of single cell and completed ... Keywords: Lithium-ion battery, Thermal characteristic analysis, Electric Vehicle

Wang Wenwei; Lin Cheng; Tang Peng; Zhou Chengjun

2012-07-01T23:59:59.000Z

118

Large-scale battery system modeling and analysis for emerging electric-drive vehicles  

Science Conference Proceedings (OSTI)

Emerging electric-drive vehicles demonstrate the potential for significant reduction of petroleum consumption and greenhouse gas emissions. Existing electric-drive vehicles typi- cally include a battery system consisting of thousands of Lithium-ion battery ... Keywords: analysis, battery system model, electric-drive vehicles

Kun Li; Jie Wu; Yifei Jiang; Zyad Hassan; Qin Lv; Li Shang; Dragan Maksimovic

2010-08-01T23:59:59.000Z

119

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

E-Print Network (OSTI)

of automobiles. The propulsion solutions for EVs are based on hybrid or fully battery powered electric vehiclesSwitching algorithms for extending battery life in Electric Vehicles Ron Adany a,*, Doron Aurbach b 27 December 2012 Keywords: Electric Vehicles (EV) Switching algorithms Battery life Lithium ion

Kraus, Sarit

120

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

E-Print Network (OSTI)

for Plug-in Hybrid Electric Vehicles (PHEVs): Goals andE. , Plug-in Hybrid-Electric Vehicle Powertrain Design andLithium Batteries for Plug-in Electric Vehicles Andrew Burke

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.


121

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

Battery, Hybrid and Fuel Cell Electric Vehicle Symposiumof a plug-in hybrid-electric vehicle is the selection of theHybrid and Fuel Cell Electric Vehicle Symposium negative)

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

122

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

E-Print Network (OSTI)

Chemistries for Plug-in Hybrid Vehicles, EVS-24, Stavanger,ion batteries in the Hybrid Vehicle Propulsion System Lab atIn the case of plug-in hybrid vehicles, there is much design

Burke, Andrew

2009-01-01T23:59:59.000Z

123

A zinc-air battery and flywheel zero emission vehicle  

DOE Green Energy (OSTI)

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

124

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

E-Print Network (OSTI)

and Batteries for Hybrid Vehicle Applications, 23 rdSimulations of Plug-in Hybrid Vehicles using Advancedultracapacitors in plug-in hybrid vehicles (PHEVs) with high

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

125

Non-isolated integrated motor drive and battery charger based on the split-phase PM motor for plug-in vehicles.  

E-Print Network (OSTI)

??In electric vehicles and plug-in hybrid electric vehicles, the utility grid charges the vehicle battery through a battery charger. Different solutions have been proposed to… (more)

Serrano Guillén, Isabel

2013-01-01T23:59:59.000Z

126

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 Lithium-ion batteries are a fast-growing technology that is attractive for use in portable electronics of lithium-ion batteries for hybrid electric vehicle (HEV) applications. The ATD Program is a joint effort

127

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

E-Print Network (OSTI)

Monitoring Battery System for Electric Vehicle, Based On "One Wire" Technology Javier Ibáñez Vial Santiago, Chile jdixon@ing.puc.cl Abstract-- A monitoring system for a battery powered electric vehicle (EV of the 24 batteries. Besides, the system will also allow monitoring the energy delivered by a photovoltaic

Rudnick, Hugh

128

Market Feasibility for Nickel Metal Hyride and Other Advanced Electric Vehicle Batteries in Selected Stationary Applications  

Science Conference Proceedings (OSTI)

Governments in the United States and other countries, as well as the automotive, battery, and utility industries, have spent millions to demonstrate the viability of next generation of batteries for electric vehicles (EVs) and hybrid electric vehicles (HEVs). An important question remains unanswered: "What value might these EV and HEV batteries add when employed in stationary and secondary use applications?"

2000-12-12T23:59:59.000Z

129

Development of advanced battery systems for vehicle applications  

SciTech Connect

The Advanced Battery Business Unit (ABBU) of Johnson Controls, Inc. is developing several promising advanced battery technologies including flow-through lead-acid, zinc/bromine, and nickel hydrogen. The flow-through lead-acid technology, which is being developed under Department of Energy (DOE) sponsorship, is progressing towards the fabrication of a 39 kWh battery system. Recent efforts have focused on achieving the aggressive specific energy goal of 56 Wh/kg in 12 volt module form. Recent DOE sponsored work in the zinc/bromine program has focused on the development of a proof-of concept 50 kWh electric vehicle system for a light van application. Efforts in the nickel hydrogen program have focused on reducing system cost in order to make the life-time premium market and EV market possible targets. The status and future direction of each of these programs are summarized.

Zagrodnik, J.P.; Eskra, M.D.; Andrew, M.G.; Gentry, W.O.

1989-01-01T23:59:59.000Z

130

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

E-Print Network (OSTI)

Battery Utilization in Electric Vehicles: Theoretical Analysis and an Almost Optimal Online Algorithm Ron Adany Tami Tamir Abstract We consider the problem of utilizing a pack of m batteries serving among the batteries in the pack. A battery's life depends on the discharge current used for supplying

Tamir, Tami

131

Factors Influencing the Diffusion of Battery Electric Vehicles in Urban Areas.  

E-Print Network (OSTI)

??Purchasing a battery electric vehicle is a type of pro-environmental behavior but the impact of such behavior on the environment becomes significant and beneficial only… (more)

Mashayekhi, Morteza

2013-01-01T23:59:59.000Z

132

Modeling, Simulation & Implementation of Li-ion Battery Powered Electric and Plug-in Hybrid Vehicles.  

E-Print Network (OSTI)

??The modeling, simulation and hardware implementation of a Li-ion battery powered electric vehicle are presented in this thesis. The results obtained from simulation and experiments… (more)

Mantravadi, Siva Rama Prasanna

2011-01-01T23:59:59.000Z

133

Commuter simulation of lithium-ion battery performance in hybrid electric vehicles.  

SciTech Connect

In this study, a lithium-ion battery was designed for a hybrid electric vehicle, and the design was tested by a computer program that simulates driving of a vehicle on test cycles. The results showed that the performance goals that have been set for such batteries by the Partnership for a New Generation of Vehicles are appropriate. The study also indicated, however, that the heat generation rate in the battery is high, and that the compact lithium-ion battery would probably require cooling by a dielectric liquid for operation under conditions of vigorous vehicle driving.

Nelson, P. A.; Henriksen, G. L.; Amine, K.

2000-12-04T23:59:59.000Z

134

U.S. Department of Energy Hybrid Electric Vehicle Battery and...  

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

and varies significantly with environmental conditions, the fuel economy and, therefore, battery performance, has remained stable over vehicle life (160,000 miles). Key Words...

135

2006 Lexus RX400h-4807 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Lexus RX900h hybrid electric vehicle (Vin Number JTJHW31U660004807). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

136

2006 Lexus RX400h-2575 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Lexus RX900h hybrid electric vehicle (Vin Number JTJHW31U660002575). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

137

2006 Lexus RX400h-2575 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Lexus RX900h hybrid electric vehicle (Vin Number JTJHW31U660002575). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

138

2006 Lexus RX400h-4807 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy's Advanced Vehicle Testing Activity conducts several different types of tests on hybrid electric vehicles, including testing hybrid electric vehicles batteries when both the vehicles and batteries are new, and at the conclusion of 160,000 miles of accelerated testing. This report documents the battery testing performed and battery testing results for the 2007 Lexus RX900h hybrid electric vehicle (Vin Number JTJHW31U660004807). Testing was performed by the Electric Transportation Engineering Corporation. The Advanced Vehicle Testing Activity is part of the U.S. Department of Energy's Vehicle Technologies Program. The Idaho National Laboratory and the Electric Transportation Engineering Corporation conduct Advanced Vehicle Testing Activity for the U.S. Department of Energy.

Tyler Gray; Chester Motloch; James Francfort

2010-01-01T23:59:59.000Z

139

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

140

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

DOE Green Energy (OSTI)

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.


141

SIMULATED LIFECYCLE COSTS OF ULTRACAPACITORS IN BATTERY ELECTRIC VEHICLES A.G. Simpson*, P.C. Sernia and G.R. Walker  

E-Print Network (OSTI)

SIMULATED LIFECYCLE COSTS OF ULTRACAPACITORS IN BATTERY ELECTRIC VEHICLES A.G. Simpson*, P, vehicle driving range, battery pack lifetime, and potential reductions in system lifecycle cost costs of ultracapacitors in battery electric vehicle applications. The lifecycle operation

Walker, Geoff

142

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

143

2010 Ford Fusion VIN 4757 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing HEV 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 2010 Ford Fusion HEV (VIN: 3FADP0L34AR144757). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Tyler Gray; Matthew Shirk

2013-01-01T23:59:59.000Z

144

2010 Honda Insight VIN 0141 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV 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 2010 Honda Insight HEV (VIN: JHMZE2H78AS010141). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Tyler Gray

2013-01-01T23:59:59.000Z

145

2010 Toyota Prius VIN 0462 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV 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 2010 Toyota Prius HEV (VIN: JTDKN3DU2A5010462). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Tyler Gray; Matthew Shirk

2013-01-01T23:59:59.000Z

146

2010 Toyota Prius VIN 6063 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV 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 2010 Toyota Prius HEV (VIN JTDKN3DU5A0006063). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Tyler Gray; Matthew Shirk

2013-01-01T23:59:59.000Z

147

2010 Honda Insight VIN 1748 Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy 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 (HEVs), including testing the HEV 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 2010 Honda Insight HEV (VIN: JHMZE2H59AS011748). Battery testing was performed by the Electric Transportation Engineering Corporation dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the Advanced Vehicle Testing Activity for the Vehicle Technologies Program of the U.S. Department of Energy.

Tyler Gray; Matthew Shirk

2013-01-01T23:59:59.000Z

148

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

149

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

E-Print Network (OSTI)

in and Batttery Electric Vehicles, The 5 th IEEE VehiclePlug-in and Battery Electric Vehicles, The 1 st IEEE EnergyE. Plug-in Hybrid-Electric Vehicle Powertrain Design and

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

150

Fuel Cell and Battery Electric Vehicles Compared By C. E. (Sandy) Thomas, Ph.D., President  

E-Print Network (OSTI)

reduction goals1 . As shown in Figure 1, hybrid electric vehicles (HEV's) and plugin hybrid electric electric vehicle; H2 ICE HEV = hydrogen internal combustion engine hybrid electric vehicle) C.E. Thomas Fuel Cell and Battery Electric Vehicles Compared By C. E. (Sandy) Thomas, Ph.D., President H2Gen

151

Implementations of electric vehicle system based on solar energy in Singapore assessment of lithium ion batteries for automobiles  

E-Print Network (OSTI)

In this thesis report, both quantitative and qualitative approaches are used to provide a comprehensive analysis of lithium ion (Li-ion) batteries for plug-in hybrid electric vehicle (PHEV) and battery electric vehicle ...

Fu, Haitao

2009-01-01T23:59:59.000Z

152

Electrochemistry theorem based state-of-charge estimation of the lead acid batteries for electric vehicles  

Science Conference Proceedings (OSTI)

A method for the estimation of the state-of-charge in lead-acid batteries for electric vehicles is investigated. The electrochemistry theorem is introduced to measure the resistance effect of the electrode reaction and to estimate the internal energy ... Keywords: digital signal processor, electric vehicles, electrode reaction, electrolyte specific gravity, lead-acid battery, state-of-charge

Ying-Shing Shiao; Ding-Tsair Su; Jui-Liang Yang; Rong-Wen Hung

2008-10-01T23:59:59.000Z

153

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. Manuscript submitted May 15, 2000; revised manuscript received January 15, 2001. Lithium-ion batteries effort by the U.S. Department of Energy to aid the development of lithium-ion batteries for hybrid

154

Electric vehicle battery R D in the context of a propulsion system  

SciTech Connect

A battery system for an electric vehicle should be designed and developed in concert with the other components of the propulsion system. Technology development efforts sponsored by the US Department of Energy are addressing all the constituent electric vehicle component technologies, including the battery subsystem technologies, from the perspective of the complete propulsion system. This approach is considered to be essential for three reasons. First, the ultimate viability of a given battery technology can only be assured in the context of a complete propulsion system. Second, many required battery subsystem technology advancements can only be addressed in concert with the other propulsion system components. Third, development and testing of battery subsystem technologies in conjunction with powertrain subsystem technology development is necessary in order to provide essential information to the battery developer and to the vehicle developer that can not be obtained when battery development is performed as a discrete activity. 7 refs., 6 figs.

Patil, P.G. (USDOE Assistant Secretary for Conservation and Renewable Energy, Washington, DC (USA). Office of Transportation Systems); Christianson, C.C.; Miller, J.F. (Argonne National Lab., IL (USA))

1989-01-01T23:59:59.000Z

155

Evaluation of near-term electric vehicle battery systems through in-vehicle testing: Second annual final report  

SciTech Connect

This report documents the performance from October 1985 through September 1986 of the Tennessee Valley Authority's ongoing project to evaluate near-term electric vehicle traction batteries. This second annual report includes the addition of four new batteries and the termination of two sets. The purpose of this field test activity is to provide an impartial evaluation and comparison of battery performance in a real-world operating environment. Testing includes initial acceptance testing of battery components and systems, daily in-vehicle operation of the batteries, monthly in-vehicle driving range tests, and periodic static (constant current) discharge tests under computer control. Battery performance data is typically presented on the basis of specific energy versus accumulated vehicle mileage and vehicle driving range over fixed operating cycle (35 mi/h) constant speed (SAE J227a ''C'' Cycle). Data is analyzed statistically with variable conditions normalized. The life-cycle is terminated when a battery system's measured capacity drops below 60 percent of rating (at the 2-hour rate) and/or after 25 percent of the battery modules have been replaced. 120 figs., 2 tabs.

Blickwedel, T.W.; Whitehead, G.D.; Thomas, W.A.

1987-12-01T23:59:59.000Z

156

2011 Chevrolet Volt VIN 0815 Plug-In Hybrid Electric Vehicle Battery Test Results  

SciTech Connect

The U.S. Department of Energy (DOE) Advanced Vehicle Testing Activity (AVTA) program consists of vehicle, battery, and infrastructure testing on advanced technology related to transportation. The activity includes tests on plug-in hybrid electric vehicles (PHEVs), including testing the PHEV batteries when both the vehicles and batteries are new and at the conclusion of 12,000 miles of on-road fleet testing. This report documents battery testing performed for the 2011 Chevrolet Volt PHEV (VIN 1G1RD6E48BU100815). The battery testing was performed by the Electric Transportation Engineering Corporation (eTec) dba ECOtality North America. The Idaho National Laboratory and ECOtality North America collaborate on the AVTA for the Vehicle Technologies Program of the DOE.

Tyler Gray; Matthew Shirk; Jeffrey Wishart

2013-07-01T23:59:59.000Z

157

Addressing the Impact of Temperature Extremes on Large Format Li-Ion Batteries for Vehicle Applications (Presentation)  

SciTech Connect

This presentation discusses the effects of temperature on large format lithium-ion batteries in electric drive vehicles.

Pesaran, A.; Santhanagopalan, S.; Kim, G. H.

2013-05-01T23:59:59.000Z

158

Battery Wear from Disparate Duty-Cycles: Opportunities for Electric-Drive Vehicle Battery Health Management; Preprint  

SciTech Connect

Electric-drive vehicles utilizing lithium-ion batteries experience wholly different degradation patterns than do conventional vehicles, depending on geographic ambient conditions and consumer driving and charging patterns. A semi-empirical life-predictive model for the lithium-ion graphite/nickel-cobalt-aluminum chemistry is presented that accounts for physically justified calendar and cycling fade mechanisms. An analysis of battery life for plug-in hybrid electric vehicles considers 782 duty-cycles from travel survey data superimposed with climate data from multiple geographic locations around the United States. Based on predicted wear distributions, opportunities for extending battery life including modification of battery operating limits, thermal and charge control are discussed.

Smith, K.; Earleywine, M.; Wood, E.; Pesaran, A.

2012-10-01T23:59:59.000Z

159

Evaluation of Emerging Battery Technologies for Plug-in Hybrid Vehicles  

Science Conference Proceedings (OSTI)

The performance, cycle life, and cost of available batteries are key issues in determining the marketability of plug-in hybrid-electric vehicles (PHEVs). The California Air Resources Board (CARB) initiated a project to evaluate emerging lithiumion battery technologies for PHEV applications. Work initially focused on the determination of the characteristics of one of the most interesting of the emerging lithium-ion batteries, the lithium titanate battery in commercial development by Altairnano, but other ...

2009-08-24T23:59:59.000Z

160

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

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

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

162

Zinc air battery development for electric vehicles. Final report  

DOE Green Energy (OSTI)

This report summarizes the results of research conducted during the sixteen month continuation of a program to develop rechargeable zinc-air batteries for electric vehicles. The zinc-air technology under development incorporates a metal foam substrate for the zinc electrode, with flow of electrolyte through the foam during battery operation. In this ``soluble`` zinc electrode the zincate discharge product dissolves completely in the electrolyte stream. Cycle testing at Lawrence Berkeley Laboratory, where the electrode was invented, and at MATSI showed that this approach avoids the zinc electrode shape change phenomenon. Further, electrolyte flow has been shown to be necessary to achieve significant cycle life (> 25 cycles) in this open system. Without it, water loss through the oxygen electrode results in high-resistance failure of the cell. The Phase I program, which focused entirely on the zinc electrode, elucidated the conditions necessary to increase electrode capacity from 75 to as much as 300 mAh/cm{sup 2}. By the end of the Phase I program over 500 cycles had accrued on one of the zinc-zinc half cells undergoing continuous cycle testing. The Phase II program continued the half cell cycle testing and separator development, further refined the foam preplate process, and launched into performance and cycle life testing of zinc-air cells.

Putt, R.A.; Merry, G.W. [MATSI, Inc., Atlanta, GA (United States)

1991-07-01T23:59:59.000Z

163

Sodium sulfur electric vehicle battery engineering program final report, September 2, 1986--June 15, 1993  

DOE Green Energy (OSTI)

In September 1986 a contract was signed between Chloride Silent Power Limited (CSPL) and Sandia National Laboratories (SNL) entitled ``Sodium Sulfur Electric Vehicle Battery Engineering Program``. The aim of the cost shared program was to advance the state of the art of sodium sulfur batteries for electric vehicle propulsion. Initially, the work statement was non-specific in regard to the vehicle to be used as the design and test platform. Under a separate contract with the DOE, Ford Motor Company was designing an advanced electric vehicle drive system. This program, called the ETX II, used a modified Aerostar van for its platform. In 1987, the ETX II vehicle was adopted for the purposes of this contract. This report details the development and testing of a series of battery designs and concepts which led to the testing, in the US, of three substantial battery deliverables.

NONE

1993-06-01T23:59:59.000Z

164

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

165

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

DOE Green Energy (OSTI)

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

166

Battery chargers  

SciTech Connect

A battery charger designed to be installed in a vehicle, and while utilizing a portion of this vehicle's electrical system, can be used to charge another vehicle's battery or batteries. This battery charger has a polarity sensor, and when properly connected to an external battery will automatically switch away from charging the internal battery to charging the external battery or batteries. And, when disconnected from the external battery or batteries will automatically switch back to charging the internal battery, thus making it an automatic vehicle to vehicle battery charger.

Winkler, H.L.

1984-05-15T23:59:59.000Z

167

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

168

Energy and environmental impacts of electric vehicle battery production and recycling  

DOE Green Energy (OSTI)

Electric vehicle batteries use energy and generate environmental residuals when they are produced and recycled. This study estimates, for 4 selected battery types (advanced lead-acid, sodium-sulfur, nickel-cadmium, and nickel-metal hydride), the impacts of production and recycling of the materials used in electric vehicle batteries. These impacts are compared, with special attention to the locations of the emissions. It is found that the choice among batteries for electric vehicles involves tradeoffs among impacts. For example, although the nickel-cadmium and nickel-metal hydride batteries are similar, energy requirements for production of the cadmium electrodes may be higher than those for the metal hydride electrodes, but the latter may be more difficult to recycle.

Gaines, L.; Singh, M.

1995-12-31T23:59:59.000Z

169

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles  

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

170

Control of fuel cell/battery/supercapacitor hybrid source for vehicle applications  

Science Conference Proceedings (OSTI)

This paper presents a control algorithm for utilizing a polymer electrolyte membrane fuel cell (PEMFC) as a main power source and storage devices (batteries and supercapacitors) for dc distributed system, particularly for future FC vehicle applications. ...

Phatiphat Thounthong; Panarit Sethakul; Stephane Rael; Bernard Davat

2009-02-01T23:59:59.000Z

171

Quantifying the Promise of Li-Air Batteries for Electric Vehicles...  

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

Quantifying the Promise of Li-Air Batteries for Electric Vehicles December 17, 2013 11:00AM to 12:00PM Presenter Kevin Gallagher, JCESR Location Building 205, Y-Wing Auditorium...

172

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

DOE Green Energy (OSTI)

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

173

Fault Prediction and Fault-Tolerant of Lithium-ion Batteries Temperature Failure for Electric Vehicle  

Science Conference Proceedings (OSTI)

Design and implementation of dual-redundancy was developed to predict Lithium-ion battery failure for electric vehicle. Data fusion unit, prediction unit and determination unit were designed. Outputs from original and redundant sensors were integrated ... Keywords: Lithium-ion battery, dual-redundancy, data fusion, prediction, Fault-tolerant

Hu Chunhua; He Ren; Wang Runcai; Yu Jianbo

2012-07-01T23:59:59.000Z

174

Thermal Management of Batteries in Advanced Vehicles Using Phase-Change Materials (Presentation)  

DOE Green Energy (OSTI)

This Powerpoint presentation examines battery thermal management using PCM and concludes excellent performance in limiting peak temperatures at short period extensive battery use; although, vehicle designers will need to weigh the potential increase in mass and cost associated with adding PCM against the anticipated benefits.

Kim, G.-H.; Gonder, J.; Lustbader, J.; Pesaran, A.

2007-12-01T23:59:59.000Z

175

Cost and design study for electric vehicle lead--acid batteries  

SciTech Connect

A design and cost study for electric-vehicle lead--acid batteries is presented; a research and development program leading to demonstration and testing of 20- to 30-kWh batteries is proposed. Both flat pasted and tubular positive electrodes are included. Detailed testing programs are set forth. 110 figures, 8 tables (RWR)

1977-01-01T23:59:59.000Z

176

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles  

SciTech Connect

Recycling and disposal of spent sodium-sulfur (Na/S) batteries are important issues that must be addressed as part of the commercialization process of Na/S battery-powered electric vehicles. The use of Na/S batteries in electric vehicles will result in significant environmental benefits, and the disposal of spent batteries should not detract from those benefits. In the United States, waste disposal is regulated under the Resource Conservation and Recovery Act (RCRA). Understanding these regulations will help in selecting recycling and disposal processes for Na/S batteries that are environmentally acceptable and cost effective. Treatment processes for spent Na/S battery wastes are in the beginning stages of development, so a final evaluation of the impact of RCRA regulations on these treatment processes is not possible. The objectives of tills report on battery recycling and disposal are as follows: Provide an overview of RCRA regulations and requirements as they apply to Na/S battery recycling and disposal so that battery developers can understand what is required of them to comply with these regulations; Analyze existing RCRA regulations for recycling and disposal and anticipated trends in these regulations and perform a preliminary regulatory analysis for potential battery disposal and recycling processes. This report assumes that long-term Na/S battery disposal processes will be capable of handling large quantities of spent batteries. The term disposal includes treatment processes that may incorporate recycling of battery constituents. The environmental regulations analyzed in this report are limited to US regulations. This report gives an overview of RCRA and discusses RCRA regulations governing Na/S battery disposal and a preliminary regulatory analysis for Na/S battery disposal.

