The application of batteries and ultracapacitors in electric energy storage units for battery powered (EV) and charge sustaining and plug-in hybrid-electric (HEV and PHEV) vehicles have been studied in detail. The use of IC engines and hydrogen fuel cells as the primary energy converters for the hybrid vehicles was considered. The study focused on the use of lithium-ion batteries and carbon/carbon ultracapacitors as the energy storage technologies most likely to be used in future vehicles. The key findings of the study are as follows. 1) The energy density and power density characteristics of both battery and ultracapacitor technologies are sufficient for the design of attractive EVs, HEVs, and PHEVs. 2) Charge sustaining, engine powered hybrid-electric vehicles (HEVs) can be designed using either batteries or ultracapacitors with fuel economy improvements of 50% and greater. 3) Plug-in hybrids (PHEVs) can be designed with effective all-electric ranges of 30-60 km using lithium-ion batteries that are relatively small. The effective fuel economy of the PHEVs can be very high (greater than 100 mpg) for long daily driving ranges (80-150 km) resulting in a large fraction (greater than 75%) of the energy to power the vehicle being grid electricity. 4) Mild hybrid-electric vehicles (MHEVs) can be designed using ultracapacitors having an energy storage capacity of 75-150 Wh. The fuel economy improvement with the ultracapacitors is 10%-15% higher than with the same weight of batteries due to the higher efficiency of the ultracapacitors and more efficient engine operation. 5) Hybrid-electric vehicles powered by hydrogen fuel cells can use either batteries or ultracapacitors for energy storage. Simulation results indicate the equivalent fuel economy of the fuel cell powered vehicles is 2-3 times higher than that of a gasoline fueled IC vehicle of the same weight and road load. Compared to an engine-powered HEV, the equivalent fuel economy of the hydrogen fuel cell vehicle would be 1.66-2.0 times higher
[1]
A. Burke,et al.
The present and projected performance and cost of double-layer pseudo-capacitive ultracapacitors for hybrid vehicle applications
,
2005,
2005 IEEE Vehicle Power and Propulsion Conference.
[2]
Karl-Heinz Hauer,et al.
A dynamic simulation tool for hydrogen fuel cell vehicles
,
2005
.
[3]
Andrew Burke,et al.
FEASIBLE CAFE STANDARD INCREASES USING EMERGING DIESEL AND HYBRID-ELECTRIC TECHNOLOGIES FOR LIGHT-DUTY VEHICLES IN THE UNITED STATES
,
2004
.
[4]
Zakiul Kabir,et al.
Steady State and Transient Modeling of a PEM Fuel Cell Power Plant for Transportation Applications
,
2005
.
[5]
G. H. Cole,et al.
SIMPLEV: A simple electric vehicle simulation program, Version 1.0
,
1991
.
[6]
Andrew Burke,et al.
Saving Petroleum with Cost-Effective Hybrids
,
2003
.
[7]
G. I. Kustova,et al.
From the author
,
2019,
Automatic Documentation and Mathematical Linguistics.
[8]
Isa Bar-On,et al.
Technical cost analysis for PEM fuel cells
,
2002
.