Corbus, D.

1992-09-01T23:59:59.000Z

177

Progress in the development of recycling processes for electric vehicle batteries  

SciTech Connect

Disposition of electric vehicle (EV) batteries after they have reached the end of their useful life is an issue that could impede the widespread acceptance of EVs in the commercial market. This is especially true for advanced battery systems where working recycling processes have not as yet been established. The DOE sponsors an Ad Hoc Electric Vehicle Battery Readiness Working Group to identify barriers to the introduction of commercial EVs and to advise them of specific issues related to battery reclamation/recycling, in-vehicle battery safety, and battery shipping. A Sub-Working Group on the reclamation/recycle topic has been reviewing the status of recycling process development for the principal battery technologies that are candidates for EV use from the near-term to the long-term. Recycling of near-term battery technologies, such as lead-acid and nickel/cadmium, is occurring today and it is believed that sufficient processing capacity can be maintained to keep up with the large number of units that could result from extensive EV use. Reclamation/recycle processes for midterm batteries are partially developed. Good progress has been made in identifying processes to recycle sodium/sulfur batteries at a reasonable cost and pilot scale facilities are being tested or planned. A pre-feasibility cost study on the nickel/metal hydride battery also indicates favorable economics for some of the proposed reclamation processes. Long-term battery technologies, including lithium-polymer and lithium/iron disulfide, are still being designed and developed for EVs, so descriptions for prototype recycling processes are rather general at this point. Due to the long time required to set up new, full-scale recycling facilities, it is important to develop a reclamation/recycling process in parallel with the battery technologies themselves.

Jungst, R.G.; Clark, R.P.

1994-08-01T23:59:59.000Z

178

Variability of Battery Wear in Light Duty Plug-In Electric Vehicles Subject to Ambient Temperature, Battery Size, and Consumer Usage: Preprint  

DOE Green Energy (OSTI)

Battery wear in plug-in electric vehicles (PEVs) is a complex function of ambient temperature, battery size, and disparate usage. Simulations capturing varying ambient temperature profiles, battery sizes, and driving patterns are of great value to battery and vehicle manufacturers. A predictive battery wear model developed by the National Renewable Energy Laboratory captures the effects of multiple cycling and storage conditions in a representative lithium chemistry. The sensitivity of battery wear rates to ambient conditions, maximum allowable depth-of-discharge, and vehicle miles travelled is explored for two midsize vehicles: a battery electric vehicle (BEV) with a nominal range of 75 mi (121 km) and a plug-in hybrid electric vehicle (PHEV) with a nominal charge-depleting range of 40 mi (64 km). Driving distance distributions represent the variability of vehicle use, both vehicle-to-vehicle and day-to-day. Battery wear over an 8-year period was dominated by ambient conditions for the BEV with capacity fade ranging from 19% to 32% while the PHEV was most sensitive to maximum allowable depth-of-discharge with capacity fade ranging from 16% to 24%. The BEV and PHEV were comparable in terms of petroleum displacement potential after 8 years of service, due to the BEV?s limited utility for accomplishing long trips.

Wood, E.; Neubauer, J.; Brooker, A. D.; Gonder, J.; Smith, K. A.

2012-08-01T23:59:59.000Z

179

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

E-Print Network (OSTI)

weight, volume, and the cost of the battery unit. It is alsoweight, volume, and the cost of the battery unit. It is alsoCost-Effective Combinations of Ultracapacitors and Batteries for Vehicle Applications, Proceedings of the Second International Advanced Battery

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

180

EVS27 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 1 Barcelona, Spain, November 17-20, 2013  

E-Print Network (OSTI)

EVS27 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 1 EVS27 Barcelona Vehicle Symposium & Exhibition (EVS27), Barcelona : Spain (2013)" #12;EVS27 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 2 However, for embedded systems, studies look for simple signals

Recanati, Catherine

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

PNGV Battery Testing Procedures and Analytical Methodologies for Hybrid Electric Vehicles  

SciTech Connect

Novel testing procedures and analytical methodologies to assess the performance of hybrid electric vehicle batteries have been developed. Tests include both characterization and cycle life and/or calendar life, and have been designed for both Power Assist and Dual Mode applications. Analytical procedures include a battery scaling methodology, the calculation of pulse resistance, pulse power, available energy, and differential capacity, and the modeling of calendar and cycle life data. Representative performance data and examples of the application of the analytical methodologies including resistance growth, power fade, and cycle and calendar life modeling for hybrid electric vehicle batteries are presented.

Motloch, Chester George; Belt, Jeffrey R; Christophersen, Jon Petter; Wright, Randy Ben; Hunt, Gary Lynn; Haskind, H. J.; Tartamella, T.; Sutula, R.

2002-06-01T23:59:59.000Z

182

Assessment of the status of fuel cell/battery vehicle power systems  

DOE Green Energy (OSTI)

An assessment of the status of the integrated fuel cell/battery power system concept for electric vehicle propulsion is reported. The fuel cell, operating on hydrogen or methanol (indirectly), acts as a very high capacity energy battery for vehicle sustaining operation, while a special power battery provides over-capacity transient power on demand, being recharged by the fuel cell, e.g., during cruising. A focused literature search and a set of industrial and Government contacts were carried out to establish views, outlooks, and general status concerning the concept. It is evident that, although vehicle battery R and D is being actively pursued, little of today's fuel cell work is directed to transportation usage. Only very limited attention has been, and is being, given to the fuel cell/battery power system concept itself. However, judging largely from computer-simulated driving cycle results, the concept can provide needed range capabilities and general operating flexibility to electric vehicles. New transportation applications, conventionally viewed as beyond the capability of electric vehicles, may thereby be practical, e.g., rail, trucks. In view of these potential and important benefits, and the absence of any comprehensive research, development, and demonstration activities which are supportive of the fuel cell/battery system concept, the initiation of an appropriate effort is recommended by the Assessment Team. This general recommendation is supported by applicable findings, observations, and conclusions.

Escher, W.J.D.; Foster, R.W.

1980-02-01T23:59:59.000Z

183

Assessment of the status of fuel cell/battery vehicle power systems  

SciTech Connect

An assessment of the status of the integrated fuel cell/battery power system concept for electric vehicle propulsion is reported. The fuel cell, operating on hydrogen or methanol (indirectly), acts as a very high capacity energy battery for vehicle sustaining operation, while a special power battery provides over-capacity transient power on demand, being recharged by the fuel cell, e.g., during cruising. A focused literature search and a set of industrial and Government contacts were carried out to establish views, outlooks, and general status concerning the concept. It is evident that, although vehicle battery R and D is being actively pursued, little of today's fuel cell work is directed to transportation usage. Only very limited attention has been, and is being, given to the fuel cell/battery power system concept itself. However, judging largely from computer-simulated driving cycle results, the concept can provide needed range capabilities and general operating flexibility to electric vehicles. New transportation applications, conventionally viewed as beyond the capability of electric vehicles, may thereby be practical, e.g., rail, trucks. In view of these potential and important benefits, and the absence of any comprehensive research, development, and demonstration activities which are supportive of the fuel cell/battery system concept, the initiation of an appropriate effort is recommended by the Assessment Team. This general recommendation is supported by applicable findings, observations, and conclusions.

Escher, W.J.D.; Foster, R.W.

1980-02-01T23:59:59.000Z

184

Battery Requirements for Plug-In Hybrid Electric Vehicles: Analysis and Rationale (Presentation)  

DOE Green Energy (OSTI)

Slide presentation to EVS-23 conference describing NREL work to help identify appropriate requirements for batteries to be useful for plug-in hybrid-electric vehicles (PHEVs). Suggested requirements were submitted to the U.S. Advanced Battery Consortium, which used them for a 2007 request for proposals. Requirements were provided both for charge-depleting mode and charge-sustaining mode and for high power/energy ratio and hige energy/power ration batteries for each (different modes of PHEV operation), along with battery and system level requirements.

Pesaran, A.

2007-12-01T23:59:59.000Z

185

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

186

Current status of environmental, health, and safety issues of nickel metal-hydride batteries for electric vehicles  

Science Conference Proceedings (OSTI)

This report identifies important environment, health, and safety issues associated with nickel metal-hydride (Ni-MH) batteries and assesses the need for further testing and analysis. Among the issues discussed are cell and battery safety, workplace health and safety, shipping requirements, and in-vehicle safety. The manufacture and recycling of Ni-MH batteries are also examined. This report also overviews the ``FH&S`` issues associated with other nickel-based electric vehicle batteries; it examines venting characteristics, toxicity of battery materials, and the status of spent batteries as a hazardous waste.

Corbus, D.; Hammel, C.J.; Mark, J.

1993-08-01T23:59:59.000Z

187

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

DOE Green Energy (OSTI)

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

188

Battery Ownership Model: A Tool for Evaluating the Economics of Electrified Vehicles and Related Infrastructure; Preprint  

DOE Green Energy (OSTI)

Electric vehicles could significantly reduce greenhouse gas (GHG) emissions and dependence on imported petroleum. However, for mass adoption, EV costs have historically been too high to be competitive with conventional vehicle options due to the high price of batteries, long refuel time, and a lack of charging infrastructure. A number of different technologies and business strategies have been proposed to address some of these cost and utility issues: battery leasing, battery fast-charging stations, battery swap stations, deployment of charge points for opportunity charging, etc. In order to investigate these approaches and compare their merits on a consistent basis, the National Renewable Energy Laboratory (NREL) has developed a new techno-economic model. The model includes nine modules to examine the levelized cost per mile for various types of powertrain and business strategies. The various input parameters such as vehicle type, battery, gasoline, and electricity prices; battery cycle life; driving profile; and infrastructure costs can be varied. In this paper, we discuss the capabilities of the model; describe key modules; give examples of how various assumptions, powertrain configurations, and business strategies impact the cost to the end user; and show the vehicle's levelized cost per mile sensitivity to seven major operational parameters.

O'Keefe, M.; Brooker, A.; Johnson, C.; Mendelsohn, M.; Neubauer, J.; Pesaran, A.

2011-01-01T23:59:59.000Z

189

Battery Ownership Model: A Tool for Evaluating the Economics of Electrified Vehicles and Related Infrastructure; Preprint  

SciTech Connect

Electric vehicles could significantly reduce greenhouse gas (GHG) emissions and dependence on imported petroleum. However, for mass adoption, EV costs have historically been too high to be competitive with conventional vehicle options due to the high price of batteries, long refuel time, and a lack of charging infrastructure. A number of different technologies and business strategies have been proposed to address some of these cost and utility issues: battery leasing, battery fast-charging stations, battery swap stations, deployment of charge points for opportunity charging, etc. In order to investigate these approaches and compare their merits on a consistent basis, the National Renewable Energy Laboratory (NREL) has developed a new techno-economic model. The model includes nine modules to examine the levelized cost per mile for various types of powertrain and business strategies. The various input parameters such as vehicle type, battery, gasoline, and electricity prices; battery cycle life; driving profile; and infrastructure costs can be varied. In this paper, we discuss the capabilities of the model; describe key modules; give examples of how various assumptions, powertrain configurations, and business strategies impact the cost to the end user; and show the vehicle's levelized cost per mile sensitivity to seven major operational parameters.

O' Keefe, M.; Brooker, A.; Johnson, C.; Mendelsohn, M.; Neubauer, J.; Pesaran, A.

2011-01-01T23:59:59.000Z

190

US Department of Energy Hybrid Vehicle Battery and Fuel Economy Testing  

DOE Green Energy (OSTI)

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

191

Lithium-Sulfur Batteries: Development of High Energy Lithium-Sulfur Cells for Electric Vehicle Applications  

SciTech Connect

BEEST Project: Sion Power is developing a lithium-sulfur (Li-S) battery, a potentially cost-effective alternative to the Li-Ion battery that could store 400% more energy per pound. All batteries have 3 key parts—a positive and negative electrode and an electrolyte—that exchange ions to store and release electricity. Using different materials for these components changes a battery’s chemistry and its ability to power a vehicle. Traditional Li-S batteries experience adverse reactions between the electrolyte and lithium-based negative electrode that ultimately limit the battery to less than 50 charge cycles. Sion Power will sandwich the lithium- and sulfur-based electrode films around a separator that protects the negative electrode and increases the number of charges the battery can complete in its lifetime. The design could eventually allow for a battery with 400% greater storage capacity per pound than Li-Ion batteries and the ability to complete more than 500 recharge cycles.

2010-10-01T23:59:59.000Z

192

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) involved two experiments which looked at a vehicle systems approach to analyze two such technical challenges: Battery life and low battery power at cold (-7 ?C) temperature. The first experiment, concerning battery life and its impact on gasoline savings due to a PHEV, evaluates different vehicle control strategies over a pre-defined vehicle drive cycle, in order to identify the control strategy which yields the maximum dollar savings (operating cost) over the life of the vehicle, when compared to a charge sustaining hybrid. Battery life degradation over the life of the vehicle, and fuel economy savings on every trip (daily) are taken into account when calculating the net present value of the gasoline dollars saved. The second experiment evaluates the impact of different vehicle control strategies in heating up the PHEV battery (due to internal ohmic losses) for cold ambient conditions. The impact of low battery power (available to the vehicle powertrain) due to low battery and ambient temperatures has been well documented in literature. The trade-off between the benefits of heating up the battery versus heating up the internal combustion engine are evaluated, using different control strategies, and the control strategy, which provided optimum temperature rise of each component, is identified.

Shidore, Neeraj Shripad

2012-05-01T23:59:59.000Z

193

Environmental impact analysis of electric and hybrid vehicle batteries. Final report  

DOE Green Energy (OSTI)

This environmental impact analysis of electric and hybrid vehicle batteries is intended to identify principal environmental impacts resulting directly or indirectly from the development of electric vehicle batteries. Thus, the result of this study could be used to determine the appropriate following step in the U.S. DOE's EIA process. The environmental impacts considered in this document are the incremental impacts generated during the various phases in the battery life cycle. The processes investigated include mining, milling, smelting, and refining of metallic materials for electrode components; manufacturing processes of inorganic chemicals and other materials for electrolytes and other hardware components; battery assembly processes; operation and maintenance of batteries; and recycling and disposal of used batteries. The severity of the incremental impacts is quantified to the extent consistent with the state-of-knowledge. Many of the industrial processes involve proprietary or patent information; thus, in many cases, the associated environmental impacts could not be determined. In addition, most candidate battery systems are still in the development phase. Thus, the manufacturing and recycling processes for most battery systems either have not been developed by industry, or the information is not available. For these cases, the associated environmental impact evaluations could only be qualitative, and the need for further investigations is indicated. 26 figures, 27 tables. (RWR)

Not Available

1977-12-16T23:59:59.000Z

194

USABC electric vehicle Battery Test Procedures Manual. Revision 2  

DOE Green Energy (OSTI)

This manual summarizes the procedural information needed to perform the battery testing being sponsored by the United States Advanced Battery Consortium (USABC). This information provides the structure and standards to be used by all testing organizations, including the USABC developers, national laboratories, or other relevant test facilities.

NONE

1996-01-01T23:59:59.000Z

195

Recommended mission directed goals for electric vehicle battery research and development. The task force on electric vehicle battery goals  

SciTech Connect

Research and development goal packages were developed for the state-of-the-art, flow-through, and bipolar lead-acid batteries, nickel/iron, nickel/zinc, nickel/cadmium, zinc/bromine, iron/air, lithium/iron sulfide, and sodium/sulfur technologies. Since each battery must satisfy mission power/energy requirements throughout every cycle of its operating life, the principal ''design point'' is the end-of-life condition. Since all batteries exhibit deteriorating performance with age, excess kWh capacity of 20 to 30 percent is required early in life. The Battery Panel first identified present state-of-the-art performance characteristics and design interrelationships for each battery technology, and projected the degree of advance expected by 1995. Near-term and 1995 design tradeoffs were modeled using the EVA computerized system developed by ANL. The next step was to target each battery system for a single range (80, 120 or 160 km), depending on its projected 1995 capabilities. For each battery, baseline calculations were carried out assuming the maximum battery weight (695 kg) to be on board. In addition to performance, life, and cost goals, development targets were also established for efficiency, maintenance, and allowable self-discharge rate. The Task Force attempted to establish battery cost requirements, assuming economic parity (in 1995) with other modes of transportation.

Not Available

1986-03-01T23:59:59.000Z

196

Effects of battery technologies, driving patterns, and climate comfort control on the performance of electric vehicles  

SciTech Connect

A computer software package, EAGLES, has been developed at Argonne National Laboratory to analyze electric vehicle (EV) performance. In this paper, we present EAGLES predictions of EV driving range, acceleration rate, and energy consumption under various driving patterns, with different battery technologies, and with assumptions concerning use of air conditioners and/or heaters for climate comfort control. The specifications of a baseline, four-passenger EV for given design performance requirements are established, assuming urban driving conditions represented by the Los Angeles 92 (LA-92) driving cycle and using battery characteristics similar to those of the United States Advanced Battery Consortium (USABC) midterm battery performance goals. To examine the impacts of driving patterns, energy consumption is simulated under three different driving cycles: the New York City Cycle, the Los Angeles 92 Cycle, and the ECE-15 Cycle. To test the impacts of battery technologies, performance attributes of an advanced lead-acid battery, the USABC midterm battery goals, and the USABC long-term battery goals are used. Finally, EV energy consumption from use of air conditioners and/or heaters under different climates is estimated and the associated driving range penalty for one European city (Paris) and two United States cities (Chicago and Los Angeles) is predicted. The results of this paper show the importance of considering various effects, such as battery technology, driving pattern, and climate comfort control, in the determination of EV performances. Electric vehicle energy consumption decreases more than 20% when a battery with characteristics similar to the USABC long-term goals is used instead of an advanced lead-acid battery.

Marr, W.W.; Wang, M.Q.; Santini, D.J.

1994-05-15T23:59:59.000Z

197

Develop nickel--zinc battery suitable for electric vehicle propulsion. Task A: design and cost study  

DOE Green Energy (OSTI)

A three-month design and cost study for the use of nickel--zinc batteries in electric vehicles is presented. Battery configuration is analyzed, and expected performance is set forth. Current development problems concern component materials and capacity decline on cycling, electrolyte maintenance, and thermal characteristics. The manufacturing process is outlined, and estimates are made for cost, materials requirements, capital needs, etc. 61 figures, 24 tables. (RWR)

None

1977-02-15T23:59:59.000Z

198

Hybrid Vehicle Comparison Testing Using Ultracapacitor vs. Battery Energy Storage (Presentation)  

SciTech Connect

With support from General Motors, NREL researchers converted and tested a hybrid electric vehicle (HEV) with three energy storage configurations: a nickel metal-hydride battery and two ultracapacitor (Ucap) modules. They found that the HEV equipped with one Ucap module performed as well as or better than the HEV with a stock NiMH battery configuration. Thus, Ucaps could increase the market penetration and fuel savings of HEVs.

Gonder, J.; Pesaran, A.; Lustbader, J.; Tataria, H.

2010-02-01T23:59:59.000Z

199

Performance and life evaluation of nickel/iron battery technology for dual shaft electric propulsion vehicle  

SciTech Connect

As part of a cost-shared contract between the US Department of Energy (Office of Transportation Systems) and Eaton Corp. to develop an advanced dual shaft electric propulsion (DSEP) vehicle, several nickel/iron (Ni/Fe) batteries were designed and procured from Eagle-Picher Industries (EPI) for evaluation and vehicle use. In March 1986, two individual 5-cell Ni/Fe modules and a 140-cell (28-module) battery pack were delivered to Argonne for evaluation. Performance characterization tests were conducted on the two modules and life testing performed on the battery pack. Module performance testing was completed in early 1987 after about 215 cycles of operation. Each module still retained {approximately}90% of its initial 180-Ah capacity at the end of testing ({approximately}163 Ah/970 Wh). Life evaluation of the 168-V, 28-kWh battery pack was conducted with driving profile discharges. A 1377-s power profile that represented the battery load in a DSEP vehicle undergoing a Federal Urban Driving Schedule (FUDS) was used. Testing was temporarily suspended in October 1987 after the battery pack had accumulated 502 cycles (209 cycles in 1986). After a three-month trickle charge ({approximately}3 A), testing was resumed (January 1988) with driving profile discharges. In March 1988, battery performance was being limited by three modules. After 545 cycles, the three modules were removed from the pack. Battery performance, however, continued to decline and another four modules were removed in September 1988 (645 cycles). Several remaining modules started to exhibit a high self-discharge loss and a capacity of only 119 Ah (15.1 kWh) could be achieved. The life evaluation was halted in October 1988 after 661 cycles had been accumulated. This report outlines the test activities and presents the performance results of the individual modules and the battery pack involved in this technology evaluation. 18 figs., 4 tabs.

DeLuca, W. (ed.)

1990-05-01T23:59:59.000Z

200

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles  

DOE Green Energy (OSTI)

This report is the last of four volumes that identify and assess the environmental, health, and safety issues that may affect the commercial-scale use of sodium-sulfur (Na/S) battery technology as the energy source in electric and hybrid vehicles. The reports 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 the in-vehicle safety issues of electric vehicles powered by Na/S batteries. The report is based on a review of the literature and on discussions with experts at DOE, national laboratories and agencies, and private industry. It has three major goals: (1) to identify the unique hazards associated with electric vehicle (EV) use; (2) to describe the existing standards, regulations, and guidelines that are or could be applicable to these hazards; and (3) to discuss the adequacy of the existing requirements in addressing the safety concerns of EVs.

Mark, J

1992-11-01T23:59:59.000Z

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.


201

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

202

Power electronic interface circuits for batteries and ultracapacitors in electric vehicles and battery storage systems  

DOE Patents (OSTI)

A method and apparatus for load leveling of a battery in an electrical power system includes a power regulator coupled to transfer power between a load and a DC link, a battery coupled to the DC link through a first DC-to-DC converter and an auxiliary passive energy storage device coupled to the DC link through a second DC-to-DC converter. The battery is coupled to the passive energy storage device through a unidirectional conducting device whereby the battery can supply power to the DC link through each of the first and second converters when battery voltage exceeds voltage on the passive storage device. When the load comprises a motor capable of operating in a regenerative mode, the converters are adapted for transferring power to the battery and passive storage device. In this form, resistance can be coupled in circuit with the second DC-to-DC converter to dissipate excess regenerative power.

King, Robert Dean (Schenectady, NY); DeDoncker, Rik Wivina Anna Adelson (Malvern, PA)

1998-01-01T23:59:59.000Z

203

Power electronic interface circuits for batteries and ultracapacitors in electric vehicles and battery storage systems  

DOE Patents (OSTI)

A method and apparatus for load leveling of a battery in an electrical power system includes a power regulator coupled to transfer power between a load and a DC link, a battery coupled to the DC link through a first DC-to-DC converter and an auxiliary passive energy storage device coupled to the DC link through a second DC-to-DC converter. The battery is coupled to the passive energy storage device through a unidirectional conducting device whereby the battery can supply power to the DC link through each of the first and second converters when battery voltage exceeds voltage on the passive storage device. When the load comprises a motor capable of operating in a regenerative mode, the converters are adapted for transferring power to the battery and passive storage device. In this form, resistance can be coupled in circuit with the second DC-to-DC converter to dissipate excess regenerative power. 8 figs.

King, R.D.; DeDoncker, R.W.A.A.

1998-01-20T23:59:59.000Z

204

Battery technology for electric and hybrid vehicles: Expert views about prospects for advancement  

SciTech Connect

In this paper we present the results of an expert elicitation on the prospects for advances in battery technology for electric and hybrid vehicles. We find disagreement among the experts on a wide range of topics, including the need for government funding, the probability of getting batteries with Lithium Metal anodes to work, and the probability of building safe Lithium-ion batteries. Averaging across experts we find that U.S. government expenditures of $150 M/year lead to a 66% chance of achieving a battery that costs less than $200/kWh, and a 20% chance for a cost of $90/kWh or less. Reducing the cost of batteries from a baseline of $384 to $200 could lead to a savings in the cost of reducing greenhouse gases of about $100 billion in 2050.

Baker, Erin D.; Chon, Haewon; Keisler, Jeffrey M.

2010-09-01T23:59:59.000Z

205

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

206

Feasibility study for the recycling of nickel metal hydride electric vehicle batteries. Final report  

DOE Green Energy (OSTI)

This feasibility study examined three possible recycling processes for two compositions (AB{sub 2} and AB{sub 5}) of nickel metal hydride electric vehicle batteries to determine possible rotes for recovering battery materials. Analysts examined the processes, estimated the costs for capital equipment and operation, and estimated the value of the reclaimed material. They examined the following three processes: (1) a chemical process that leached battery powders using hydrochloric acid, (2) a pyrometallurical process, and (3) a physical separation/chemical process. The economic analysis revealed that the physical separation/chemical process generated the most revenue.

Sabatini, J.C.; Field, E.L.; Wu, I.C.; Cox, M.R.; Barnett, B.M.; Coleman, J.T. [Little (Arthur D.), Inc., Cambridge, MA (United States)

1994-01-01T23:59:59.000Z

207

Novel Battery Testing Procedures and Analytical Methodologies for Hybrid Electric Vehicles  

SciTech Connect

The Idaho National Engineering and Environmental Laboratory has developed novel testing procedures and analytical methodologies to assess the performance of batteries for use in hybrid electric vehicles. Tests include both characterization and cycle life and/or calendar life. Tests have been designed for both Power Assist and Dual Mode applications. Analytical procedures include a battery scaling methodology, the calculation of pulse resistance, pulse power, available energy, and differential capacitance, and the modeling of calendar and cycle life data. At periodic intervals during life testing, a series of Reference Performance Tests are executed to determine changes in the baseline performance of the batteries.

Motloch, Chester George; Batt, J. R.; Christophersen, Jon Petter; Wright, Randy Ben; Hunt, Gary Lynn

2001-06-01T23:59:59.000Z

208

National program plan for electric vehicle battery research and development  

SciTech Connect

EVs offer the prospect of reducing US petroleum fuel usage and air pollution in major metropolitan areas. In 1987, DOE-EHP commissioned a two-phase study at INEL to produce a national plan for R D on battery technology -- the limiting component in EVs. The battery assessment phase identified the most-promising'' technologies from a comprehensive list of viable EV batteries. This multi-year R D program plan identifies development schedules, milestones, and tasks directed at resolving the critical technical and economic issues for the most-promising developmental batteries: bipolar lead/acid, flow-through lead/acid, iron/air, lithium/iron sulfide, nickel/iron, sodium/metal chloride, sodium/sulfur, zinc/air, and zinc/bromine. 8 refs., 1 fig., 6 tabs.

Henriksen, G.L.; Douglas, D.L.; Warde, C.J. (EG and G Idaho, Inc., Idaho Falls, ID (USA); Douglas (David L.), Inc., Bloomington, MN (USA); Warde Associates, Inc., Greensboro, NC (USA))

1989-08-01T23:59:59.000Z

209

A refuelable zinc/air battery for fleet electric vehicle propulsion  

SciTech Connect

We report the development and on-vehicle testing of an engineering prototype zinc/air battery. The battery is refueled by periodic exchange of spent electrolyte for zinc particles entrained in fresh electrolyte. The technology is intended to provide a capability for nearly continuous vehicle operation, using the fleet s home base for 10 minute refuelings and zinc recycling instead of commercial infrastructure. In the battery, the zinc fuel particles are stored in hoppers, from which they are gravity fed into individual cells and completely consumed during discharge. A six-celled (7V) engineering prototype battery was combined with a 6 V lead/acid battery to form a parallel hybrid unit, which was tested in series with the 216 V battery of an electric shuttle bus over a 75 mile circuit. The battery has an energy density of 140 Wh/kg and a mass density of 1.5 kg/L. Cost, energy efficiency, and alternative hybrid configurations are discussed.

Cooper, J.F.; Fleming, D.; Hargrove, D.; Koopman, R.; Peterman, K.

1995-04-20T23:59:59.000Z

210

Design and Study on the State of Charge Estimation for Lithium-ion Battery Pack in Electric Vehicle  

Science Conference Proceedings (OSTI)

State of charge (SOC) estimation is an increasingly important issue in battery management system (BMS) and has become a core factor to promote the development of electric vehicle (EV). In addition to offering the real time display of battery parameters ... Keywords: combination algorithm, state of charge (SOC), open circuit voltage (OCV), extended Kalman filtering (EKF), ampere hour (Ah), battery management system (BMS), electric vehicle (EV)

Jie Xu; Mingyu Gao; Zhiwei He; Jianbin Yao; Hongfeng Xu

2009-11-01T23:59:59.000Z

211

The lithium-ion battery industry for electric vehicles.  

E-Print Network (OSTI)

??Electric vehicles have reemerged as a viable alternative means of transportation, driven by energy security concerns, pressures to mitigate climate change, and soaring energy demand.… (more)

Kassatly, Sherif (Sherif Nabil)

2010-01-01T23:59:59.000Z

212

U.S.-China Electric Vehicle and Battery Technology Workshop ...  

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

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...

213

U.S. - China Electric Vehicle and Battery Technology Workshop  

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

Center, Argonne National Lab TCS Building and Conference Center United States Flag China flag U.S. - China Electric Vehicle Technology Workshop August 30 - September 1, 2010...

214

Proof-of-concept zinc/bromine electric vehicle battery  

SciTech Connect

At the inception of the contract, Johnson Controls acquired and tested the zinc/bromine battery design developed by Exxon Research and Engineering Corporation (the Z-design) and, with Exxon, determined the key problems in this design: expansion and warping of electrodes, leaking of electrolyte from the battery stack, and excessive self-discharge brought about by transfer of bromine across the separator. The problems of electrode expansion and high self-discharge were mitigated by developing improved electrode and separator materials. Starting in the second year of the contract, JCI developed a new V-design battery stack which used different hardware and tooling to address the problem of stack leakage. The V-design uses thermal welding to achieve a hermetically sealed construction. The flow distribution is improved, and the massive endblocks of the original system have been replaced by thinner, lighter endblocks which are stiffened by means of rigid aluminum honeycomb inserts. Highlights of performance characteristics of batteries built and tested under the contract given. The battery was developed for the ETX-II, a Ford Aerostar minivan. 44 figs., 21 tabs.

Bolsted, J.; Eidler, P.; Miles, R.; Petersen, R.; Yaccarino, K. (Johnson Controls, Inc., Milwaukee, WI (USA). Advanced Battery Engineering); Lott, S. (Sandia National Labs., Albuquerque, NM (USA))

1991-04-01T23:59:59.000Z

215

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

216

Safety and environmental aspects of zinc--chlorine hydrate batteries for electric-vehicle applications  

DOE Green Energy (OSTI)

Public acceptance of high-performance cost-effective zinc--chlorine hydrate batteries for the random-use electric-vehicle application will require meeting stringent safety and environmental requirements. These requirements revolve mainly around the question of accidental release and spread of toxic amounts of chlorine gas, the only potential hazard in this battery system. Available information in the areas of physiological effects, environmental impact, and governmental regulation of chlorine were reviewed. The design, operation, and safety features of a first commercial electric-vehicle battery were conceived and analyzed from the chlorine release aspect. Two types of accident scenarios were analyzed in terms of chlorine release rates, atmospheric dispersion, health hazard, and possible clean-up operations. The worst-case scenario, a quite improbable accident, involves the spillage of chlorine hydrate onto the ground, while the other scenario, a more probable accident, involves the release of chlorine gas from a ruptured battery case. Heat-transfer and chlorine-dispersion models, developed to analyze these scenarios, establish a firm basis for a comprehenive and factual position statement on this topic. The results of this preliminary study suggest that electric vehicles powered by appropriately designed zinc--chlorine hydrate batteries will pose negligible health or environmental hazards on the nation's streets and highways. 8 figures, 14 tables.

Kodali, S.; Henriksen, G.L.; Whittlesey, C.C.; Warde, C.J.; Carr, P.; Symons, P.C.

1978-03-01T23:59:59.000Z

217

Test Protocol for System Compatibility of Single-Phase Battery Chargers for Electric Vehicles (SC-320)  

Science Conference Proceedings (OSTI)

This document defines procedures for performing comparisons of 240 V, single-phase residential battery chargers suitable for charging electric vehicles. The protocol describes methods for evaluating the charging characteristics, response to supply-side voltage variations, effects on supply-side power quality, and protection features of these charging devices.

1997-02-03T23:59:59.000Z

218

Test Protocol for System Compatibility of Three-Phase Battery Chargers for Electric Vehicles (SC-330)  

Science Conference Proceedings (OSTI)

This document defines procedures for performing comparisons of 480 V, three-phase battery chargers suitable for charging electric vehicles (EVs). The protocol describes methods for evaluating the charging characteristics, response to supply-side voltage variations, effects on supply-side power quality, and protection features of these charging devices.

1997-02-03T23:59:59.000Z

219

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

220

Method and apparatus for controlling battery charging in a hybrid electric vehicle  

DOE Green Energy (OSTI)

A starter/alternator system (24) for hybrid electric vehicle (10) having an internal combustion engine (12) and an energy storage device (34) has a controller (30) coupled to the starter/alternator (26). The controller (30) has a state of charge manager (40) that monitors the state of charge of the energy storage device. The controller has eight battery state-of-charge threshold values that determine the hybrid operating mode of the hybrid electric vehicle. The value of the battery state-of-charge relative to the threshold values is a factor in the determination of the hybrid mode, for example; regenerative braking, charging, battery bleed, boost. The starter/alternator may be operated as a generator or a motor, depending upon the mode.

Phillips, Anthony Mark (Northville, MI); Blankenship, John Richard (Dearborn, MI); Bailey, Kathleen Ellen (Dearborn, MI); Jankovic, Miroslava (Birmingham, MI)

2003-06-24T23:59:59.000Z

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

Comparison of Plug-In Hybrid Electric Vehicle Battery Life Across Geographies and Drive-Cycles  

DOE Green Energy (OSTI)

In a laboratory environment, it is cost prohibitive to run automotive battery aging experiments across a wide range of possible ambient environment, drive cycle and charging scenarios. Since worst-case scenarios drive the conservative sizing of electric-drive vehicle batteries, it is useful to understand how and why those scenarios arise and what design or control actions might be taken to mitigate them. In an effort to explore this problem, this paper applies a semi-empirical life model of the graphite/nickel-cobalt-aluminum lithium-ion chemistry to investigate impacts of geographic environments under storage and simplified cycling conditions. The model is then applied to analyze complex cycling conditions, using battery charge/discharge profiles generated from simulations of PHEV10 and PHEV40 vehicles across 782 single-day driving cycles taken from Texas travel survey data.

Smith, K.; Warleywine, M.; Wood, E.; Neubauer, J.; Pesaran, A.

2012-06-01T23:59:59.000Z

222

Research, development, and demonstration of nickel-iron batteries for electric vehicle propulsion. Annual report, 1980  

DOE Green Energy (OSTI)

The objective of the Eagle-Picher nickel-iron battery program is to develop a nickel-iron battery for use in the propulsion of electric and electric-hybrid vehicles. To date, the program has concentrated on the characterization, fabrication and testing of the required electrodes, the fabrication and testing of full-scale cells, and finally, the fabrication and testing of full-scale (270 AH) six (6) volt modules. Electrodes of the final configuration have now exceeded 1880 cycles and are showing minimal capacity decline. Full-scale cells have presently exceeded 600 cycles and are tracking the individual electrode tests almost identically. Six volt module tests have exceeded 500 cycles, with a specific energy of 48 Wh/kg. Results to date indicate the nickel-iron battery is beginning to demonstrate the performance required for electric vehicle propulsion.

Not Available

1981-03-01T23:59:59.000Z

223

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles. Volume 2, Battery recycling and disposal  

SciTech Connect

Recycling and disposal of spent sodium-sulfur (Na/S) batteries are important issues that must be addressed as part of the commercialization process of Na/S battery-powered electric vehicles. The use of Na/S batteries in electric vehicles will result in significant environmental benefits, and the disposal of spent batteries should not detract from those benefits. In the United States, waste disposal is regulated under the Resource Conservation and Recovery Act (RCRA). Understanding these regulations will help in selecting recycling and disposal processes for Na/S batteries that are environmentally acceptable and cost effective. Treatment processes for spent Na/S battery wastes are in the beginning stages of development, so a final evaluation of the impact of RCRA regulations on these treatment processes is not possible. The objectives of tills report on battery recycling and disposal are as follows: Provide an overview of RCRA regulations and requirements as they apply to Na/S battery recycling and disposal so that battery developers can understand what is required of them to comply with these regulations; Analyze existing RCRA regulations for recycling and disposal and anticipated trends in these regulations and perform a preliminary regulatory analysis for potential battery disposal and recycling processes. This report assumes that long-term Na/S battery disposal processes will be capable of handling large quantities of spent batteries. The term disposal includes treatment processes that may incorporate recycling of battery constituents. The environmental regulations analyzed in this report are limited to US regulations. This report gives an overview of RCRA and discusses RCRA regulations governing Na/S battery disposal and a preliminary regulatory analysis for Na/S battery disposal.

Corbus, D.

1992-09-01T23:59:59.000Z

224

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

225

Long-Range Electric Vehicle Batteries: High Energy Density Lithium Batteries  

SciTech Connect

Broad Funding Opportunity Announcement Project: In a battery, metal ions move between the electrodes through the electrolyte in order to store energy. Envia Systems is developing new silicon-based negative electrode materials for Li-Ion batteries. Using this technology, Envia will be able to produce commercial EV batteries that outperform today’s technology by 2-3 times. Many other programs have attempted to make anode materials based on silicon, but have not been able to produce materials that can withstand charge/discharge cycles multiple times. Envia has been able to make this material which can successfully cycle hundreds of times, on a scale that is economically viable. Today, Envia’s batteries exhibit world-record energy densities.

None

2010-01-01T23:59:59.000Z

226

Plug-In Hybrid Electric Vehicles - PHEV and HEV Batteries  

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

Argonne is a major player in the Department of Energy's (DOE's) plug-in hybrid electric vehicle (PHEV) energy storage research and development (R&D) program. DOE has...

227

Status of improved lead-acid, nickel/iron, and nickel/zinc batteries being developed under DOE's electric vehicle battery program  

SciTech Connect

The significant progress achieved in each of the three battery systems since the initiation of this battery development program is described. The 1982 demonstrated accomplishments are verified test results obtained on multicell modules (typically three to six cells each) at NBTL through May 1982. In particular, significant technical progress has been made in extending battery life. Additional progress in cell development and battery subsystem design (chargers, watering systems, electrolyte management systems) has allowed the construction of full-size battery packs. Globe Battery Division (lead-acid), Westinghouse (nickel/iron), and Eagle-Picher (nickel/iron) delivered full-size batteries to the Jet Propulsion Laboratory (JPL) for in-vehicle testing and evaluation.

Miller, J.F.; Rajan, J.B.; Hornstra, F.; Christianson, C.C.; Yao, N.P.

1982-01-01T23:59:59.000Z

228

The ANL electric vehicle battery R D program for DOE-EHP  

DOE Green Energy (OSTI)

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE's Electric and Hybrid Propulsion Division (DOE-EBP). The goal of DOE-EHP is to advance promising EV propulsion technologies to levels where industry will continue their commercial development and thereby significantly reduce petroleum consumption in the transportation sector of the US economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R D contracts on advanced battery and fuel cell technologies for DOE-EBP. This report summarizes the objectives, background, technical progress, and status of ANL electric vehicle battery R D tasks for DOE-EHP during the period of October 1, 1990 through December 31, 1990. The work is organized into the following six task areas: 1.0 Project Management; 3.0 Battery Systems Technology; 4.0 Lithium/Sulfide Batteries; 5.0 Advanced Sodium/Metal Chloride Battery; 6.0 Aqueous Batteries; 7.0 EV Battery Performance/Life Evaluation.

Not Available

1990-01-01T23:59:59.000Z

229

The ANL electric vehicle battery R D program for DOE-EHP  

SciTech Connect

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE's Electric and Hybrid Propulsion Division (DOE-EBP). The goal of DOE-EHP is to advance promising EV propulsion technologies to levels where industry will continue their commercial development and thereby significantly reduce petroleum consumption in the transportation sector of the US economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R D contracts on advanced battery and fuel cell technologies for DOE-EBP. This report summarizes the objectives, background, technical progress, and status of ANL electric vehicle battery R D tasks for DOE-EHP during the period of October 1, 1990 through December 31, 1990. The work is organized into the following six task areas: 1.0 Project Management; 3.0 Battery Systems Technology; 4.0 Lithium/Sulfide Batteries; 5.0 Advanced Sodium/Metal Chloride Battery; 6.0 Aqueous Batteries; 7.0 EV Battery Performance/Life Evaluation.

1990-01-01T23:59:59.000Z

230

High-temperature sodium nickel chloride battery for electric vehicles  

DOE Green Energy (OSTI)

Although the sodium-nickel chloride cell couple has a high voltage (2.59 V) and a high specific energy (790 Wh/kg), the performance of present incarnations of this battery tend to be limited by their power. Because the nickel chloride electrode dominates the resistance and weight of the cell, research on this cell couple at Argonne National Laboratory (ANL) has been primarily directed toward improving both the specific power and energy of the NiCl{sub 2} electrodes. During the course of these investigations a major breakthrough was achieved in lowering the impedance and increasing the usable capacity through the use of chemical additives and a tailored electrode morphology. This improved Ni/NiCl{sub 2} electrode has excellent performance characteristics, wide-temperature operation and fast recharge capability. Modeling studies done on this electrode indicate that a fully developed Na/NiCl{sub 2} battery based on ANL-single tube and bipolar designs would surpass the mid-term and approach the long-term goals of the US Advanced Battery Consortium.

Prakash, J.; Redey, L.; Nelson, P.A.; Vissers, D.R. [Argonne National Lab., IL (United States). Electrotechnical Technology Program

1996-07-01T23:59:59.000Z

231

ANL's electric vehicle battery activities for USABC. [US Advanced Battery Consortium (USABC)  

DOE Green Energy (OSTI)

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides advanced battery R D; technology transfer to industry; technical analyses, assessments, modeling, and databases; and independent testing and post-test analyses of advanced batteries. These capabilities and services are being offered to the US Advanced Battery Consortium (USABC) and Cooperative Research and Development Agreements (CRADA) are being negotiated for USABC-sponsored work at ANL. A small portion of DOE's cost share for USABC projects has been provided to ANL to continue R D and testing activities on key technologies that were previously supported directly by DOE. This report summarizes progress on these USABC projects during the period of April I through September 30, 1992. In this report, the objective, background, technical progress, and status are described for each task. The work is organized into the following task areas: 1.0 Lithium/Sulfide Batteries; 2.0 Nickel/Metal Hydride Support 3.0 EV Battery Performance and Life Evaluation.

Not Available

1992-01-01T23:59:59.000Z

232

ANL's electric vehicle battery activities for USABC. [US Advanced Battery Consortium (USABC)  

SciTech Connect

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides advanced battery R D; technology transfer to industry; technical analyses, assessments, modeling, and databases; and independent testing and post-test analyses of advanced batteries. These capabilities and services are being offered to the US Advanced Battery Consortium (USABC) and Cooperative Research and Development Agreements (CRADA) are being negotiated for USABC-sponsored work at ANL. A small portion of DOE's cost share for USABC projects has been provided to ANL to continue R D and testing activities on key technologies that were previously supported directly by DOE. This report summarizes progress on these USABC projects during the period of April I through September 30, 1992. In this report, the objective, background, technical progress, and status are described for each task. The work is organized into the following task areas: 1.0 Lithium/Sulfide Batteries; 2.0 Nickel/Metal Hydride Support 3.0 EV Battery Performance and Life Evaluation.

1992-01-01T23:59:59.000Z

233

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

such as cycle life and battery cost and battery managementnot dominate the total battery cost. Note that in generalsuch as cycle life and battery cost and battery management

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

234

The Potential of Plug-in Hybrid and Battery Electric Vehicles as Grid Resources: the Case of a Gas and Petroleum Oriented Elecricity Generation System  

E-Print Network (OSTI)

Ferdowsi, M. (2007). Plug-hybrid vehicles – A vision for thepower: battery, hybrid and fuel cell vehicles as resources2010). Plug-in hybrid electric vehicles as regulating power

Greer, Mark R

2012-01-01T23:59:59.000Z

235

The Potential of Plug-in Hybrid and Battery Electric Vehicles as Grid Resources: the Case of a Gas and Petroleum Oriented Elecricity Generation System  

E-Print Network (OSTI)

2010). Plug-in hybrid electric vehicles as regulating powervalue of plug-in hybrid electric vehicles as grid resources.of using plug-in hybrid electric vehicle battery packs for

Greer, Mark R

2012-01-01T23:59:59.000Z

236

Preliminary evaluation of regulatory and safety issues for sodium-sulfur batteries in electric vehicle applications  

DOE Green Energy (OSTI)

The US Department of Energy (DOE) Electric and Hybrid Vehicle Program is involved in the development and evaluation of sodium-sulfur energy storage batteries for electric vehicle (EV) applications. Laboratory testing of complete battery systems, to be followed by controlled in-vehicle testing and on-road usage, are expected to occur as components of the DOE program during the 1988--1990 time frame. Testing and operation of sodium-sulfur batteries at other DOE contractor facilities may also take place during this time frame. A number of regulatory and safety issues can affect the technical scope, schedule, and cost of the expected programmatic activities. This document describes these issues and requirements, provides a preliminary evaluation of their significance, and lists those critical items that may result from them. The actions needed to permit the conduct of a successful program at DOE contractor facilities are identified, and concerns that could affect the eventual commercialization potential of sodium-sulfur batteries are noted to the extent they are known.

Evans, D.R.; Henriksen, G.L.; Hunt, G.L.

1987-05-01T23:59:59.000Z

237

Battery Ownership Model: A Tool for Evaluating the Economics of Electrified Vehicles and Related Infrastructure (Presentation)  

DOE Green Energy (OSTI)

This presentation uses a vehicle simulator and economics model called the Battery Ownership Model to examine the levelized cost per mile of conventional (CV) and hybrid electric vehicles (HEVs) in comparison with the cost to operate an electric vehicle (EV) under a service provider business model. The service provider is assumed to provide EV infrastructure such as charge points and swap stations to allow an EV with a 100-mile range to operate with driving profiles equivalent to CVs and HEVs. Battery cost, fuel price forecast, battery life, and other variables are examined to determine under what scenarios the levelized cost of an EV with a service provider can approach that of a CV. Scenarios in both the United States as an average and Hawaii are examined. The levelized cost of operating an EV with a service provider under average U.S. conditions is approximately twice the cost of operating a small CV. If battery cost and life can be improved, in this study the cost of an EV drops to under 1.5 times the cost of a CV for U.S. average conditions. In Hawaii, the same EV is only slightly more expensive to operate than a CV.

O'Keefe, M.; Brooker, A.; Johnson, C.; Mendelsohn, M.; Neubauer, J.; Pesaran, A.

2010-11-01T23:59:59.000Z

238

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles  

DOE Green Energy (OSTI)

This report examines the shipping regulations that govern the shipment of dangerous goods. Since the elemental sodium contained in both sodium-sulfur and sodium-metal-chloride batteries is classified as a dangerous good, and is listed on both the national and international hazardous materials listings, both national and international regulatory processes are considered in this report The interrelationships as well as the differences between the two processes are highlighted. It is important to note that the transport regulatory processes examined in this report are reviewed within the context of assessing the necessary steps needed to provide for the domestic and international transport of sodium-beta batteries. The need for such an assessment was determined by the Shipping Sub-Working Group (SSWG) of the EV Battery Readiness Working Group (Working Group), created in 1990. The Working Group was created to examine the regulatory issues pertaining to in-vehicle safety, shipping, and recycling of sodium-sulfur batteries, each of which is addressed by a sub-working group. The mission of the SSWG is to establish basic provisions that will ensure the safe and efficient transport of sodium-beta batteries. To support that end, a proposal to the UN Committee of Experts was prepared by the SSWG, with the goal of obtaining a proper shipping name and UN number for sodium-beta batteries and to establish the basic transport requirements for such batteries (see the appendix for the proposal as submitted). It is emphasized that because batteries are large articles containing elemental sodium and, in some cases, sulfur, there is no existing UN entry under which they can be classified and for which modal transport requirements, such as the use of packaging appropriate for such large articles, are provided for. It is for this reason that a specific UN entry for sodium-beta batteries is considered essential.

Hammel, C.J.

1992-09-01T23:59:59.000Z

239

Current status of environmental, health, and safety issues of lithium polymer electric vehicle batteries  

DOE Green Energy (OSTI)

Lithium solid polymer electrolyte (SPE) batteries are being investigated by researchers worldwide as a possible energy source for future electric vehicles (EVs). One of the main reasons for interest in lithium SPE battery systems is the potential safety features they offer as compared to lithium battery systems using inorganic and organic liquid electrolytes. However, the development of lithium SPE batteries is still in its infancy, and the technology is not envisioned to be ready for commercialization for several years. Because the research and development (R&D) of lithium SPE battery technology is of a highly competitive nature, with many companies both in the United States and abroad pursuing R&D efforts, much of the information concerning specific developments of lithium SPE battery technology is proprietary. This report is based on information available only through the open literature (i.e., information available through library searches). Furthermore, whereas R&D activities for lithium SPE cells have focused on a number of different chemistries, for both electrodes and electrolytes, this report examines the general environmental, health, and safety (EH&S) issues common to many lithium SPE chemistries. However, EH&S issues for specific lithium SPE cell chemistries are discussed when sufficient information exists. Although lithium batteries that do not have a SPE are also being considered for EV applications, this report focuses only on those lithium battery technologies that utilize the SPE technology. The lithium SPE battery technologies considered in this report may contain metallic lithium or nonmetallic lithium compounds (e.g., lithium intercalated carbons) in the negative electrode.

Corbus, D.; Hammel, C.J.

1995-02-01T23:59:59.000Z

240

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,

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

The ANL electric vehicle battery R D program for DOE-EHP  

DOE Green Energy (OSTI)

The Electrochemical Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE's Electric and Hybrid Propulsion Division (DOE-EHP). The goal of DOE-EHP is to advance promising electric-vehicle (EV) propulsion technologies to levels where industry will continue their commercial development and thereby. significantly reduce petroleum consumption in the transportation sector of the economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R D contracts on advanced battery and fuel cell technologies for DOE-EHP. This report summarizes the battery-related activities undertaken during the period of October 1, 1991 through March 31, 1992. In this report, the objective, background, technical progress, and status are described for each task. These tasks are structured into the following task areas: 1.0 Project Management and Coordination; 2.0 Lithium/Sulfide Batteries; 3.0 Advanced Sodium/Beta Batteries; 4.0 Advanced Ambient-Temperature Batteries; 5.0 EV Battery Performance and Life Evaluation.

Not Available

1992-01-01T23:59:59.000Z

242

Tools for Designing Thermal Management of Batteries in Electric Drive Vehicles (Presentation)  

DOE Green Energy (OSTI)

Temperature has a significant impact on life, performance, and safety of lithium-ion battery technology, which is expected to be the energy storage of choice for electric drive vehicles (xEVs). High temperatures degrade Li-ion cells faster while low temperatures reduce power and energy capabilities that could have cost, reliability, range, or drivability implications. Thermal management of battery packs in xEVs is essential to keep the cells in the desired temperature range and also reduce cell-to-cell temperature variations, both of which impact life and performance. The value that the battery thermal management system provides in reducing battery life and improving performance outweighs its additional cost and complexity. Tools that are essential for thermal management of batteries are infrared thermal imaging, isothermal calorimetry, thermal conductivity meter and computer-aided thermal analysis design software. This presentation provides details of these tools that NREL has used and we believe are needed to design right-sized battery thermal management systems.

Pesaran, A.; Keyser, M.; Kim, G. H.; Santhanagopalan, S.; Smith, K.

2013-02-01T23:59:59.000Z

243

The ANL electric vehicle battery R D program for DOE-EHP  

SciTech Connect

The Electrochemical Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE's Electric and Hybrid Propulsion Division (DOE-EHP). The goal of DOE-EHP is to advance promising electric-vehicle (EV) propulsion technologies to levels where industry will continue their commercial development and thereby. significantly reduce petroleum consumption in the transportation sector of the economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R D contracts on advanced battery and fuel cell technologies for DOE-EHP. This report summarizes the battery-related activities undertaken during the period of October 1, 1991 through March 31, 1992. In this report, the objective, background, technical progress, and status are described for each task. These tasks are structured into the following task areas: 1.0 Project Management and Coordination; 2.0 Lithium/Sulfide Batteries; 3.0 Advanced Sodium/Beta Batteries; 4.0 Advanced Ambient-Temperature Batteries; 5.0 EV Battery Performance and Life Evaluation.

1992-01-01T23:59:59.000Z

244

Ford/DOE sodium-sulfur battery electric vehicle development and demonstration. Phase I-1. Final report  

DOE Green Energy (OSTI)

The results of Phase I-A analyses and design studies are presented. The objective of the Phase I-A effort was to evaluate the sodium-sulfur battery, in an existing conventional production automobile, as a potential power source for an electric vehicle. The Phase I-A work was divided into five (5) major sub-tasks as follows: vehicle specification sub-task; NaS battery packaging study sub-task; vehicle packaging layout sub-task; electrical system study sub-task; and system study sub-tasks covering performance and economy projections, powertrain and vehicle safety issues and thermal studies. The major results of the sodium-sulfur battery powered electric vehicle study program are: the Fiesta was chosen to be the production vehicle which would be modified into a 2-passenger, electric test bed vehicle powered by a NaS battery; the vehicle mission was defined to be a 2-passenger urban/suburban commuter vehicle capable of at least 100 miles range over the CVS driving cycle and a wide open throttle capability of 0 to 50 mph in 14 seconds, or less; powertrain component specifications were defined; powertrain control strategy has been selected; and a suitable test bed vehicle package scheme has been developed.

Not Available

1979-01-01T23:59:59.000Z

245

Integration Issues of Cells into Battery Packs for Plug-in and Hybrid Electric Vehicles: Preprint  

DOE Green Energy (OSTI)

The main barriers to increased market share of hybrid electric vehicles (HEVs) and commercialization of plug-in HEVs are the cost, safety, and life of lithium ion batteries. Significant effort is being directed to address these issues for lithium ion cells. However, even the best cells may not perform as well when integrated into packs for vehicles because of the environment in which vehicles operate. This paper discusses mechanical, electrical, and thermal integration issues and vehicle interface issues that could impact the cost, life, and safety of the system. It also compares the advantages and disadvantages of using many small cells versus a few large cells and using prismatic cells versus cylindrical cells.

Pesaran, A. A.; Kim, G. H.; Keyser, M.

2009-05-01T23:59:59.000Z

246

In-Vehicle Testing and Computer Modeling of Electric Vehicle Batteries  

E-Print Network (OSTI)

] .......................................................................................................... 8 1.1.4 Separator .......................................................................................... 12 1.1.6.2 VRLA batteries.................................................................................... 105 3.6 ANALYZING EVOLUTION OF SEPARATED STATES OF CHARGE OF NEGATIVE AND POSITIVE ELECTRODES USING

Wang, Chao-Yang

247

Research, development and demonstration of nickel-zinc batteries for electric vehicle propulsion. Annual report for 1978  

DOE Green Energy (OSTI)

This is the first annual report describing progress in the 33-month cooperative program between Argonne National Laboratory and Gould Inc.'s Nickel-Zinc/Electric Vehicle Project. The purpose of the program is to demonstrate the technical and economic feasibility of the nickel-zinc battery for electric vehicle propulsion. The successful completion of the program will qualify the nickel-zinc battery for use in the Department of Energy's demonstration program under the auspices of Public Law 94-413.

Not Available

1979-10-01T23:59:59.000Z

248

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

249

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,

250

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

251

Development of near-term batteries for electric vehicles. Summary report, October 1977-September 1979  

DOE Green Energy (OSTI)

The status and results through FY 1979 on the Near-Term Electric Vehicle Battery Project of the Argonne National Laboratory are summarized. This project conducts R and D on lead-acid, nickel/zinc and nickel/iron batteries with the objective of achieving commercialization in electric vehicles in the 1980's. Key results of the R and D indicate major technology advancements and achievement of most of FY 1979 performance goals. In the lead-acid system the specific energy was increased from less than 30 Wh/kg to over 40 Wh/kg at the C/3 rate; the peak power density improved from 70 W/kg to over 110 W/kg at the 50% state of charge; and over 200 deep-discharge cycle life demonstrated. In the nickel/iron system a specific energy of 48 Wh/kg was achieved; a peak power of about 100 W/kg demonstrated and a life of 36 cycles obtained. In the nickel/zinc system, specific energies of up to 64 Wh/kg were shown; peak powers of 133 W/kg obtained; and a life of up to 120 cycles measured. Future R and D will emphasize increased cycle life for nickel/zinc batteries and increased cycle life and specific energy for lead-acid and nickel/iron batteries. Testing of 145 cells was completed by NBTL. Cell evaluation included a full set of performance tests plus the application of a simulated power profile equivalent to the power demands of an electric vehicle in stop-start urban driving. Simplified test profiles which approximate electric vehicle demands are also described.

Rajan, J.B. (comp.) [comp.

1980-06-01T23:59:59.000Z

252

Battery Electric Vehicles: Range Optimization and Diversification for the U.S. Drivers  

DOE Green Energy (OSTI)

Properly selecting the driving range is critical for accurately predicting the market acceptance and the resulting social benefits of BEVs. Analysis of transportation technology transition could be biased against battery electric vehicles (BEV) and mislead policy making, if BEVs are not represented with optimal ranges. This study proposes a coherent method to optimize the BEV driving range by minimizing the range-related cost, which is formulated as a function of range, battery cost, energy prices, charging frequency, access to backup vehicles, and the cost and refueling hassle of operating the backup vehicle. This method is implemented with a sample of 36,664 drivers, representing U.S. new car drivers, based on the 2009 National Household Travel Survey data. Key findings are: 1) Assuming the near term (2015) battery cost at $405/kWh, about 98% of the sampled drivers are predicted to prefer a range below 200 miles, and about 70% below 100 miles. The most popular 20-mile band of range is 57 to77 miles, unsurprisingly encompassing the Leaf s EPA-certified 73-mile range. With range limited to 4 or 7 discrete options, the majority are predicted to choose a range below 100 miles. 2) Found as a statistically robust rule of thumb, the BEV optimal range is approximately 0.6% of one s annual driving distance. 3) Reducing battery costs could motivate demand for larger range, but improving public charging may cause the opposite. 4) Using a single range to represent BEVs in analysis could significantly underestimate their competitiveness e.g. by $3226/vehicle if BEVs are represented with 73-mile range only or by $7404/BEV if with 150-mile range only. Range optimization and diversification into 4 or 7 range options reduce such analytical bias by 78% or 90%, respectively.

Lin, Zhenhong [ORNL

2012-01-01T23:59:59.000Z

253

An SCR inverter with an integral battery charger for electric vehicles  

SciTech Connect

A thyristor-based inverter/charger for use in electric passenger vehicles is described, and prototype charger test results are presented. A battery charger is included integral to the inverter by using a subset of the inverter power circuit components. The integral charger employs the inverter commutation components as a resonant ac/dc converter rated at 3.6 kW. The resulting charger provides electrical isolation between the vehicle propulsion battery and ac line and is capable of charging a 25kWh propulsion battery in 8 h from a 220-V ac line. Charger efficiency and power factor at an output power of 3.6 kW are 86 and 95 percent, respectively. The inverter, when operated with a matching polyphase ac induction motor and nominal 132-V propulsion battery, can provide a peak shaft power of 34 kW (45 hp) during motoring operation and 45 kW (60 hp) during regeneration. Thyristors are employed for the inverter power switching devices and are arranged in an input-commutated topology. This configuration requires only two thyristors to commutate the six main inverter thyristors. The combined ac inverter/charger package weighs 47 kg (103 lb).

Thimmesch, D.

1985-07-01T23:59:59.000Z

254

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

DOE Green Energy (OSTI)

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

255

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

E-Print Network (OSTI)

such as cycle life and battery cost and battery managementsuch as cycle life and battery cost and battery managementof the battery. The battery size and cost will vary markedly

Burke, Andrew

2009-01-01T23:59:59.000Z

256

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

DOE Green Energy (OSTI)

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

257

Large-Scale Electric-Vehicle Battery Systems: Long-Term . . .  

E-Print Network (OSTI)

We investigate long-term metal resource constraints for large-scale EV systems for nine types of batteries: Li-polymer(V), Li-ion(Mn, Ni and Co), NaNiCl, NiMH(AB 2 and AB 5 ), NiCd and PbA, containing seven potentially scarce metals/group of metals: lithium, nickel, cobalt, vanadium, cadmium, lead and rare-earth elements. As a basis for the analysis, we calculate EV fleet size potentials (FSP) from estimated materials requirements: metal intensities (kg/kWh) and battery energy capacities per vehicle (kWh/vehicle); and available materials: reserve base and the amount that corresponds to 100 years of mining at current rates. NiCd, Li-ion(Co) and PbA have the most limited FSP (reserve base) with 20--50 million, 200--500 million and 500--800 million vehicles, respectively. Li-ion(Mn), NaNiCl and Li-ion(Ni) have the least limited FSP (reserve base) with 3--8 billion, 3--5 billion and 2--4 billion vehicles, respectively. However, for several of the batteries, 100 years of mining at current rate is much more limiting. The FSP only indicate magnitudes and it is not hard to reach FSP values ten times lower with additional assumptions. Important factors regarding the potential for higher or lower FSP are discussed, both for materials requirements: materials intensity and energy storage capacity per vehicle; as well as for metals availability: stocks of available resources, constraints on annual mine production and competition for metals. 1.

Björn A. Andersson; Ingrid Råde

1999-01-01T23:59:59.000Z

258

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

E-Print Network (OSTI)

Cost-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 for plug-in hybrid electric vehicles as alternate methods to reduce gasoline consumption for cars, trucks

McGaughey, Alan

259

EVS24 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 1 Stavanger, Norway, May 13-16, 2009  

E-Print Network (OSTI)

, Norway, May 13-16, 2009 Site selection for electric cars of a car-sharing service Luminita Ion1 , T. Cucu, modeling, electric vehicle 1 Introduction Car-sharing is defined as a system which allows to eachEVS24 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 1 EVS24 Stavanger

Paris-Sud XI, Université de

260

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed Electric Power in California  

E-Print Network (OSTI)

32 B.1 Electrical power capacity: BatteryB.1 Electrical power capacity: Battery EDVs For the battery-and/or generation capacity of battery, hybrid and fuel cell

Kempton, Willett; Tomic, Jasna; Letendre, Steven; Brooks, Alec; Lipman, Timothy

2001-01-01T23:59:59.000Z

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.


261

Test Profile Development for the Evaluation of Battery Cycle Life for Plug-In Hybrid Electric Vehicles  

Science Conference Proceedings (OSTI)

EPRI and DaimlerChrysler have developed a plug-in hybrid electric vehicle (PHEV) concept for the DaimlerChrysler Sprinter Van in an effort to reduce the emissions, fuel consumption, and operating costs of the vehicle while maintaining equivalent or superior functionality and performance. This report describes the development of a test profile to evaluate the life cycle of the batteries for the PHEV vehicle.

2004-03-29T23:59:59.000Z

262

President Obama Announces $2.4 Billion in Grants to Accelerate the Manufacturing and Deployment of the Next Generation of U.S. Batteries and Electric Vehicles  

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

Recovery Act will fund 48 new advanced battery and electric drive components manufacturing and electric drive vehicle deployment projects in over 20 states

263

Compact, Interactive Electric Vehicle Charger: Gallium-Nitride Switch Technology for Bi-directional Battery-to-Grid Charger Applications  

SciTech Connect

ADEPT Project: HRL Laboratories is using gallium nitride (GaN) semiconductors to create battery chargers for electric vehicles (EVs) that are more compact and efficient than traditional EV chargers. Reducing the size and weight of the battery charger is important because it would help improve the overall performance of the EV. GaN semiconductors process electricity faster than the silicon semiconductors used in most conventional EV battery chargers. These high-speed semiconductors can be paired with lighter-weight electrical circuit components, which helps decrease the overall weight of the EV battery charger. HRL Laboratories is combining the performance advantages of GaN semiconductors with an innovative, interactive battery-to-grid energy distribution design. This design would support 2-way power flow, enabling EV battery chargers to not only draw energy from the power grid, but also store and feed energy back into it.

2010-10-01T23:59:59.000Z

264

Integral inverter/battery charger for use in electric vehicles. Final report  

SciTech Connect

The design and test results of a thyristor based inverter/charger are discussed. A battery charger is included integral to the inverter by using a subset of the inverter power circuit components. The resulting charger provides electrical isolation between the vehicle propulsion battery and ac line and is capable of charging a 25 kWh propulsion battery in 8 hours from a 220 volt ac line. The integral charger employs the inverter commutation components as a resonant ac/dc isolated converter rated at 3.6 kW. Charger efficiency and power factor at an output power of 3.6 kW are 86% and 95%, respectively. The inverter, when operated with a matching polyphase ac induction motor and nominal 132 volt propulsion battery, can provide a peak shaft power of 34 kW (45 hp) during motoring operation and 45 kW (60 hp) during regeneration. Thyristors are employed for the inverter power switching devices and are arranged in an input-commutated topology. This configuration requires only two thyristors to commutate the six main inverter thyristors. Inverter efficiency during motoring operation at motor shaft speeds above 450 rad/sec (4300 rpm) is 92 to 94% for output power levels above 11 KW (15 hp). The combined ac inverter/charger package weighs 47 kg (103 lbs).

Thimmesch, D.

1983-09-01T23:59:59.000Z

265

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

266

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

Science Conference Proceedings (OSTI)

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); Thallam, R.S. [Salt River Project, Phoenix, AZ (United States)

1997-10-01T23:59:59.000Z

267

Evaluation of a new type stable nickel-zinc battery for electric vehicle application. Final report  

SciTech Connect

This report describes discharge-recharge cycle testing of 14 nickel-zinc storage battery cells of a proprietary design. This testing was to obtain performance data on new types of stabilized nickel-zinc battery cells for possible electric vehicle applications. The test sample cells were manufactured by Electrochimica Corporation (ELCA) in two sizes (15 ampere-hours and 225 ampere-hours) with a total of seven different internal combinations. The cells completed up to 470 cycles when testing was halted due to funding limitations. Near the end of testing, the cells were providing 40% of nominal capacity when discharged to 1.2 volts and 58 to 73% when discharged in two steps to 1.0 volt.

Not Available

1985-07-26T23:59:59.000Z

268

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles. Volume 4, In-vehicle safety  

DOE Green Energy (OSTI)

This report is the last of four volumes that identify and assess the environmental, health, and safety issues that may affect the commercial-scale use of sodium-sulfur (Na/S) battery technology as the energy source in electric and hybrid vehicles. The reports 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 the in-vehicle safety issues of electric vehicles powered by Na/S batteries. The report is based on a review of the literature and on discussions with experts at DOE, national laboratories and agencies, and private industry. It has three major goals: (1) to identify the unique hazards associated with electric vehicle (EV) use; (2) to describe the existing standards, regulations, and guidelines that are or could be applicable to these hazards; and (3) to discuss the adequacy of the existing requirements in addressing the safety concerns of EVs.

Mark, J.

1992-11-01T23:59:59.000Z

269

User's guide to DIANE Version 2. 1: A microcomputer software package for modeling battery performance in electric vehicle applications  

DOE Green Energy (OSTI)

DIANE is an interactive microcomputer software package for the analysis of battery performance in electric vehicle (EV) applications. The principal objective of this software package is to enable the prediction of EV performance on the basis of laboratory test data for batteries. The model provides a second-by-second simulation of battery voltage and current for any specified velocity/time or power/time profile. The capability of the battery is modeled by an algorithm that relates the battery voltage to the withdrawn current, taking into account the effect of battery depth-of-discharge (DOD). Because of the lack of test data and other constraints, the current version of DIANE deals only with vehicles using fresh'' batteries with or without regenerative braking. Deterioration of battery capability due to aging can presently be simulated with user-input parameters accounting for an increase of effective internal resistance and/or a decrease of cell no-load voltage. DIANE 2.1 is written in FORTRAN language for use on IBM-compatible microcomputers. 7 refs.

Marr, W.W.; Walsh, W.J. (Argonne National Lab., IL (USA). Energy Systems Div.); Symons, P.C. (Electrochemical Engineering Consultants, Inc., Morgan Hill, CA (USA))

1990-06-01T23:59:59.000Z

270

Current status of environmental, health, and safety issues of lithium ion electric vehicle batteries  

DOE Green Energy (OSTI)

The lithium ion system considered in this report uses lithium intercalation compounds as both positive and negative electrodes and has an organic liquid electrolyte. Oxides of nickel, cobalt, and manganese are used in the positive electrode, and carbon is used in the negative electrode. This report presents health and safety issues, environmental issues, and shipping requirements for lithium ion electric vehicle (EV) batteries. A lithium-based electrochemical system can, in theory, achieve higher energy density than systems using other elements. The lithium ion system is less reactive and more reliable than present lithium metal systems and has possible performance advantages over some lithium solid polymer electrolyte batteries. However, the possibility of electrolyte spills could be a disadvantage of a liquid electrolyte system compared to a solid electrolyte. The lithium ion system is a developing technology, so there is some uncertainty regarding which materials will be used in an EV-sized battery. This report reviews the materials presented in the open literature within the context of health and safety issues, considering intrinsic material hazards, mitigation of material hazards, and safety testing. Some possible lithium ion battery materials are toxic, carcinogenic, or could undergo chemical reactions that produce hazardous heat or gases. Toxic materials include lithium compounds, nickel compounds, arsenic compounds, and dimethoxyethane. Carcinogenic materials include nickel compounds, arsenic compounds, and (possibly) cobalt compounds, copper, and polypropylene. Lithiated negative electrode materials could be reactive. However, because information about the exact compounds that will be used in future batteries is proprietary, ongoing research will determine which specific hazards will apply.

Vimmerstedt, L.J.; Ring, S.; Hammel, C.J.

1995-09-01T23:59:59.000Z

271

Power management strategy based on adaptive neuro-fuzzy inference system for fuel cell-battery hybrid vehicle  

Science Conference Proceedings (OSTI)

A power management strategy based on an adaptive neuro-fuzzy inference system is proposed to enhance the fuel economy of fuel cell-battery hybrid vehicle and increase the mileage of continuation of journey. The model of hybrid vehicle for fuel cell-battery structure is developed by electric vehicle simulation software advisor. The simulation results demonstrate that the proposed strategy can satisfy the power requirement of four standard drive cycles and achieve the power distribution between fuel cell system and battery. The comprehensive comparisons with a power tracking control strategy which is widely adopted in advisor verify that the proposed strategy has better validity in terms of fuel economy in four standard drive cycles. Hence

Qi Li; Weirong Chen; Shukui Liu; Zhiyu You; Shiyong Tao; Yankun Li

2012-01-01T23:59:59.000Z

272

Modeling the performance and cost of lithium-ion batteries for electric-drive vehicles.  

DOE Green Energy (OSTI)

This report details the Battery Performance and Cost model (BatPaC) developed at Argonne National Laboratory for lithium-ion battery packs used in automotive transportation. The model designs the battery for a specified power, energy, and type of vehicle battery. The cost of the designed battery is then calculated by accounting for every step in the lithium-ion battery manufacturing process. The assumed annual production level directly affects each process step. The total cost to the original equipment manufacturer calculated by the model includes the materials, manufacturing, and warranty costs for a battery produced in the year 2020 (in 2010 US$). At the time this report is written, this calculation is the only publically available model that performs a bottom-up lithium-ion battery design and cost calculation. Both the model and the report have been publically peer-reviewed by battery experts assembled by the U.S. Environmental Protection Agency. This report and accompanying model include changes made in response to the comments received during the peer-review. The purpose of the report is to document the equations and assumptions from which the model has been created. A user of the model will be able to recreate the calculations and perhaps more importantly, understand the driving forces for the results. Instructions for use and an illustration of model results are also presented. Almost every variable in the calculation may be changed by the user to represent a system different from the default values pre-entered into the program. The distinct advantage of using a bottom-up cost and design model is that the entire power-to-energy space may be traversed to examine the correlation between performance and cost. The BatPaC model accounts for the physical limitations of the electrochemical processes within the battery. Thus, unrealistic designs are penalized in energy density and cost, unlike cost models based on linear extrapolations. Additionally, the consequences on cost and energy density from changes in cell capacity, parallel cell groups, and manufacturing capabilities are easily assessed with the model. New proposed materials may also be examined to translate bench-scale values to the design of full-scale battery packs providing realistic energy densities and prices to the original equipment manufacturer. The model will be openly distributed to the public in the year 2011. Currently, the calculations are based in a Microsoft{reg_sign} Office Excel spreadsheet. Instructions are provided for use; however, the format is admittedly not user-friendly. A parallel development effort has created an alternate version based on a graphical user-interface that will be more intuitive to some users. The version that is more user-friendly should allow for wider adoption of the model.

Nelson, P. A.

2011-10-20T23:59:59.000Z

273

Battery technology for electric and hybrid vehicles: Expert viewsabout prospects for advancement. Under Review at Technological Forecasting and Social Change  

E-Print Network (OSTI)

In this paper we present the results of an expert elicitation on the prospects for advances in battery technology for electric and hybrid vehicles. We find disagreement among the experts on a wide range of topics, including the need for government funding, the probability of getting batteries with Lithium Metal anodes to work, and the probability of building safe Lithium-ion batteries. Averaging across experts we find that U.S. government expenditures of $150M/yr lead to a 66 % chance of achieving a battery that costs less than $200/kWh, and a 20 % chance for a cost of $90/kWh or less. Reducing the cost of batteries from a baseline of $384 to $200 could lead to a savings in the cost of reducing greenhouse gases of about $100 Billion in 2050.

Erin Baker; Jeffrey Keisler

2009-01-01T23:59:59.000Z

274

Research and development of advanced nickel-iron batteries for electric vehicle propulsion  

DOE Green Energy (OSTI)

The purpose of this program has been to develop and demonstrate an advanced nickel-iron battery suitable for use in electric vehicles. During the course of this contract various steps and modification have been taken to improve Nickel-Iron battery performance while reducing cost. Improvement of the nickel electrode through slurry formulations and substrate changes, as seen with the fiber electrode, were investigated. Processing parameters for impregnation and formation were also manipulated to improve efficiency. Impregnation saw the change of anode type from platinized titanium to the consumable nickel anode. Formation changes were also made allowing for doubled processing capabilities of positive electrodes, a savings in both time and money. A final design change involved the evolution of the NIF-200 from the NIF-220. This change permitted the use of 1.2 mm iron electrodes and maintained the necessary performance characteristics for electric vehicle propulsion. Emphasis on a pilot plant became the main focus during the late 1989--90 period. The pilot plant facility would be a culmination of the program providing the best product at the lowest price.

Not Available

1991-01-01T23:59:59.000Z

275

Promoting the Market for Plug-in Hybrid and Battery Electric Vehicles: Role of Recharge Availability  

Science Conference Proceedings (OSTI)

Much recent attention has been drawn to providing adequate recharge availability as a means to promote the battery electric vehicle (BEV) and plug-in hybrid electric vehicle (PHEV) market. The possible role of improved recharge availability in developing the BEV-PHEV market and the priorities that different charging options should receive from the government require better understanding. This study reviews the charging issue and conceptualizes it into three interactions between the charge network and the travel network. With travel data from 3,755 drivers in the National Household Travel Survey, this paper estimates the distribution among U.S. consumers of (a) PHEV fuel-saving benefits by different recharge availability improvements, (b) range anxiety by different BEV ranges, and (c) willingness to pay for workplace and public charging in addition to home recharging. With the Oak Ridge National Laboratory MA3T model, the impact of three recharge improvements is quantified by the resulting increase in BEV-PHEV sales. Compared with workplace and public recharging improvements, home recharging improvement appears to have a greater impact on BEV-PHEV sales. The impact of improved recharging availability is shown to be amplified by a faster reduction in battery cost.

Lin, Zhenhong [ORNL; Greene, David L [ORNL

2012-01-01T23:59:59.000Z

276

Battery Electric Vehicle Driving and Charging Behavior Observed Early in The EV Project  

DOE Green Energy (OSTI)

As concern about society's dependence on petroleum-based transportation fuels increases, many see plug-in electric vehicles (PEV) as enablers to diversifying transportation energy sources. These vehicles, which include plug-in hybrid electric vehicles (PHEV), range-extended electric vehicles (EREV), and battery electric vehicles (BEV), draw some or all of their power from electricity stored in batteries, which are charged by the electric grid. In order for PEVs to be accepted by the mass market, electric charging infrastructure must also be deployed. Charging infrastructure must be safe, convenient, and financially sustainable. Additionally, electric utilities must be able to manage PEV charging demand on the electric grid. In the Fall of 2009, a large scale PEV infrastructure demonstration was launched to deploy an unprecedented number of PEVs and charging infrastructure. This demonstration, called The EV Project, is led by Electric Transportation Engineering Corporation (eTec) and funded by the U.S. Department of Energy. eTec is partnering with Nissan North America to deploy up to 4,700 Nissan Leaf BEVs and 11,210 charging units in five market areas in Arizona, California, Oregon, Tennessee, and Washington. With the assistance of the Idaho National Laboratory, eTec will collect and analyze data to characterize vehicle consumer driving and charging behavior, evaluate the effectiveness of charging infrastructure, and understand the impact of PEV charging on the electric grid. Trials of various revenue systems for commercial and public charging infrastructure will also be conducted. The ultimate goal of The EV Project is to capture lessons learned to enable the mass deployment of PEVs. This paper is the first in a series of papers documenting the progress and findings of The EV Project. This paper describes key research objectives of The EV Project and establishes the project background, including lessons learned from previous infrastructure deployment and PEV demonstrations. One such previous study was a PHEV demonstration conducted by the U.S. Department of Energy's Advanced Vehicle Testing Activity (AVTA), led by the Idaho National Laboratory (INL). AVTA's PHEV demonstration involved over 250 vehicles in the United States, Canada, and Finland. This paper summarizes driving and charging behavior observed in that demonstration, including the distribution of distance driven between charging events, charging frequency, and resulting proportion of operation charge depleting mode. Charging demand relative to time of day and day of the week will also be shown. Conclusions from the PHEV demonstration will be given which highlight the need for expanded analysis in The EV Project. For example, the AVTA PHEV demonstration showed that in the absence of controlled charging by the vehicle owner or electric utility, the majority of vehicles were charged in the evening hours, coincident with typical utility peak demand. Given this baseline, The EV Project will demonstrate the effects of consumer charge control and grid-side charge management on electricity demand. This paper will outline further analyses which will be performed by eTec and INL to documenting driving and charging behavior of vehicles operated in a infrastructure-rich environment.

John Smart; Stephen Schey

2012-04-01T23:59:59.000Z

277

Environmental, health, and safety issues of sodium-sulfur batteries for electric and hybrid vehicles. Volume 3, Transport of sodium-sulfur and sodium-metal-chloride batteries  

DOE Green Energy (OSTI)

This report examines the shipping regulations that govern the shipment of dangerous goods. Since the elemental sodium contained in both sodium-sulfur and sodium-metal-chloride batteries is classified as a dangerous good, and is listed on both the national and international hazardous materials listings, both national and international regulatory processes are considered in this report The interrelationships as well as the differences between the two processes are highlighted. It is important to note that the transport regulatory processes examined in this report are reviewed within the context of assessing the necessary steps needed to provide for the domestic and international transport of sodium-beta batteries. The need for such an assessment was determined by the Shipping Sub-Working Group (SSWG) of the EV Battery Readiness Working Group (Working Group), created in 1990. The Working Group was created to examine the regulatory issues pertaining to in-vehicle safety, shipping, and recycling of sodium-sulfur batteries, each of which is addressed by a sub-working group. The mission of the SSWG is to establish basic provisions that will ensure the safe and efficient transport of sodium-beta batteries. To support that end, a proposal to the UN Committee of Experts was prepared by the SSWG, with the goal of obtaining a proper shipping name and UN number for sodium-beta batteries and to establish the basic transport requirements for such batteries (see the appendix for the proposal as submitted). It is emphasized that because batteries are large articles containing elemental sodium and, in some cases, sulfur, there is no existing UN entry under which they can be classified and for which modal transport requirements, such as the use of packaging appropriate for such large articles, are provided for. It is for this reason that a specific UN entry for sodium-beta batteries is considered essential.

Hammel, C.J.

1992-09-01T23:59:59.000Z

278

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed Electric Power in California  

E-Print Network (OSTI)

service company EV – Electric vehicle (used to refer to aHenriette Schøn of the Electric Vehicle Information CenterJason France of Electric Vehicle Infrastructure, and Mark

Kempton, Willett; Tomic, Jasna; Letendre, Steven; Brooks, Alec; Lipman, Timothy

2001-01-01T23:59:59.000Z

279

Advanced Vehicle Testing Activity - Hybrid Electric Vehicles  

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

Hyundai Sonata (4932) Battery Report 2010 Ultra-Battery Honda Civic Battery Report Some hybrid electric vehicles (HEVs) combine a conventional internal combustion engine (using...

280

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

DOE Green Energy (OSTI)

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

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

Electric Vehicles  

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

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.

282

Comparative costs of flexible package cells and rigid cells for lithium-ionhybrid electric vehicle batteries.  

DOE Green Energy (OSTI)

We conducted a design study to compare the manufacturing costs at a level of 100,000 hybrid vehicle batteries per year for flexible package (Flex) cells and for rigid aluminum container (Rigid) cells. Initially, the Rigid cells were considered to have welded closures and to be deep-drawn containers of about the same shape as the Flex cells. As the study progressed, the method of fabricating and sealing the Rigid cells was expanded to include lower cost options including double seaming and other mechanically fastened closures with polymer sealants. Both types of batteries were designed with positive electrodes containing Li(Ni{sub 1/3}Co{sub 1/3}Mn{sub 1/3})O{sub 2} and graphite negative electrodes. The use of a different combination of lithium-ion electrodes would have little effect on the difference in costs for the two types of cells. We found that 20-Ah cells could be designed with excellent performance and heat rejection capabilities for either type of cell. Many parts in the design of the Flex cells are identical or nearly identical to those of the Rigid Cell, so for these features there would be no difference in the cost of manufacturing the two types of batteries. We judged the performance, size and weight of the batteries to be sufficiently similar that the batteries would have the same value for their application. Some of the design features of the Flex cells were markedly different than those of the deep-drawn and welded Rigid cells and would result in significant cost savings. Fabrication and processing steps for which the Flex cells appear to have a cost advantage over these Rigid cells are (1) container fabrication and sealing, (2) terminal fabrication and sealing, and (3) intercell connections. The costs of providing cooling channels adjacent to the cells and for module and battery hardware appear to favor Rigid cell batteries slightly. Overall, Flex cell batteries appear to have an advantage of about $1.20-$3.70 per cell for a 25-kW Battery of 20 cells or about $24 to $74 per battery. Container experts assisted with this study, including a paid consultant and personnel at container manufacturing companies. Some of the companies are considering entering the business of manufacturing containers for hybrid vehicle battery manufacturers. For this reason they provided valuable guidance on overall approaches to reducing the costs of the cell containers. They have retained the description of some specific designs and procedures for future possible work with battery manufacturers, with whom they are now in contact. Through the guidance of these experts, we determined that a new type of container could be manufactured that would have the best features of performance and low cost of both the Rigid and Flex containers. For instance, the aluminum layer in a tri-layer sheet can be sufficiently thick to form a rigid container that can be fabricated in two halves, much like a Flex container, and mechanically joined at the edges for strength. In addition to the mechanical joint, this container can be sealed at the edges, much like a Flex container, by means of an inner polymer liner that can be heat-sealed or ultrasonically welded. The terminals can be flat strips of metal sealed into the top of the container as part of the edge sealing of the container, as for the Flex cell. Ridges can be stamped into one side of the container to provide cooling channels and the exterior layer of the container stock can be coated with a thin, electrically insulating, polymer layer. We expect this type of container will provide excellent sealing and durability and be less expensive than either the Flex or the Rigid container, which the study initially considered. A major cost for the original Rigid container is the welding required for sealing the container. However, the welding of the current collector tabs to the terminal piece may be even more complex and costly than welding the container. It is important, therefore, to develop an inexpensive procedure for attachment of the foils to the terminal pieces. A lower-cost procedure, such as

Nelson, P. A.; Jansen, A. N.

2006-11-28T23:59:59.000Z

283

Prospect of advanced lead-acid, nickel/iron and nickel/zinc batteries for electric vehicle applications  

SciTech Connect

Major progress has been achieved in the lead-acid, nickel/iron and nickel/zinc battery technology development since the initiation of the Near-Term EV Battery Project in 1978. Against the specific energy goal of 56 Wh/kg the demonstrated specific energies are 41 Wh/kg for the improved lead-acid batteries, 48 Wh/kg for the improved nickel/iron batteries, and 68 Wh/kg for the improved nickel/zinc batteries. These specific energy values would allow an ETV-1 vehicle to have an urban range of 80 miles in the case of the improved lead-acid batteries, 96 miles for the improved nickel/iron batteries, and 138 miles for the improved nickel/zinc batteries. All represent a significant improvement over the state-of-the-art lead-acid battery capability of about 30 Wh/kg with approximately a 51 mile urban range for the ETV-1 vehicle. The project goal for specific power of 104 W/kg for 30 seconds at a 50% depth of discharge has been achieved for all of the technologies with the improved lead-acid demonstrating 111 W/kg, the improved nickel/iron demonstrating 103 W/kg and the improved nickel/zinc demonstrating 131 W/kg. Again this is a significant improvement over the state-of-the-art lead-acid battery capability of 70 W/kg. Substantial progress has been made against the life cycle goal of 800 cycles as evidenced by the demonstrated lead-acid battery achievement of >295 cycles in ongoing tests, the nickel/iron demonstrated capability of >515 cycles in ongoing tests, and the nickel/zinc demonstrated capability of 179 cycles. Except for the nickel/zinc batteries, the demonstrated cycle life is better than the state-of-the-art lead-acid battery cycle life of about 250 cycles. Future program emphases will be on improving cycle life and further reductions in cost.

Yao, N.P.; Christianson, C.C.; Hornstra, F.

1981-01-01T23:59:59.000Z

284

Internal Resistance Identification in Vehicle Power Lithium-Ion Battery and Application in Lifetime Evaluation  

Science Conference Proceedings (OSTI)

According to the characteristic analysis of lithium-ion power battery, battery accelerate life test is carried out to obtain the relevant conclusions such as the changing trend of battery ohmic resistance in different conditions. Battery ohmic resistance ... Keywords: Lithium-ion battery, Internal resistance, Equivalent model, Lifetime evaluation

Xuezhe Wei; Bing Zhu; Wei Xu

2009-04-01T23:59:59.000Z

285

European battery market  

SciTech Connect

The electric battery industry in Europe is discussed. As in any other part of the world, battery activity in Europe is dependent on people, prosperity, car numbers, and vehicle design. The European battery industry is discussed from the following viewpoints: battery performance, car design, battery production, marketing of batteries, battery life, and technology changes.

1984-02-01T23:59:59.000Z

286

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

287

Failure modes in high-power lithium-ion batteries for use inhybrid electric vehicles  

DOE Green Energy (OSTI)

The Advanced Technology Development (ATD) Program seeks to aid the development of high-power lithium-ion batteries for hybrid electric vehicles. Nine 18650-size ATD baseline cells were tested under a variety of conditions. The cells consisted of a carbon anode, LiNi{sub 0.8}Co{sub 0.2}O{sub 2} cathode and DEC-EC-LiPF{sub 6} electrolyte, and they were engineered for high-power applications. Selected instrumental techniques such as synchrotron IR microscopy, Raman spectroscopy, scanning electron microscopy, atomic force microscopy, gas chromatography, etc. were used to characterize the anode, cathode, current collectors and electrolyte from these cells. The goal was to identify detrimental processes which lead to battery failure under a high-current cycling regime as well as during storage at elevated temperatures. The diagnostic results suggest that the following factors contribute to the cell power loss: (a) SEI deterioration and non-uniformity on the anode, (b) morphology changes, increase of impedance and phase separation on the cathode, (c) pitting corrosion on the cathode Al current collector, and (d) decomposition of the LiPF{sub 6} salt in the electrolyte at elevated temperature.

Kostecki, R.; Zhang, X.; Ross Jr., P.N.; Kong, F.; Sloop, S.; Kerr, J.B.; Striebel, K.; Cairns, E.; McLarnon, F.

2001-06-22T23:59:59.000Z

288

The ANL electric vehicle battery R&D program for DOE-EHP. Quarterly progress report, October--December 1990  

DOE Green Energy (OSTI)

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE`s Electric and Hybrid Propulsion Division (DOE-EBP). The goal of DOE-EHP is to advance promising EV propulsion technologies to levels where industry will continue their commercial development and thereby significantly reduce petroleum consumption in the transportation sector of the US economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R&D contracts on advanced battery and fuel cell technologies for DOE-EBP. This report summarizes the objectives, background, technical progress, and status of ANL electric vehicle battery R&D tasks for DOE-EHP during the period of October 1, 1990 through December 31, 1990. The work is organized into the following six task areas: 1.0 Project Management; 3.0 Battery Systems Technology; 4.0 Lithium/Sulfide Batteries; 5.0 Advanced Sodium/Metal Chloride Battery; 6.0 Aqueous Batteries; 7.0 EV Battery Performance/Life Evaluation.

Not Available

1990-12-31T23:59:59.000Z

289

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

E-Print Network (OSTI)

Miller, M. , Emerging Lithium-ion Battery Technologies forMid-size Full (1) Lithium-ion battery with an energy densitypresent study. The lithium-ion battery technology used for

Burke, Andrew

2009-01-01T23:59:59.000Z

290

An Analysis of the Retail and Lifecycle Cost of Battery-Powered Electric Vehicles  

E-Print Network (OSTI)

±metal hydride (NiMH) battery costs, several di€erent ``in other cases. The battery cost per mile is low in partstorage energy ± and hence battery cost ± required to supply

Delucchi, Mark; Lipman, Timothy

2001-01-01T23:59:59.000Z

291

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

E-Print Network (OSTI)

defined as when the battery capacity decreases by 20% fromdiscern a decrease in battery capacity (decrease in range)capacity. The test results, which are summarized in Table 7, indicate that both battery

Burke, Andrew

2009-01-01T23:59:59.000Z

292

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed Electric Power in California  

E-Print Network (OSTI)

to approximately 40 kW. The hybrid vehicles are of interestat $0.84/therm). The hybrid vehicles in motor-generator modegas reformer, and the hybrid vehicle. However, the simple

Kempton, Willett; Tomic, Jasna; Letendre, Steven; Brooks, Alec; Lipman, Timothy

2001-01-01T23:59:59.000Z

293

Optimum Performance of Direct Hydrogen Hybrid Fuel Cell Vehicles  

E-Print Network (OSTI)

in batteries, ultracapacitors, fuel cells and hybrid vehicleBattery, Hybrid and Fuel Cell Electric Vehicle SymposiumBattery, Hybrid and Fuel Cell Electric Vehicle Symposium

Zhao, Hengbing; Burke, Andy

2009-01-01T23:59:59.000Z

294

Battery Recycling  

Science Conference Proceedings (OSTI)

Mar 6, 2013 ... By the mid-1990's due to manufacturers changing the composition of ... for electric drive vehicles is dependent battery performance, cost, and ...

295

An Analysis of the Retail and Lifecycle Cost of Battery-Powered Electric Vehicles  

E-Print Network (OSTI)

1997. Electric and hybrid electric vehicles: a technology1998. An assessment of electric vehicle life cycle costs tothe bene®ts of electric vehicles. Union of Concerned

Delucchi, Mark; Lipman, Timothy

2001-01-01T23:59:59.000Z

296

The ANL electric vehicle battery R&D program for DOE-EHP. Progress report, October 1991--March 1992  

DOE Green Energy (OSTI)

The Electrochemical Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE`s Electric and Hybrid Propulsion Division (DOE-EHP). The goal of DOE-EHP is to advance promising electric-vehicle (EV) propulsion technologies to levels where industry will continue their commercial development and thereby. significantly reduce petroleum consumption in the transportation sector of the economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, database management, and technical management of industrial R&D contracts on advanced battery and fuel cell technologies for DOE-EHP. This report summarizes the battery-related activities undertaken during the period of October 1, 1991 through March 31, 1992. In this report, the objective, background, technical progress, and status are described for each task. These tasks are structured into the following task areas: 1.0 Project Management and Coordination; 2.0 Lithium/Sulfide Batteries; 3.0 Advanced Sodium/Beta Batteries; 4.0 Advanced Ambient-Temperature Batteries; 5.0 EV Battery Performance and Life Evaluation.

Not Available

1992-12-31T23:59:59.000Z

297

Assessing the Battery Cost at Which Plug-In Hybrid Medium-Duty Parcel Delivery Vehicles Become Cost-Effective  

DOE Green Energy (OSTI)

The National Renewable Energy Laboratory (NREL) validated diesel-conventional and diesel-hybrid medium-duty parcel delivery vehicle models to evaluate petroleum reductions and cost implications of hybrid and plug-in hybrid diesel variants. The hybrid and plug-in hybrid variants are run on a field data-derived design matrix to analyze the effect of drive cycle, distance, engine downsizing, battery replacements, and battery energy on fuel consumption and lifetime cost. For an array of diesel fuel costs, the battery cost per kilowatt-hour at which the hybridized configuration becomes cost-effective is calculated. This builds on a previous analysis that found the fuel savings from medium duty plug-in hybrids more than offset the vehicles' incremental price under future battery and fuel cost projections, but that they seldom did so under present day cost assumptions in the absence of purchase incentives. The results also highlight the importance of understanding the application's drive cycle specific daily distance and kinetic intensity.

Ramroth, L. A.; Gonder, J. D.; Brooker, A. D.

2013-04-01T23:59:59.000Z

298

Modeling temperature distribution in cylindrical lithium ion batteries for use in electric vehicle cooling system design  

E-Print Network (OSTI)

Recent advancements in lithium ion battery technology have made BEV's a more feasible alternative. However, some safety concerns still exist. While the energy density of lithium ion batteries has all but made them the ...

Jasinski, Samuel Anthony

2008-01-01T23:59:59.000Z

299

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

E-Print Network (OSTI)

carbonate Separator Cathode:Anode: e-e- Li++e-+C6LiC6 Li+ Lithium-ion battery e- Binder Conductive additives to as lithium batteries and the various chemistries that are the most promising for these applications. While Li-ion. The figure shows that lithium-ion (Li-ion) batteries are superior to nickel metal hydride (Ni-MH) batteries

300

Aluminum-Ion Battery to Transform Century Energy Storage  

vehicles to perform comparably to vehicles powered by petroleum-fueled internal combustion engines. ... ••Battery manufacturers

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

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

E-Print Network (OSTI)

for Plug-in Hybrid Electric Vehicles (PHEVs): Goals andE. , Plug-in Hybrid-Electric Vehicle Powertrain Design andUC Davis Plug-in Hybrid Electric Vehicle Research Center and

Burke, Andrew

2009-01-01T23:59:59.000Z

302

Lessons learned in acquiring new regulations for shipping advanced electric vehicle batteries  

DOE Green Energy (OSTI)

In 1990, the Electric and Hybrid Propulsion Division of the US Department of Energy established its ad hoc EV Battery Readiness Working Group to identify regulatory barriers to the commercialization of advanced EV battery technologies and facilitate the removal of these barriers. A Shipping Sub-Working Group (SSWG) was formed to address the regulatory issues associated with the domestic and international shipment of these new battery technologies. The SSWG invites major industrial developers of advanced battery technologies to join as members and work closely with appropriate domestic and international regulatory authorities to develop suitable regulations and procedures for the safe transport of these new battery technologies. This paper describes the domestic and international regulatory processes for the transport of dangerous goods; reviews the status of shipping regulations for sodium-beta and lithium batteries; and delineates the lessons learned to date in this process. The sodium-beta battery family was the first category of advanced EV batteries to be addressed by the SSWG. It includes both sodium/sulfur and sodium/metal chloride batteries. Their efforts led to the establishment of a UN number (UN 3292) in the UN Recommendations, for cold cells and batteries, and establishment of a US Department of Transportation general exemption (DOT-E-10917) covering cold and hot batteries, as well as cold cells. The lessons learned for sodium-beta batteries, over the period of 1990--94, are now being applied to the development of regulations for shipping a new generation of lithium battery technologies (lithium-polymer and lithium-aluminum/iron sulfide batteries).

Henriksen, G. [Argonne National Lab., IL (United States); Hammel, C. [National Renewable Energy Lab., Golden, CO (United States); Altemos, E.A. [Winston and Strawn, Washington, DC (United States)

1994-12-01T23:59:59.000Z

303

Results of electric vehicle safety issues survey: Conducted on behalf of ad hoc EV battery readiness working group in-vehicle safety sub-working group  

DOE Green Energy (OSTI)

This report documents the results of a survey conducted in the winter of 1994-1995 by the In-Vehicle Safety Sub-Working Group, a working subunit of the DOE-sponsored ad hoc EV Battery Readiness Working Group. The survey was intended to determine the opinions of a group of industry experts regarding the relative importance of a list of some 39 potential safety concerns, grouped into 8 broad areas related to electric vehicles and their battery systems. Participation in the survey was solicited from the members of the Battery Readiness Working Group, along with members of the SAE EV Battery Safety Issues Task Force and selected other knowledgeable individuals. Results of the survey questionnaire were compiled anonymously from the 38 individuals who submitted responses. For each of the issues, survey respondents ranked them as having high, medium or low importance in each of three areas: the severity of events involving this concern, the probability that such events will occur, and the likelihood that mitigating action for such events may be needed beyond normal practices. The accumulated responses from this ranking activity are tabulated, and the response totals are also provided by several subgroupings of respondents. Additionally, large numbers of written comments were provided by respondents, and these are summarized with numbers of responses indicated. A preliminary statistical analysis of the tabulated results was performed but did not provide a satisfactory ranking of the concerns and has not been included in this report. A list is provided of the 15 concerns which a majority of the respondents indicated could be of both medium-to-high severity and medium-to-high probability of occurrence. This list will be reviewed by the Safety Sub-Working Group to determine the status of actions being taken by industry or government to mitigate these concerns, and the likelihood that additional research, standards development or regulation may be warranted to address them.

Hunt, G.L.

1996-06-01T23:59:59.000Z

304

Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed Electric Power in California  

E-Print Network (OSTI)

efficiency of the electric power system. This opportunity isvehicles and of the electric power grid, yet analysts,cell vehicle generates electric power, but it's not hooked

Kempton, Willett; Tomic, Jasna; Letendre, Steven; Brooks, Alec; Lipman, Timothy

2001-01-01T23:59:59.000Z

305

Lithium-Ion Batteries: Possible Materials Issues  

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

Argonne, IL Abstract The transition to plug-in hybrid vehicles and possibly pure battery electric vehicles will depend on the successful development of lithium-ion batteries....

306

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

E-Print Network (OSTI)

in a battery to the battery’s maximum capacity. Total Energyversion of the battery, with total energy capacity of (0.057Mass Battery “Goals” kW Peak Power kWh Energy Capacity years

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

2008-01-01T23:59:59.000Z

307

A one-wire'' battery monitoring system with applications to on-board charging for electric vehicles  

DOE Green Energy (OSTI)

A novel on-board charge system which utilizes a One-Wire'' system for voltage monitoring is discussed and test results obtained using the system are presented. The system consists of a 20 kHz high frequency charger, an algorithm for charging lead-acid batteries with gelled electrolyte, such that gassing is avoided, the control system to implement this charge algorithm and a one-wire battery monitoring system to provide cell/module voltage information to the battery charge controller. Prototype elements of the system have been tested and the system was installed into an EVA Pacer electric vehicle. Charge tests are performed and data taken with the system installed. All elements of the system functioned properly under user conditions. In particular, the charger demonstrated good efficiency, near unity power factor and full programmability. The charge controller functioned reliably and without flaw. The one-wire monitoring system which permits monitoring of cell/module voltages in a battery pack without an extensive conventional wire harness has proven effective and voltage measurements have taken fast enough for control of charging. It was found that for the purpose of voltage monitoring under driving conditions, the system in its present form is too slow.

Nowak, D. (Alabama Univ., Huntsville, AL (USA). Kenneth E. Johnson Research Center)

1990-10-08T23:59:59.000Z

308

High-performance batteries for electric-vehicle propulsion and stationary energy storage. Progress report, October 1977--September 1978  

DOE Green Energy (OSTI)

The research, development, and management activities of the programs at Argonne National Laboratory (ANL) and at industrial subcontractors' laboratories on high-temperature batteries during the period October 1977--September 1978 are reported. These batteries are being developed for electric-vehicle propulsion and for stationary-energy-storage applications. The present cells, which operate at 400 to 500/sup 0/C, are of a vertically oriented, prismatic design with one or more inner positive electrodes of FeS or FeS/sub 2/, facing electrodes of lithium--aluminum alloy, and molten LiCl--KCl electrolyte. During this fiscal year, cell and battery development work continued at ANL, Eagle--Picher Industries, Inc., the Energy Systems Group of Rockwell International, and Gould Inc. Related work was also in progress at the Carborundum Co., General Motors Research Laboratories, and various other organizations. A major event was the initiation of a subcontract with Eagle--Picher Industries to develop, design, and fabricate a 40-kWh battery (Mark IA) for testing in an electric van. Conceptual design studies on a 100-MWh stationary-energy-storage module were conducted as a joint effort between ANL and Rockwell International. A significant technical advance was the development of multiplate cells, which are capable of higher performance than bicells. 89 figures, 57 tables.

Nelson, P.A.; Barney, D.L.; Steunenberg, R.K.

1978-11-01T23:59:59.000Z

309

High-performance batteries for electric-vehicle propulsion and stationary energy storage. Progress report, October 1977--September 1978  

SciTech Connect

The research, development, and management activities of the programs at Argonne National Laboratory (ANL) and at industrial subcontractors' laboratories on high-temperature batteries during the period October 1977--September 1978 are reported. These batteries are being developed for electric-vehicle propulsion and for stationary-energy-storage applications. The present cells, which operate at 400 to 500/sup 0/C, are of a vertically oriented, prismatic design with one or more inner positive electrodes of FeS or FeS/sub 2/, facing electrodes of lithium--aluminum alloy, and molten LiCl--KCl electrolyte. During this fiscal year, cell and battery development work continued at ANL, Eagle--Picher Industries, Inc., the Energy Systems Group of Rockwell International, and Gould Inc. Related work was also in progress at the Carborundum Co., General Motors Research Laboratories, and various other organizations. A major event was the initiation of a subcontract with Eagle--Picher Industries to develop, design, and fabricate a 40-kWh battery (Mark IA) for testing in an electric van. Conceptual design studies on a 100-MWh stationary-energy-storage module were conducted as a joint effort between ANL and Rockwell International. A significant technical advance was the development of multiplate cells, which are capable of higher performance than bicells. 89 figures, 57 tables.

Nelson, P.A.; Barney, D.L.; Steunenberg, R.K.

1978-11-01T23:59:59.000Z

310

Modeling temperature distribution in cylindrical lithium ion batteries for use in electric vehicle cooling system design.  

E-Print Network (OSTI)

??Recent advancements in lithium ion battery technology have made BEV's a more feasible alternative. However, some safety concerns still exist. While the energy density of… (more)

Jasinski, Samuel Anthony

2008-01-01T23:59:59.000Z

311

Nano-structured anode material for high-power battery system in electric vehicles.  

SciTech Connect

A new MSNP-LTO anode is developed to enable a high-power battery system that provides three times more power than any existing battery system. It shows excellent cycle life and low-temperature performance, and exhibits unmatched safety characteristics.

Amine, K.; Belharouak, I.; Chen, Z.; Taison, T.; Yumoto, H.; Ota, N.; Myung, S.-T.; Sun, Y.-K. (Chemical Sciences and Engineering Division); (Enerdel Lithium Power Systems); (Iwate Univ.); (Hanyang Univ.)

2010-07-27T23:59:59.000Z

312

Research, development and demonstration of nickel-zinc batteries for electric vehicle propulsion. Annual report, 1978  

DOE Green Energy (OSTI)

The work carried out under the Yardney Contract with ANL for R, D and D on nickel zinc batteries over the past year was directed in three major areas: (1) elucidating the failure modes of the nickel-zinc battery system; (2) improving performance of the system; and (3) effecting a cost reduction program. Progress on the three areas is reported. (TFD)

Not Available

1979-10-01T23:59:59.000Z

313

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

Electric Vehicle Symposium negative) being developed are known to have less favorable performance, but less concern regarding safety

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

314

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

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

vehicle types, configurations, and use strategies - Accounting for the added utility, battery wear, and infrastructure costs of range-extension techniques (battery swap, fast...

315

Research and development of advanced nickel-iron batteries for electric vehicle propulsion. Annual report, February 1990--January 1991  

DOE Green Energy (OSTI)

The purpose of this program has been to develop and demonstrate an advanced nickel-iron battery suitable for use in electric vehicles. During the course of this contract various steps and modification have been taken to improve Nickel-Iron battery performance while reducing cost. Improvement of the nickel electrode through slurry formulations and substrate changes, as seen with the fiber electrode, were investigated. Processing parameters for impregnation and formation were also manipulated to improve efficiency. Impregnation saw the change of anode type from platinized titanium to the consumable nickel anode. Formation changes were also made allowing for doubled processing capabilities of positive electrodes, a savings in both time and money. A final design change involved the evolution of the NIF-200 from the NIF-220. This change permitted the use of 1.2 mm iron electrodes and maintained the necessary performance characteristics for electric vehicle propulsion. Emphasis on a pilot plant became the main focus during the late 1989--90 period. The pilot plant facility would be a culmination of the program providing the best product at the lowest price.

Not Available

1991-12-31T23:59:59.000Z

316

The ANL electric vehicle battery R&D program for DOE-EHP. Progress report: January--March 1993  

SciTech Connect

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE`s Electric and Hybrid Propulsion Division (DOE-EHP). The goal of DOE-EHP is to advance promising electric-vehicle (EV) propulsion technologies to levels where industry will continue their commercial development and thereby significantly reduce air pollution and petroleum consumption due to the transportation sector of the economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, and project management on advanced battery technologies for DOE-EHP. This report summarizes the battery-related activities undertaken during the period of January 1, 1993 through March 31, 1993. In this report, the objective, background, technical progress, and status are described for each task. The work is organized into the following task areas: 1.0 Project Management; 2.0 Sodium/Metal Chloride R&D; 3.0 Microreference Electrodes for Lithium/Polymer Batteries.

1993-06-15T23:59:59.000Z

317

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

E-Print Network (OSTI)

technology is a lithium-ion battery using lithium titanateof lithium-ion batteries of various chemistries Batterylithium-ion batteries were 20-22 kg and in the zinc-air battery,

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

318

Metal-Air Electric Vehicle Battery: Sustainable, High-Energy Density, Low-Cost Electrochemical Energy Storage – Metal-Air Ionic Liquid (MAIL) Batteries  

SciTech Connect

Broad Funding Opportunity Announcement Project: ASU is developing a new class of metal-air batteries. Metal-air batteries are promising for future generations of EVs because they use oxygen from the air as one of the battery’s main reactants, reducing the weight of the battery and freeing up more space to devote to energy storage than Li-Ion batteries. ASU technology uses Zinc as the active metal in the battery because it is more abundant and affordable than imported lithium. Metal-air batteries have long been considered impractical for EV applications because the water-based electrolytes inside would decompose the battery interior after just a few uses. Overcoming this traditional limitation, ASU’s new battery system could be both cheaper and safer than today’s Li-Ion batteries, store from 4-5 times more energy, and be recharged over 2,500 times.

2009-12-21T23:59:59.000Z

319

Electric and hybrid vehicles charge efficiency tests of ESB EV-106 lead-acid batteries  

DOE Green Energy (OSTI)

Charge efficiencies were determined for ESB EV-106 lead-acid batteries by measurements made under widely differing conditions of temperature, charge procedure, and battery age. The measurements were used to optimize charge procedures and to evaluate the concept of a modified, coulometric state-of-charge indicator. Charge efficiency determinations were made by measuring gassing rates and oxygen fractions. A novel, positive displacement gas flow meter which proved to be both simple and highly accurate is described and illustrated.

Rowlette, J.J.

1981-01-15T23:59:59.000Z

320

Research, development and demonstration of lead-acid batteries for electric vehicle propulsion. Annual report, 1979  

DOE Green Energy (OSTI)

This report describes work performed from October 1, 1978 to September 30, 1979. The approach for development of both the Improved State-of-the-Art (ISOA) and Advanced lead-acid batteries is three pronged. This approach concentrates on simultaneous optimization of battery design, materials, and manufacturing processing. The 1979 fiscal year saw the achievement of significant progress in the program. Some of the major accomplishments of the year are outlined. 33 figures, 13 tables. (RWR)

Not Available

1980-06-01T23:59:59.000Z

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.


321

AVCEM: Advanced-Vehicle Cost and Energy Use Model  

E-Print Network (OSTI)

of the battery, according to the battery cost equations (seediscussion of battery cost above). There actually are twoin the amount and cost of fuel-storage, battery, vehicle

Delucchi, Mark

2005-01-01T23:59:59.000Z

322

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.

323

An Analysis of the Retail and Lifecycle Cost of Battery-Powered Electric Vehicles  

E-Print Network (OSTI)

vehicles: Social costs and bene®ts in France. TransportationTransportation Research Part D 6 (2001) 371±404 Table 5 The social cost

Delucchi, Mark; Lipman, Timothy

2001-01-01T23:59:59.000Z

324

Advanced Vehicle Testing Activity - Hybrid Electric Vehicles  

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

Hybrid Electric Vehicles What's New 2012 Hyundai Sonata (4932) Battery Report (PDF 574KB) 2010 Ultra-Battery Honda Civic Battery Report (PDF 614KB) 2013 Chevrolet Malibu Baseline...

325

Battery Thermal Management System Design Modeling (Presentation)  

DOE Green Energy (OSTI)

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

326

Optimum Performance of Direct Hydrogen Hybrid Fuel Cell Vehicles  

E-Print Network (OSTI)

batteries and ultracapacitors for electric vehicles. EVS24Battery, Hybrid and Fuel Cell Electric Vehicle Symposiumpublications on electric and hybrid vehicle technology and

Zhao, Hengbing; Burke, Andy

2009-01-01T23:59:59.000Z

327

ANL`s electric vehicle battery activities for USABC. Progress report, April--September 1992  

SciTech Connect

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides advanced battery R&D; technology transfer to industry; technical analyses, assessments, modeling, and databases; and independent testing and post-test analyses of advanced batteries. These capabilities and services are being offered to the US Advanced Battery Consortium (USABC) and Cooperative Research and Development Agreements (CRADA) are being negotiated for USABC-sponsored work at ANL. A small portion of DOE`s cost share for USABC projects has been provided to ANL to continue R&D and testing activities on key technologies that were previously supported directly by DOE. This report summarizes progress on these USABC projects during the period of April I through September 30, 1992. In this report, the objective, background, technical progress, and status are described for each task. The work is organized into the following task areas: 1.0 Lithium/Sulfide Batteries; 2.0 Nickel/Metal Hydride Support 3.0 EV Battery Performance and Life Evaluation.

1992-12-31T23:59:59.000Z

328

On charging equipment and batteries in plug-in vehicles: Present status  

Science Conference Proceedings (OSTI)

In 2005 Kempton and Tomic laid out a vision for V2G which presumed that use of V2G technology could provide a high revenue stream to early plug-in electric vehicles, enabling market penetration of relatively high cost early-to-market electric drive vehicles. ...

E. Rask; T. Bohn; K. Gallagher

2012-01-01T23:59:59.000Z

329

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

E-Print Network (OSTI)

detour? Presentation at SAE 2008 Hybrid Vehicle Technologiesdrive vehicles, including plug-in hybrid vehicles. -vi-including plug-in hybrid vehicles. 7.0 References Anderman,

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

2008-01-01T23:59:59.000Z

330

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

E-Print Network (OSTI)

vehicles was the Hybrid and Electric Vehicle Act of 1976.for Electric and Hybrid Electric Vehicle Applications,and Impacts of Hybrid Electric Vehicle Options EPRI, Palo

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

2008-01-01T23:59:59.000Z

331

Electricity Grid: Impacts of Plug-In Electric Vehicle Charging  

E-Print Network (OSTI)

hybrid electric vehicles (PHEVs) and battery electric vehicles (BEVs), are among the most promising of the advanced vehicle

Yang, Christopher; McCarthy, Ryan

2009-01-01T23:59:59.000Z

332

Vehicle Manufacturing Futures in Transportation Life-cycle Assessment  

E-Print Network (OSTI)

gasoline vehicles, hybrid electric vehicles, aircraft, high-Gasoline Vehicle (CGV), Hybrid Electric Vehicle (HEV),Plug-in Hybrid Electric Vehicle (PHEV), and Battery Electric

Chester, Mikhail; Horvath, Arpad

2011-01-01T23:59:59.000Z

333

Fuzzy Clustering Based Multi-model Support Vector Regression State of Charge Estimator for Lithium-ion Battery of Electric Vehicle  

Science Conference Proceedings (OSTI)

Based on fuzzy clustering and multi-model support vector regression, a novel lithium-ion battery state of charge (SOC) estimating model for electric vehicle is proposed. Fuzzy C-means and Subtractive clustering combined algorithm is employed to implement ...

Xiaosong Hu; Fengchun Sun

2009-08-01T23:59:59.000Z

334

An Analysis of the Retail and Lifecycle Cost of Battery-Powered Electric Vehicles  

E-Print Network (OSTI)

product of an assumed cost per kWh and the total number ofmethod assumes that the cost per kWh does not vary with thethis battery has a low cost per kWh, and relatively few kWh

Delucchi, Mark; Lipman, Timothy

2001-01-01T23:59:59.000Z

335

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

E-Print Network (OSTI)

in use for several months. While some failures simply result in the cells getting very hot, in extreme battery internal shorts occur, they tend to surface without warning and usually after the cell has been cases cells go into thermal runaway, igniting the device in which they are installed. The most

336

Performance Characteristics of Lithium-ion Batteries of Various Chemistries for Plug-in Hybrid Vehicles  

E-Print Network (OSTI)

design. Simulations of Prius plug-in hybrids were performedpresented for a plug-in Prius-type vehicle using differentchemistries Simulations of Prius plug-in hybrids have been

Burke, Andrew; Miller, Marshall

2009-01-01T23:59:59.000Z

337

Development of Low Cost Carbonaceous Materials for Anodes in Lithium-Ion Batteries for Electric and Hybrid Electric Vehicles  

DOE Green Energy (OSTI)

Final report on the US DOE CARAT program describes innovative R & D conducted by Superior Graphite Co., Chicago, IL, USA in cooperation with researchers from the Illinois Institute of Technology, and defines the proper type of carbon and a cost effective method for its production, as well as establishes a US based manufacturer for the application of anodes of the Lithium-Ion, Lithium polymer batteries of the Hybrid Electric and Pure Electric Vehicles. The three materials each representing a separate class of graphitic carbon, have been developed and released for field trials. They include natural purified flake graphite, purified vein graphite and a graphitized synthetic carbon. Screening of the available on the market materials, which will help fully utilize the graphite, has been carried out.

Barsukov, Igor V.

2002-12-10T23:59:59.000Z

338

The Evolution of Sustainable Personal Vehicles  

E-Print Network (OSTI)

of $200 - $400/kWh, the OEM battery cost would be $6,000 - $Battery Cost..74 Illustration 31: Battery cost as a function of vehicle

Jungers, Bryan D

2009-01-01T23:59:59.000Z

339

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

E-Print Network (OSTI)

cost. Third, lithium-ion (Li-Ion) battery designs are betterclass of advanced battery using lithium-ion chemistry. LMS –Li-Ion battery technologies as follows: LCO: Lithium cobalt

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

2008-01-01T23:59:59.000Z

340

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

E-Print Network (OSTI)

of “acceptability”. Targeted battery costs are $200-$300 persafety will increase battery cost. Table E-1: Comparing PHEVthis report. 3.5 Costs Battery cost is thought to be one of

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.


341

Laboratory-scale evaluation of secondary alkaline zinc batteries...  

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

Laboratory-scale evaluation of secondary alkaline zinc batteries for electric vehicles Title Laboratory-scale evaluation of secondary alkaline zinc batteries for electric vehicles...

342

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

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

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

343

Vehicles  

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

The U.S. Department of Energy (DOE) supports the development and deployment of advanced vehicle technologies, including advances in electric vehicles, engine efficiency, and lightweight materials....

344

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.

345

Demonstration of zinc/air fuel battery to enhance the range and mission of fleet electric vehicles: Preliminary results in the refueling of a multicell module  

DOE Green Energy (OSTI)

We report progress in an effort to develop and demonstrate a refuelable zinc/air battery for fleet electric vehicle applications. A refuelable module consisting of twelve bipolar cells with internal flow system has been refueled at rates of nearly 4 cells per minute refueling time of 10 minutes for a 15 kW, 55 kWh battery. The module is refueled by entrainment of 0.5-mm particles in rapidly flowing electrolyte, which delivers the particles into hoppers above each cell in a parallel-flow hydraulic circuit. The concept of user-recovery is presented as an alternative to centralized service infrastructure during market entry.

Cooper, J.F.; Fleming, D.; Keene, L.; Maimoni, A.; Peterman, K.; Koopman, R.

1994-08-08T23:59:59.000Z

346

High-performance batteries for electric-vehicle propulsion and stationary energy storage. Progress report, October 1978-March 1979. [Ca/sulfides  

DOE Green Energy (OSTI)

This report covers the research, development, and management activities of the programs at Argonne National Laboratory (ANL) and at subcontractors' laboratories on high-temperature batteries during the period October 1978 to March 1979. These batteries are being developed for electric-vehicle propulsion and for stationary energy-storage applications. The present cells, which operate at 400 to 500/sup 0/C, are of a vertically oriented, prismatic design with one or more inner positive electrodes of FeS or FeS/sub 2/, facing electrodes of lithium-aluminum alloy, and molten LiCl-KCl electrolyte. During this six-month period, cell and battery development work continued at ANL, Eagle-Picher Industries, Inc., Gould Inc., and the Energy Systems Group of Rockwell International. Fabrication of a 40-kWh battery by Eagle-Picher for testing in an electric van is nearing completion. Cost and design studies for a Mark II electric-vehicle battery, which will have somewhat higher performance and use potentially low-cost materials and fabrication methods, were conducted by all three subcontractors, and contracts are being negotiated for development of Mark II batteries. Conceptual design studies continued at Rockwell International on a 100 MWh stationary energy-storage module. The present plan is to construct a module based on these designs for testing at the BEST (Battery Energy Storage Test) Facility. Work was also in progress at the Carborundum Co., General Motors Research Laboratories, and various other organizations on developing materials and components for cells. 38 figures, 28 tables.

None

1979-05-01T23:59:59.000Z

347

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

E-Print Network (OSTI)

rd International Electric Vehicle Symposium and Exposition (Electric and Hybrid Electric Vehicle Applications, Sandiaand Impacts of Hybrid Electric Vehicle Options EPRI, Palo

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

2008-01-01T23:59:59.000Z

348

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

E-Print Network (OSTI)

Technology Power devices supercapacitor Activated 2320 11600Effectiveness of Battery-Supercapacitor Combination in

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

349

Energy Materials: Battery Technologies  

Science Conference Proceedings (OSTI)

... batteries of miniature electronic devices to large power source of electric vehicles. ... process developments on electrodes and separators and safety design.

350

Multilayer Graphene-Silicon Structures for Lithium Ion Battery ...  

Automotive industry: electric vehicles, hybrid electric vehicles; High performance lithium ion battery manufacturers; Aerospace industry, for lightweight power storage;

351

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

352

AVCEM: Advanced Vehicle Cost and Energy Use Model. Overview of AVCEM  

E-Print Network (OSTI)

of the battery, according to the battery cost equations (seediscussion of battery cost above). There actually are twoin the amount and cost of fuel-storage, battery, vehicle

Delucchi, Mark

2005-01-01T23:59:59.000Z

353

Battery Life Predictor Model - Energy Innovation Portal  

Energy Analysis Battery Life Predictor Model ... Technology Marketing Summary Batteries are one of the leading cost drivers of any electric vehicle ...

354

Advanced battery modeling using neural networks.  

E-Print Network (OSTI)

??Batteries have gained importance as power sources for electric vehicles. The main problem with the battery technology available today is that the design of the… (more)

Arikara, Muralidharan Pushpakam

2012-01-01T23:59:59.000Z

355

Nanofilm Coatings Improve Battery Performance - Energy Innovation ...  

Recent advances in battery technology are expected to more than double consumer demand for electric vehicles within the next five years. The lithium-ion battery is an ...

356

Myths Regarding Alternative Fuel Vehicle Demand by Light-Duty Vehicle Fleets  

E-Print Network (OSTI)

unlikely). For electric vehicles the primary safety concernsand safety issues of nickel metal-hydride batteries for electric vehicles.

Nesbitt, Kevin; Sperling, Daniel

1998-01-01T23:59:59.000Z

357

Electrochemical Capacitors as Energy Storage in Hybrid-Electric Vehicles: Present Status and Future Prospects  

E-Print Network (OSTI)

batteries and ultracapacitors for electric vehicles. EVS24Battery, Hybrid and Fuel Cell Electric Vehicle Symposiumpublications on electric and hybrid vehicle technology and

Burke, Andy; Miller, Marshall

2009-01-01T23:59:59.000Z

358

Research, development and demonstration of nickel-iron batteries for electric vehicle propulsion. Annual report, 1978  

DOE Green Energy (OSTI)

The program has advanced to the level of full-size, prototype cell fabrication and evaluation. EPP nickel electrodes are now being prepared of up to 24 Ah/plate (at C/3 drain rate) at design thickness (2.5 mm). Iron electrodes of the composite-type are delivering 24 Ah/plate (at C/3) at target thickness (1.0 mm). Both plates are displaying good capacity stability at 130 to 175 test cycles, respectively, in some of the 3 plate cell tests. Finished cells are delivering up to 58 Wh/Kg at C/3, based on projected weight of the finished cell and in the actual designed cell volume. Reduction in cell resistance, reduction in nickel plate processing time and swelling on cycling are areas of major effort to reach the final battery objectives. Thermal nickel electrodes are showing promise in full size plate tests (up to 22 Ah in a plate of only 2.3 mm thickness) and will be evaluated in finished cells as soon as the technology shows repeatable results in full-size test plates.

Not Available

1979-10-01T23:59:59.000Z

359

Development of high-specific-energy batteries for electric vehicles. Progress report, February 1973--July 1973  

DOE Green Energy (OSTI)

A high-specific-energy lithium/sulfur battery having the performance characteristics required for powering pollutionfree automobiles is described. The cells currently under development have negative electrodes of molten lithium and positive electrodes of sulfur (plus an additive to reduce the sulfur vapor pressure) separated by a molten lithium halide-containing electrolyte. The operating temperature of the cells is about 400 deg C. The performance goals for a single cell include a capacity density of 0.4 A-hr/cm/sup 2/ at a current density of 0.1 A/cm/sup 2/, a peak power density of 1-2 W/cm/sup 2/, and a minimum cycle life of 1000 cycles. Cells with positive electrodes consisting of sulfurarsenic-carbon mixtures in graphite housings have achieved short-time peak power densities and capacity densities that meet or exceed the goals for a single cell. A capacity density of 0.1 A-hr/cm/sup 2/ has been sustained at a discharge current density of 0.1 A/cm/sup 2/l (1-V cutoff) for more than 500 hr and 100 cycles. Improvement in cell design is needed, however, to achieve higher sulfur utilization and longer cell lifetimes. (auth)

Nelson, P.A.; Gay, E.C.; Steunenberg, R.K.; Battles, J.E.; Schertz, W.W.; Vissers, D.R.; Myles, K.M.; Kyle, M.L.; Webster, D.S.; Burris, L.

1973-12-01T23:59:59.000Z

360

Energizing the batteries for electric cars  

SciTech Connect

This article reports of the nickel-metal-hydride battery and its ability to compete with the lead-acid battery in electric-powered vehicles. The topics of the article include development of the battery, the impetus for development in California environmental law, battery performance, packaging for the battery's hazardous materials, and the solid electrolyte battery.

O' Connor, L.

1993-07-01T23:59:59.000Z

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.


361

Design and cost study of nickel--zinc batteries for electric vehicle. Final report. [24 kWh battery of 48 325-Ah cells, 35 Wh/lb  

DOE Green Energy (OSTI)

A battery module configuration consisting of four 325-Ah cells was selected. Twelve such modules would make up a 24-kWh battery. The key design parameter is operation current density. An energy density of 2.1 Wh/in./sup 3/ and 35 Wh/lb was obtained. A flow diagram was drawn for the manufacturing process. An eight-month period would be required to set up a pilot plant. The material requirements for 100,000 batteries per year would not have a significant impact on current U.S. consumption. 29 figures, 28 tables (RWR)

Klein, M; Dube, D

1976-10-01T23:59:59.000Z

362

Electric vehicle propulsion batteries: design and cost study for nickel/zinc battery manufacture. Task A. [25 kWh, 700 pounds, 245 Ah at 100+ V, 4. 77 ft/sup 3/  

DOE Green Energy (OSTI)

For satisfying the 25-kWh energy requirement necessary for vehicle propulsion, a 700-pound nickel--zinc battery was configured. Containing 64 individual cells, the unit was selected for minimum weight from computed packaging possibilities. Unit volume was projected to be 4.77 cubic feet. Capacity of the cells delivering 100+ volts was set at 245 ampere-hours. Selection was made primarily because of the compatibility with expressed vehicle requirements of a lower-current system. Manufacturing costs were computed for a unit using sintered positive electrodes at $86/kWh, pilot plant rate, and $78/kWh, production plant rate. Based on a lower than anticipated cost differential between sintered and nonsintered positive electrodes and certain other performance differences, the sintered electrode was chosen for the battery design. Capital expenditures for a production rate of 10,000 batteries per year are estimated to be $2,316,500. Capital expenditure for demonstrating production rates in a pilot plant facility is approximately $280,000, with the use of some shared available equipment. 29 figures, 9 tables.

None

1977-01-01T23:59:59.000Z

363

Solar Electrical Vehicles | Open Energy Information  

Open Energy Info (EERE)

California Zip 91361 Sector Solar, Vehicles Product US-based manufacturer of solar battery chargers for hybrid vehicles. References Solar Electrical Vehicles1 LinkedIn...

364

Hydrogen Fuel Cell Vehicles  

E-Print Network (OSTI)

Traction Battery for the ETX-II Vehicle, EGG-EP-9688, IdahoElectric Vehicle Powertrain (ETX-II) Performance: VehicleDevelopment Program - ETX-II, Phase II Technical Report, DOE

Delucchi, Mark

1992-01-01T23:59:59.000Z

365

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

E-Print Network (OSTI)

Gelder E. Plug-in Hybrid-Electric Vehicle Powertrain DesignIntegration for Hybrid Electric Vehicles, IEEE Transactionsmodels [1-3] of hybrid-electric vehicles using Advisor have

Burke, Andy; Zhao, Hengbing

2010-01-01T23:59:59.000Z

366

Effect of Temperature on Lithium-Iron Phosphate Battery Performance and Plug-in Hybrid Electric Vehicle Range.  

E-Print Network (OSTI)

??Increasing pressure from environmental, political and economic sources are driving the development of an electric vehicle powertrain. The advent of hybrid electric vehicles (HEVs), plug-in… (more)

Lo, Joshua

2013-01-01T23:59:59.000Z

367

Wanxiang Electric Vehicle Co Ltd | Open Energy Information  

Open Energy Info (EERE)

electric vehicles as well as the lithium polymer batteries, powertrain components, Battery Management Systems and electronic control components for those vehicles. Coordinates...

368

Choices and Requirements of Batteries for EVs, HEVs, PHEVs (Presentation)  

DOE Green Energy (OSTI)

This presentation describes the choices available and requirements for batteries for electric vehicles, hybrid electric vehicles, plug-in hybrid electric vehicles.

Pesaran, A. A.

2011-04-01T23:59:59.000Z

369

KATECH (Lithium Polymer) 4-Passenger NEV Range and Battery Testing...  

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

Vehicle Testing Activity (AVTA) received a Neighborhood Electric Vehicle (NEV) from the Korea Automotive Technology Institute (KATECH) for vehicle and battery characterization...

370

Applying the Battery Ownership Model in Pursuit of Optimal Battery Use Strategies (Presentation)  

DOE Green Energy (OSTI)

This Annual Merit Review presentation describes the application of the Battery Ownership Model for strategies for optimal battery use in electric drive vehicles (PEVs, PHEVs, and BEVs).

Neubauer, J.; Ahmad, P.; Brooker, A.; Wood, E.; Smith, K.; Johnson, C.; Mendelsohn, M.

2012-05-01T23:59:59.000Z

371

Advanced Vehicle Testing Activity - Full Size Electric Vehicles  

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

Full Size Electric Vehicles What's New Baseline Performance Testing for 2011 Nissan Leaf Battery Testing for 2011 Nissan Leaf - When New The Advanced Vehicle Testing Activity...

372

EVS 24 International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium 1 Stavanger, Norway, May 13-16, 2009  

E-Print Network (OSTI)

driver efficiency - increase mission safety margins - minimize vehicle emissions #12;VI Issues in the U safety. #12;Intelligent Vehicle Advanced Control Capabilities - The AVIP Paradigm (a System ofThe AVIPThe U.S. Army's VehicleThe U.S. Army's Vehicle Intelligence Program (AVIP):Intelligence Program

Senger, Ryan S.

373

Battery construction. [miniaturized batteries  

SciTech Connect

A description is given of a battery having a battery cup and a battery cap which has a ridge portion to provide a battery chamber for accommodating a positive electrode, a negative electrode, and an electrolyte. The battery chamber has a contour at its outer periphery different from that of the sealing flanges of the battery cup and the battery cap. 11 figures.

Nishimura, H.; Nomura, Y.

1977-05-24T23:59:59.000Z

374

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

E-Print Network (OSTI)

Targeted battery costs are $200-$300 per kWh. We note thatbattery cost is commonly measured in dollars per total kWh (

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

2008-01-01T23:59:59.000Z

375

Batteries - HEV Batteries  

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

and component levels. A very detailed battery design model is used to establish these costs for different Li-Ion battery chemistries. The battery design model considers the...

376

Lithium Ion Battery Aging Experiments and Algorithm Development for Life Estimation.  

E-Print Network (OSTI)

??Battery lifespan is one of the largest considerations when designing battery packs for electrified vehicles. Even during vehicle operation, it is essential to monitor the… (more)

Suttman, Alexander K.

2011-01-01T23:59:59.000Z

377

Current and future developments of batteries for electric cars - an analysis.  

E-Print Network (OSTI)

??To make battery electric vehicles (BEVs) energetically, environmentally and economically competitive to internal combustion engine vehicles (ICEVs), batteries play an important role. In this study,… (more)

Gondelach, S.J.

2010-01-01T23:59:59.000Z

378

Advanced Vehicle Testing Activity: Hybrid Electric Vehicles  

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

motor of an electric vehicle. Other hybrids combine a fuel cell with batteries to power electric propulsion motors. Fuel Cell Concept: Fuel passes through an anode, electrolyte,...

379

Advanced Vehicles Group: Center for Transportation Technologies and Systems  

DOE Green Energy (OSTI)

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

380

Vehicle Specifications  

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

E27C177982 Vehicle Specifications Engine: 2.5 L 4-cylinder Electric Motor: 105 kW Battery: NiMH Seatbelt Positions: Five Payload: 981 lbs Features: Regenerative braking Traction...

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

Vehicle Specifications  

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

E87C172351 Vehicle Specifications Engine: 2.5 L 4-cylinder Electric Motor: 105 kW Battery: NiMH Seatbelt Positions: Five Payload: 981 lbs Features: Regenerative braking Traction...

382

Vehicle Specifications  

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

Z07S838122 Vehicle Specifications Engine: 2.4 L 4 cylinder Electric Motor: 14.5 kW Battery: NiMH Seatbelt Positions: Five Payload: 1,244 lbs Features: Regenerative braking wABS 4...

383

Vehicle Specifications  

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

2AR194699 Vehicle Specifications Engine: 2.5 L 4-cylinder Electric Motor: 60 kW Battery: NiMH Seatbelt Positions: Five Payload: 850 lbs Features: Regenerative braking Traction...

384

Vehicle Specifications  

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

2WD VIN 1FMYU95H75KC45881 Vehicle Specifications Engine: 2.3 L 4-cylinder Electric Motor: 70 kW Battery: NiMH Seatbelt Positions: Five Features: Four wheel drive Regenerative...

385

Vehicle Specifications  

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

4AR144757 Vehicle Specifications Engine: 2.5 L 4-cylinder Electric Motor: 60 kW Battery: NiMH Seatbelt Positions: Five Payload: 850 lbs Features: Regenerative braking Traction...

386

Vehicle Specifications  

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

Z37S813344 Vehicle Specifications Engine: 2.4 L 4 cylinder Electric Motor: 14.5 kW Battery: NiMH Seatbelt Positions: Five Payload: 1,244 lbs Features: Regenerative braking wABS 4...

387

Vehicle Specifications  

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

4WD VIN 1FMCU96H15KE18237 Vehicle Specifications Engine: 2.4 L 4-cylinder Electric Motor: 70 kW Battery: NiMH Seatbelt Positions: Five Features: Four wheel drive Regenerative...

388

Impact of battery weight and charging patterns on the economic and environmental benefits of plug-in hybrid vehicles  

E-Print Network (OSTI)

incentives. The federal Qualified Plug-In Electric Drive Motor Vehicle Tax Credit is available for PEV. Advances in electric-drive technologies enabled commercializa- tion of hybrid electric vehicles (HEVs That Affect All-Electric and Hybrid Electric Vehicle Efficiency and Range section). The time required to fully

Michalek, Jeremy J.

389

Nanofilm Coatings Improve Battery Performance  

Recent advances in battery technology are expected to more than double consumer demand for electric vehicles within the next five years. The ...

390

Battery Testing in the US  

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

U.S.-China EV and Battery Workshop Joint Vehicle Demonstrations and Standards Development August 24, 2012 Session Chairmen: Keith Hardy, Argonne National Laboratory Li Jianqiu,...

391

The ANL electric vehicle battery R D program for DOE-EHP. [ANL (Argonne National Laboratory); EHP (Electric and Hybrid Propulsion Division)  

SciTech Connect

The Electrochemical Technology Program at Argonne National Laboratory (ANL) provides technical and programmatic support to DOE's Electric and Hybrid Propulsion Division (DOE-EHP). The goal of DOE-EHP is to advance promising electric-vehicle (EV) propulsion technologies to levels where industry will continue their commercial development and thereby significantly reduce air pollution and petroleum consumption due to the transportation sector of the economy. In support of this goal, ANL provides research, development, testing/evaluation, post-test analysis, modeling, and project management on advanced battery technologies for DOE-EHP. This report summarizes the battery-related activities undertaken during the period of January 1, 1993 through March 31, 1993. In this report, the objective, background, technical progress, and status are described for each task. The work is organized into the following task areas: 1.0 Project Management; 2.0 Sodium/Metal Chloride R D; 3.0 Microreference Electrodes for Lithium/Polymer Batteries.

1993-06-15T23:59:59.000Z

392

Implementation of electric vehicle system based on solar energy in Singapore assessment of flow batteries for energy storage  

E-Print Network (OSTI)

For large-scale energy storage application, flow battery has the advantages of decoupled power and energy management, extended life cycles and relatively low cost of unit energy output ($/kWh). In this thesis, an overview ...

Chen, Yaliang

2009-01-01T23:59:59.000Z

393

A Practical Circuit-based Model for State of Health Estimation of Li-ion Battery Cells in Electric Vehicles.  

E-Print Network (OSTI)

??In this thesis the development of the state of health of Li-ion battery cells under possible real-life operating conditions in electric cars has been characterised.… (more)

Lam, L.

2011-01-01T23:59:59.000Z

394

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

E-Print Network (OSTI)

5, Shirouzu, N. (2007). Toyota Puts Off New Type of Batteryof one battery, e.g. Toyota’s concerns about safety with itssuccess, typified by the Toyota Prius. Currently, interest

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

2008-01-01T23:59:59.000Z

395

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

E-Print Network (OSTI)

New Type of Battery for Next Prius, The Wall Street Journal,typified by the Toyota Prius. Currently, interest has turneda plug-in version of the Prius, General Motors is working

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

2008-01-01T23:59:59.000Z

396

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

397

PNGV battery test manual  

DOE Green Energy (OSTI)

This manual defines a series of tests to characterize aspects of the performance or life cycle behavior of batteries for hybrid electric vehicle applications. Tests are defined based on the Partnership for New Generation Vehicles (PNGV) program goals, although it is anticipated these tests may be generally useful for testing energy storage devices for hybrid electric vehicles. Separate test regimes are defined for laboratory cells, battery modules or full size cells, and complete battery systems. Some tests are common to all three test regimes, while others are not normally applicable to some regimes. The test regimes are treated separately because their corresponding development goals are somewhat different.

NONE

1997-07-01T23:59:59.000Z

398

Interactions between Electric-drive Vehicles and the Power Sector in California  

E-Print Network (OSTI)

vehicle demand. Plug-in hybrid vehicles are found to reduceto conventional hybrid vehicles is further considered inBattery, Hybrid and Fuel Cell Electric Vehicle Symposium

McCarthy, Ryan; Yang, Christopher; Ogden, Joan M.

2009-01-01T23:59:59.000Z

399

Modeling the Performance of Lithium-Ion Batteries and Capacitors...  

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

Modeling the Performance of Lithium-Ion Batteries and Capacitors during Hybird Electric-Vehicle Operation Title Modeling the Performance of Lithium-Ion Batteries and Capacitors...

400

Transformative Battery Technology at the National Labs | Department...  

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

for 300 miles. Lithium-sulfur and lithium-air are "unknown known" technologies for the future of electric vehicle batteries. At the Batteries for Advanced Transportation...

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

Available Technologies: Lower Cost Lithium Ion Batteries from ...  

Lower Cost Lithium Ion Batteries from ... Although lithium ion batteries are the most promising candidates for plug-in hybrid electric vehicles, the u ...

402

Electric Vehicle Manufacturing in Southern California: Current Developments, Future Prospects  

E-Print Network (OSTI)

the production of electric vehicle componentswill result an1992. "Hot Sales of Electric Vehicles." p. El. Sharpe, W. ,1992. "Battery and Electric Vehicle Update." September1992.

Scott, Allen J.

1993-01-01T23:59:59.000Z

403

Evaluation Of Potential Hybrid Electric Vehicle Applications: Vol I  

E-Print Network (OSTI)

Air Batteries for Electric Vehicles” E.J.Rudd. SAE 891660.the Soleq Evcort Electric Vehicle”. DOE/ID--10232. Preparedfor Fiscal Year 88, Electric Vehicle Program, February

Gris, Arturo E.

1991-01-01T23:59:59.000Z

404

Electric Vehicles: Performances, Life Cycle Costs, Emissions, and Recharging Requirements  

E-Print Network (OSTI)

Sealed lead-acid electric and vehicle battery development.A. (1987a) ture for electric vehicles. In Resources ElectricInternational Conference. Electric Vehicle De- Universityof

DeLuchi, Mark A.; Wang, Quanlu; Sperling, Daniel

1989-01-01T23:59:59.000Z

405

Evaluation Study for Large Prismatic Lithium-Ion Cell Designs Using Multi-Scale Multi-Dimensional Battery Model (Presentation)  

Science Conference Proceedings (OSTI)

Addresses battery requirements for electric vehicles using a model that evaluates physical-chemical processes in lithium-ion batteries, from atomic variations to vehicle interface controls.

Kim, G. H.; Smith, K.

2009-05-01T23:59:59.000Z

406

Hybrid Electric Vehicle Testing  

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

- 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) -...

407

Battery resource assessment. Interim report No. 1. Battery materials demand scenarios  

DOE Green Energy (OSTI)

Projections of demand for batteries and battery materials between 1980 and 2000 are presented. The estimates are based on existing predictions for the future of the electric vehicle, photovoltaic, utility load-leveling, and existing battery industry. Battery demand was first computed as kilowatt-hours of storage for various types of batteries. Using estimates for the materials required for each battery, the maximum demand that could be expected for each battery material was determined.

Sullivan, D.

1980-12-01T23:59:59.000Z

408

Internal Short Circuit Device Helps Improve Lithium-Ion Battery Design (Fact Sheet)  

DOE Green Energy (OSTI)

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

Not Available

2012-04-01T23:59:59.000Z

409

Nanofilm Coatings Improve Battery Performance  

demand for electric vehicles within the next five years. The lithium-ion battery is an attractive candidate for use in such vehicles because of its light weight and high energy density. At present, however, lithium-ion batteries are not ...

410

Alternative Fuels Vehicle Group | Open Energy Information  

Open Energy Info (EERE)

Product Focussed on news and information on natural gas, biofuel, battery-electric, hybrid and fuel cell vehicles. References Alternative Fuels Vehicle Group1 LinkedIn...

411

Technology Status and Expected Greenhouse Gas Emissions of Battery, Plug?In Hybrid, and Fuel Cell Electric Vehicles  

Science Conference Proceedings (OSTI)

Electric vehicles (EVs) of various types are experiencing a commercial renaissance but of uncertain ultimate success. Many new electric?drive models are being introduced by different automakers with significant technical improvements from earlier models

2011-01-01T23:59:59.000Z

412

The Potential of Plug-in Hybrid and Battery Electric Vehicles as Grid Resources: the Case of a Gas and Petroleum Oriented Elecricity Generation System  

E-Print Network (OSTI)

the battery depletion cost per kWh transferred could bethe battery depletion cost per kWh transferred from off-peakhigher battery depletion cost per kWh transferred under the

Greer, Mark R

2012-01-01T23:59:59.000Z

413

The Potential of Plug-in Hybrid and Battery Electric Vehicles as Grid Resources: the Case of a Gas and Petroleum Oriented Elecricity Generation System  

E-Print Network (OSTI)

the significant battery depletion costs incurred from deep-Consequently, the battery depletion cost per kWh transferredTo estimate the battery depletion cost of peak shaving, we

Greer, Mark R

2012-01-01T23:59:59.000Z

414

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

415

Electric vehicles  

SciTech Connect

Quiet, clean, and efficient, electric vehicles (EVs) may someday become a practical mode of transportation for the general public. Electric vehicles can provide many advantages for the nation's environment and energy supply because they run on electricity, which can be produced from many sources of energy such as coal, natural gas, uranium, and hydropower. These vehicles offer fuel versatility to the transportation sector, which depends almost solely on oil for its energy needs. Electric vehicles are any mode of transportation operated by a motor that receives electricity from a battery or fuel cell. EVs come in all shapes and sizes and may be used for different tasks. Some EVs are small and simple, such as golf carts and electric wheel chairs. Others are larger and more complex, such as automobile and vans. Some EVs, such as fork lifts, are used in industries. In this fact sheet, we will discuss mostly automobiles and vans. There are also variations on electric vehicles, such as hybrid vehicles and solar-powered vehicles. Hybrid vehicles use electricity as their primary source of energy, however, they also use a backup source of energy, such as gasoline, methanol or ethanol. Solar-powered vehicles are electric vehicles that use photovoltaic cells (cells that convert solar energy to electricity) rather than utility-supplied electricity to recharge the batteries. This paper discusses these concepts.

Not Available

1990-03-01T23:59:59.000Z

416

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

417

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  

DOE Green Energy (OSTI)

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

2011-01-01T23:59:59.000Z

418

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

419

Battery Types  

Science Conference Proceedings (OSTI)

...and rechargeable batteries (Table 1A battery consists of a negative electrode (anode) from which electrons

420

Advanced Lithium Ion Battery Technologies - Energy Innovation Portal  

The Berkeley Lab technology contributes to improved battery safety by circumventing lithium metal dendrite formation. Benefits. ... 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.


421

Myths Regarding Alternative Fuel Vehicle Demand by Light-Duty Vehicle Fleets  

E-Print Network (OSTI)

unlikely). For electric vehicles the primary safety concernsand safety issues of mckel C M metal-hydride batteries for electric vehicles

Nesbitt, Kevin; Sperling, Daniel

1998-01-01T23:59:59.000Z

422

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.

423

EERE: Vehicle Technologies Office - Energizing the Economy with...  

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

with Advanced Batteries Site Map Printable Version Share this resource Send a link to EERE: Vehicle Technologies Office - Energizing the Economy with Advanced Batteries to...

424

Alternative Fuels Data Center: Light-Duty Vehicle Search  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Electric (Dedicated) Class: Neighborhood Electric Vehicle Estimated Range: 30 city Battery: absorbed glass mat lead-acid (6 12-volt batteries) Engine: Brushless 3 phase...

425

Alternative Fuels Data Center: Light-Duty Vehicle Search  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Electric (Dedicated) Class: Neighborhood Electric Vehicle Estimated Range: 40 city Battery: Absorbed glass mat lead-acid (6 12-volt batteries) Dealer: Locate a dealer...

426

Alternative Fuels Data Center: Light-Duty Vehicle Search  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Electric (Dedicated) Class: Neighborhood Electric Vehicle Estimated Range: 40 city Battery: 9 8-volt gel batteries Engine: 7.0 hp motor Dealer: Locate a dealer Description: The...

427

Alternative Fuels Data Center: Light-Duty Vehicle Search  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Electric (Dedicated) Class: Neighborhood Electric Vehicle Estimated Range: 30 city Battery: 6 12-volt gel batteries Dealer: Locate a dealer Description: The GEM e6 has seating...

428

Electric and Hybrid Vehicle Program Site Operator Program Quarterly...  

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

vehicle range through both reduced battery capacity and increased accessory usage. q Battery pack life for a given type is not uniform and frequently much shorter than...

429

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

430

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

431

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

432

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

Doeff, Marca M

2010-07-12T23:59:59.000Z

433

Electrothermal Battery Pack Modeling and Simulation.  

E-Print Network (OSTI)

??Much attention as been given to the study of Li-Ion batteries for their use in automotive applications such as Hybrid Electric Vehicles (HEV), Plug In… (more)

Yurkovich, Benjamin J.

2010-01-01T23:59:59.000Z

434

Surface Modification Agents for Lithium Batteries  

Increased safety and life of lithium-ion batteries, ... Electric and plug-in hybrid electric vehicles; Portable electronic devices; Medical devices; and

435

Electric and Hybrid Vehicle Testing  

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

results. Generally, hotel loads while on charge in fleet use contributes to lower energy efficiencies. These hotel loads can include heating and cooling vehicle battery...

436

Interactions between Electric-drive Vehicles and the Power Sector in California  

E-Print Network (OSTI)

Battery, Hybrid and Fuel Cell Electric Vehicle SymposiumSystem. 23rd International Electric Vehicle Symposium andof Plug-In Hybrid Electric Vehicles, Volume 1: Nationwide

McCarthy, Ryan; Yang, Christopher; Ogden, Joan M.

2009-01-01T23:59:59.000Z

437

Electric and Gasoline Vehicle Lifecycle Cost and Energy-Use Model  

E-Print Network (OSTI)

Electric and Hybrid Electric Vehicles (Workshop Proceedings,J. Oros, President, Electric Vehicle Infrastructure, Inc. ,Hydride Batteries for Electric Vehicles,” presented at the

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

2000-01-01T23:59:59.000Z

438

Electric Vehicles: Performance, Life-Cycle Costs, Emissions, and Recharging Requirements  

E-Print Network (OSTI)

Sealed lead-acid electric and vehicle battery development.A. (1987a) ture for electric vehicles. In Resources ElectricInternational Conference. Electric Vehicle De- Universityof

DeLuchi, Mark A.; Wang, Quanlu; Sperling, Daniel

1989-01-01T23:59:59.000Z

439

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

E-Print Network (OSTI)

16, Appendix I Fuel cell hybrid vehicles with load levelingfuel cell/battery hybrid vehicles, Journal of Power Sourcesfor a PEM Fuel Cell Hybrid Vehicle, Transactions of the

Zhao, Hengbing; Burke, Andy

2010-01-01T23:59:59.000Z

440

The Evolution of Sustainable Personal Vehicles  

E-Print Network (OSTI)

M. (2007). Battery Electric Vehicles: An Assessment of theExtended-Range Electric Vehicles: An Enabling Platform forReady Plug-in Hybrid Electric Vehicle. D.O.E. Challenge X,

Jungers, Bryan D

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.


441

Realising low carbon vehicles  

E-Print Network (OSTI)

MorganMotorCompany #12;Hybrid and electric vehicle design and novel power trains Cranfield has an impressive track record in the design and integration of near-to-market solutions for hybrid, electric and fuel cell vehicles coupe body the vehicle is powered by advanced lithium-ion batteries, and also features a novel all-electric

442

Life-cycle cost comparisons of advanced storage batteries and fuel cells for utility, stand-alone, and electric vehicle applications  

DOE Green Energy (OSTI)

This report presents a comparison of battery and fuel cell economics for ten different technologies. To develop an equitable economic comparison, the technologies were evaluated on a life-cycle cost (LCC) basis. The LCC comparison involved normalizing source estimates to a standard set of assumptions and preparing a lifetime cost scenario for each technology, including the initial capital cost, replacement costs, operating and maintenance (O M) costs, auxiliary energy costs, costs due to system inefficiencies, the cost of energy stored, and salvage costs or credits. By considering all the costs associated with each technology over its respective lifetime, the technology that is most economical to operate over any given period of time can be determined. An analysis of this type indicates whether paying a high initial capital cost for a technology with low O M costs is more or less economical on a lifetime basis than purchasing a technology with a low initial capital cost and high O M costs. It is important to realize that while minimizing cost is important, the customer will not always purchase the least expensive technology. The customer may identify benefits associated with a more expensive option that make it the more attractive over all (e.g., reduced construction lead times, modularity, environmental benefits, spinning reserve, etc.). The LCC estimates presented in this report represent three end-use applications: utility load-leveling, stand-alone power systems, and electric vehicles.

Humphreys, K.K.; Brown, D.R.

1990-01-01T23:59:59.000Z

443

Batteries: Overview of Battery Cathodes  

E-Print Network (OSTI)

a graphite-free lithium ion battery can be built, usingK (1990) Lithium Ion Rechargeable Battery. Prog. Batteriesion battery configurations, as all of the cycleable lithium

Doeff, Marca M

2011-01-01T23:59:59.000Z

444

Design of Electric Drive Vehicle Batteries for Long Life and Low Cost: Robustness to Geographic and Consumer-Usage Variation (Presentation)  

DOE Green Energy (OSTI)

This presentation describes a battery optimization and trade-off analysis for Li-ion batteries used in EVs and PHEVs to extend their life and/or reduce cost.

Smith, K.; Markel, T.; Kim, G. H.; Pesaran, A.

2010-10-01T23:59:59.000Z

445

A Historical-Data-Based Method for Health Assessment of Li-Ion Battery.  

E-Print Network (OSTI)

??Nowadays, rechargeable Li-ion batteries have been widely used in laptops, cell phones and hybrid electric vehicles (HEV). The health information of battery is very important.… (more)

Dai, Wanchen

2012-01-01T23:59:59.000Z

446

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

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

solicitation by the United States Advanced Battery Consortium (USABC), for plug-in hybrid electric vehicle (PHEV) battery development. This research aims to find solutions...

447

High-performance batteries for off-peak energy storage and electric-vehicle propulsion. Progress report, January--June 1975. [Li--Al/KCl--LiCl/Fe sulfide, 42 kWh  

DOE Green Energy (OSTI)

This report describes the research and management efforts, for the period January--June 1975, of Argonne National Laboratory's program on high-performance lithium/metal sulfide batteries. The batteries are being developed for two applications, off-peak energy storage in electric utility networks and electric-vehicle propulsion. The battery design for the two applications differ, particularly in cell configuration and electrode design, because of the differing performance requirements. The present cells are vertically oriented, prismatic cells with two negative electrodes of a solid lithium--aluminium alloy, a central positive electrode of iron sulfide (FeS/sub 2/ or FeS), and an electrolyte of LiCl--KCl eutectic (mp, 352/sup 0/C). The operating temperature of the cells is about 400--450/sup 0/C. Recent effort in the development of engineering-scale cells was focused on designing and fabricating vertically oriented, prismatic cells and on improving the lifetime capabilities of cells. Work on electrode development was directed toward the evaluation of the factors that influence the performance of the negative electrode and the development of new designs of vertical, prismatic iron sulfide electrodes. Materials studies included work on improving feedthroughs and separators, corrosion tests of candidate materials of construction, and postoperative examinations of cells. Cell chemistry studies included continuing investigations of cell reactions and the identification of advanced cell systems. Battery development work included the design of a battery for an electric automobile and the development of battery components. The transfer of Li--Al/FeS/sub x/ battery technology to industry is being implemented through contracts with industrial firms for the manufacture of components, electrodes, and cells.

Not Available

1976-03-01T23:59:59.000Z

448

Battery Maintenance  

Science Conference Proceedings (OSTI)

... Cranking batteries are not appropriate for extended use since disharging the battery deeply can rapidly destroy the thin plates. ...

449

Flywheel Battery Commercialization Study  

Science Conference Proceedings (OSTI)

High energy-density flywheel batteries, already in development as load leveling devices for electric and hybrid vehicles, have the potential to form part of an uninterruptible power supply (UPS) for utilities and their customers. This comprehensive assessment of the potential of flywheels in a power conditioning role shows that a sizeable market for flywheel battery-UPS systems may emerge if units can be manufactured in sufficient volume.

1999-09-23T23:59:59.000Z

450

?Just-in-Time? Battery Charge Depletion Control for PHEVs and E-REVs for Maximum Battery Life  

SciTech Connect

Conventional methods of vehicle operation for Plug-in Hybrid Vehicles first discharge the battery to a minimum State of Charge (SOC) before switching to charge sustaining operation. This is very demanding on the battery, maximizing the number of trips ending with a depleted battery and maximizing the distance driven on a depleted battery over the vehicle s life. Several methods have been proposed to reduce the number of trips ending with a deeply discharged battery and also eliminate the need for extended driving on a depleted battery. An optimum SOC can be maintained for long battery life before discharging the battery so that the vehicle reaches an electric plug-in destination just as the battery reaches the minimum operating SOC. These Just-in-Time methods provide maximum effective battery life while getting virtually the same electricity from the grid.

DeVault, Robert C [ORNL

2009-01-01T23:59:59.000Z

451

Automotive batteries. (Bibliography from the Global Mobility database). Published Search  

SciTech Connect

The bibliography contains citations concerning the design, manufacture, and marketing of automotive batteries. Included are nickel-cadmium, nickel metal hydride, sodium sulfur, zinc-air, lead-acid, and polymer batteries. Testing includes life-cycling, performance and peak-power characteristics, and vehicle testing of near-term batteries. Also mentioned are measurement equipment, European batteries, and electric vehicle battery development. (Contains a minimum of 76 citations and includes a subject term index and title list.)

NONE

1995-03-01T23:59:59.000Z

452

Automotive batteries. (Bibliography from the Global Mobility database). Published Search  

SciTech Connect

The bibliography contains citations concerning the design, manufacture, and marketing of automotive batteries. Included are nickel-cadmium, nickel metal hydride, sodium sulfur, zinc-air, lead-acid, and polymer batteries. Testing includes life-cycling, performance and peak-power characteristics, and vehicle testing of near-term batteries. Also mentioned are measurement equipment, European batteries, and electric vehicle battery development.(Contains 50-250 citations and includes a subject term index and title list.) (Copyright NERAC, Inc. 1995)

NONE

1996-02-01T23:59:59.000Z

453

Automotive batteries. (Bibliography from the Global Mobility database). Published Search  

SciTech Connect

The bibliography contains citations concerning the design, manufacture, and marketing of automotive batteries. Included are nickel-cadmium, nickel metal hydride, sodium sulfur, zinc-air, lead-acid, and polymer batteries. Testing includes life-cycling, performance and peak-power characteristics, and vehicle testing of near-term batteries. Also mentioned are measurement equipment, European batteries, and electric vehicle battery development. (Contains a minimum of 71 citations and includes a subject term index and title list.)

Not Available

1994-06-01T23:59:59.000Z

454

Batteries: Overview of Battery Cathodes  

E-Print Network (OSTI)

Challenges in Future Li-Battery Research. Phil Trans. RoyalBatteries: Overview of Battery Cathodes Marca M. Doeffduring cell discharge. Battery-a device consisting of one or

Doeff, Marca M

2011-01-01T23:59:59.000Z

455

Optimization of a plug-in hybrid electric vehicle .  

E-Print Network (OSTI)

??A plug-in hybrid electric vehicle (PHEV) is a vehicle powered by a combination of an internal combustion engine and an electric motor with a battery… (more)

Golbuff, Sam

2006-01-01T23:59:59.000Z

456

Household Markets for Neighborhood Electric Vehicles in California  

E-Print Network (OSTI)

of electric and compressed natural gas vehicles; and Twogasoline, compressed natural gas, hybrid electric, and threethe batteries. f-v Compressed natural gas vehicle Natural g

Kurani, Kenneth S; Sperling, Daniel; Lipman, Timothy; Stanger, Deborah; Turrentine, Thomas; Stein, Aram

1995-01-01T23:59:59.000Z

457

Household Markets for Neighborhood Electric Vehicles in California  

E-Print Network (OSTI)

of electric and compressed natural gas vehicles; and Twogasoline, compressed natural gas, hybridelectric, and threeon the batteries. Compressed natural gas vehicle Natural

Kurani, Kenneth S.; Sperling, Daniel; Lipman, Timothy; Stanger, Deborah; Turrentine, Thomas; Stein, Aram

2001-01-01T23:59:59.000Z

458

Under Secretary Nominee Sees INL Advanced Vehicle Technology...  

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

INL engineers explain the laboratory's role in DOE's Advanced Vehicle Testing Activity, hybrid-electric battery vehicle research, and biofuels research and development. He also...

459

Alternative Fuels Data Center: Heavy-Duty Vehicle and Engine...  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Boulder Electric Vehicle - DV-500 Delivery Truck Boulder Electric Vehicle - AC brushless induction motor with lithium-ion batteries Fuel Type: Electricity...

460

Optimization of blended battery packs  

E-Print Network (OSTI)

This thesis reviews the traditional battery pack design process for hybrid and electric vehicles, and presents a dynamic programming (DP) based algorithm that eases the process of cell selection and pack design, especially ...

Erb, Dylan C. (Dylan Charles)

2013-01-01T23:59:59.000Z

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.


461

“Smart” Frequency-Sensing Charge Controller for Electric Vehicles  

As plug-in hybrid electric vehicles (PHEVs) and battery electric vehicles (BEVs) become more popular, they create additional demand for electricity. Their emergence also raises a host of issues regarding how, where and when car batteries should be ...

462

Societal lifetime cost of hydrogen fuel cell vehicles  

E-Print Network (OSTI)

James, A cost comparison of fuel-cell and battery electricHowever, battery electric vehicles have lower fuel cost, usebattery-electric vehicles in terms of weight, volume, GHGs and cost,

Sun, Yongling; Ogden, J; Delucchi, Mark

2010-01-01T23:59:59.000Z

463

The origin of California’s zero emission vehicle mandate  

E-Print Network (OSTI)

them. Staff estimates of battery costs were questioned, how-has always been battery technology and costs. In 1990, whenmate of the additional cost of a battery electric vehicle,

Sperling, Dan; Collantes, Gustavo O

2008-01-01T23:59:59.000Z

464

Metal-air battery assessment  

DOE Green Energy (OSTI)

The objective of this report is to evaluate the present technical status of the zinc-air, aluminum/air and iron/air batteries and assess their potential for use in an electric vehicle. In addition, this report will outline proposed research and development priorities for the successful development of metal-air batteries for electric vehicle application. 39 refs., 25 figs., 11 tabs.

Sen, R.K.; Van Voorhees, S.L.; Ferrel, T.

1988-05-01T23:59:59.000Z

465

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.

466

Second use of transportation batteries: Maximizing the value of batteries for transportation and grid services  

SciTech Connect

Plug-in hybrid electric vehicles (PHEVs) and electric vehicles (EVs) are expected to gain significant market share over the next decade. The economic viability for such vehicles is contingent upon the availability of cost-effective batteries with high power and energy density. For initial commercial success, government subsidies will be highly instrumental in allowing PHEVs to gain a foothold. However, in the long-term, for electric vehicles to be commercially viable, the economics have to be self-sustaining. Towards the end of battery life in the vehicle, the energy capacity left in the battery is not sufficient to provide the designed range for the vehicle. Typically, the automotive manufacturers indicated the need for battery replacement when the remaining energy capacity reaches 70-80%. There is still sufficient power (kW) and energy capacity (kWh) left in the battery to support various grid ancillary services such as balancing, spinning reserve, load following services. As renewable energy penetration increases, the need for such balancing services is expected to increase. This work explores optimality for the replacement of transportation batteries to be subsequently used for grid services. This analysis maximizes the value of an electric vehicle battery to be used as a transportation battery (in its first life) and then as a resource for providing grid services (in its second life). The results are presented across a range of key parameters, such as depth of discharge (DOD), number of batteries used over the life of the vehicle, battery life in vehicle, battery state of health (SOH) at end of life in vehicle and ancillary services rate. The results provide valuable insights for the automotive industry into maximizing the utility and the value of the vehicle batteries in an effort to either reduce the selling price of EVs and PHEVs or maximize the profitability of the emerging electrification of transportation.

Viswanathan, Vilayanur V.; Kintner-Meyer, Michael CW

2010-09-30T23:59:59.000Z

467

Societal lifetime cost of hydrogen fuel cell vehicles  

E-Print Network (OSTI)

analysis of battery electric, hydrogen fuel cell and hybrid vehicles in a future sustainable road transport system, Energy Policy

Sun, Yongling; Ogden, J; Delucchi, Mark

2010-01-01T23:59:59.000Z

468

Alternative Fuels Data Center: Heavy-Duty Vehicle and Engine...  

Alternative Fuels and Advanced Vehicles Data Center (EERE)

Trans Tech - ETrans Smith Electric Vehicles - 120kW induction motor with lithium-ion batteries Fuel Type: Electricity...

469

Advanced Batteries for PHEVs  

Science Conference Proceedings (OSTI)

This report describes testing conducted on two different types of batteriesVARTA nickel-metal hydride and SAFT lithium ionused in the Plug-in Hybrid Electric Vehicle (PHEV) Sprinter program. EPRI and DaimlerChrysler developed a PHEV concept for the Sprinter Van to reduce the vehicle's emissions, fuel consumption, and operating costs while maintaining equivalent or superior functionality and performance. The PHEV Sprinter was designed to operate in both a pure electric mode and a charge-sustaining hybrid ...

2009-12-22T23:59:59.000Z

470

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

471

Electric Vehicle Infrastructure  

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

Infrastructure JOHN DAVIS: Nearly everyone who owns a plug-in electric vehicle has some capacity to replenish the battery at home, either with a dedicated 220-volt charger, or by...

472

Energy Basics: Electric Vehicles  

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

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...

473

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

474

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 onusing plug-in hybrid electric vehicle battery packs for gridL ABORATORY Plug-in Electric Vehicle Interactions with a

Momber, Ilan

2010-01-01T23:59:59.000Z

475

Online Algorithm for Battery Utilization in Electric Computer Science Department  

E-Print Network (OSTI)

Online Algorithm for Battery Utilization in Electric Vehicles Ron Adany Computer Science Department the problem of utilizing the pack of batteries serving current demands in Electric Vehicles. When serving a demand, the current allocation might be split among the batteries in the pack. Due to its internal

Tamir, Tami

476

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.

477

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

478

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

479

Battery system  

DOE Patents (OSTI)

A battery module includes a plurality of battery cells and a system configured for passing a fluid past at least a portion of the plurality of battery cells in a parallel manner.

Dougherty, Thomas J; Wood, Steven J; Trester, Dale B; Andrew, Michael G

2013-08-27T23:59:59.000Z

480

The INEL battery data base  

SciTech Connect

The Department of Energy (DOE) has established a Battery Data Base for electric vehicle applications at the Idaho National Engineering Laboratory (INEL). The objectives of the Data Base are to collect, store, and make available to the electric vehicle community battery data from the INEL. Argonne National Laboratory, Sandia National Laboratory, and DOE battery contractors in forms appropriate for evaluating the batteries in electric vehicles. The Data Base currently includes data from over 500 test on 15 batteries of 5 different types. The data (over 120 MB) is stored on a 760 MB harddisk attached to a MicroVax 2. PC-based software to access the data has been developed on the IBM PS/2 using dBASE 4. The initial version of the Data Base to be distributed on a single floppy disk is nearly complete. The first release will include the physical characteristics of the batteries, summary tables showing the test results for each cycle of the battery test programs, and some constant power discharge data for the batteries. Later versions of the Data Base will include second-by-second peak power and SFUDS data, which will require several floppy of Bernoulli disks to store the data. 2 refs., 4 figs.

Burke, A.F.; Hardin, J.E.; Kiser, D.M.

1990-01-01T23:59:59.000Z