An optimized energy management strategy for preheating vehicle-mounted Li-ion batteries at subzero temperatures
An optimized energy management strategy for preheating vehicle-mounted Li-ion batteries at subzero temperatures
This paper presents an optimized energy management strategy for Li-ion power batteries used on electric vehicles (EVs) at low temperatures. In low-temperature environments, EVs suffer a sharp driving range loss resulting from the energy and power capability reduction of the battery. Simultaneously, because of Li plating, battery degradation becomes an increasing concern as the temperature drops. All these factors could greatly increase the total vehicle operation cost. Prior to battery charging and vehicle operating, preheating the battery to a battery-friendly temperature is an approach to promote energy utilization and reduce total cost. Based on the proposed LiFePO4 battery model, the total vehicle operation cost under certain driving cycles is quantified in the present paper. Then, given a certain ambient temperature, a target preheating temperature is optimized under the principle of minimizing total cost. As for the preheating method, a liquid heating system is also implemented on an electric bus. Simulation results show that the preheating process becomes increasingly necessary with decreasing ambient temperature, however, the preheating demand declines as driving range grows. Vehicle tests verify that the preheating management strategy proposed in this paper is able to save on total vehicle operation costs.
electric vehicle (EV); battery heat generation; battery degradation; vehicle operation cost; preheating target temperature; heating system
1-23
Zhu, Tao
2333524f-f55e-4069-85b9-82d89277efc4
Min, Haitao
80e81d9c-43ed-4048-aa50-75c32f84830b
Yu, Yuanbin
40b8a3d1-d0cd-4e55-8888-15466bc4c20f
Zhao, Zhongmin
976a83a8-edb7-4b07-9cda-b3f267b2d701
Xu, Tao
8ba2cbb6-8058-4a5c-8f14-dca9d9037da4
Chen, Yang
5eb3a594-8255-4e04-ba17-62790e5f19b6
Li, Xinyong
d0cd6339-0c15-40d3-9627-16f18882ff94
Cong, Zhang
969283a6-a7cc-4d53-8f44-d58130a0093c
2017
Zhu, Tao
2333524f-f55e-4069-85b9-82d89277efc4
Min, Haitao
80e81d9c-43ed-4048-aa50-75c32f84830b
Yu, Yuanbin
40b8a3d1-d0cd-4e55-8888-15466bc4c20f
Zhao, Zhongmin
976a83a8-edb7-4b07-9cda-b3f267b2d701
Xu, Tao
8ba2cbb6-8058-4a5c-8f14-dca9d9037da4
Chen, Yang
5eb3a594-8255-4e04-ba17-62790e5f19b6
Li, Xinyong
d0cd6339-0c15-40d3-9627-16f18882ff94
Cong, Zhang
969283a6-a7cc-4d53-8f44-d58130a0093c
Zhu, Tao, Min, Haitao, Yu, Yuanbin, Zhao, Zhongmin, Xu, Tao, Chen, Yang, Li, Xinyong and Cong, Zhang
(2017)
An optimized energy management strategy for preheating vehicle-mounted Li-ion batteries at subzero temperatures.
Energies, 10 (2), , [243].
(doi:10.3390/en10020243).
Abstract
This paper presents an optimized energy management strategy for Li-ion power batteries used on electric vehicles (EVs) at low temperatures. In low-temperature environments, EVs suffer a sharp driving range loss resulting from the energy and power capability reduction of the battery. Simultaneously, because of Li plating, battery degradation becomes an increasing concern as the temperature drops. All these factors could greatly increase the total vehicle operation cost. Prior to battery charging and vehicle operating, preheating the battery to a battery-friendly temperature is an approach to promote energy utilization and reduce total cost. Based on the proposed LiFePO4 battery model, the total vehicle operation cost under certain driving cycles is quantified in the present paper. Then, given a certain ambient temperature, a target preheating temperature is optimized under the principle of minimizing total cost. As for the preheating method, a liquid heating system is also implemented on an electric bus. Simulation results show that the preheating process becomes increasingly necessary with decreasing ambient temperature, however, the preheating demand declines as driving range grows. Vehicle tests verify that the preheating management strategy proposed in this paper is able to save on total vehicle operation costs.
Text
energies-10-00243
- Version of Record
More information
Accepted/In Press date: 15 February 2017
e-pub ahead of print date: 17 February 2017
Published date: 2017
Keywords:
electric vehicle (EV); battery heat generation; battery degradation; vehicle operation cost; preheating target temperature; heating system
Identifiers
Local EPrints ID: 418460
URI: http://eprints.soton.ac.uk/id/eprint/418460
ISSN: 1996-1073
PURE UUID: 4509a257-d151-4839-a4e1-71d293efb47e
Catalogue record
Date deposited: 09 Mar 2018 17:30
Last modified: 15 Mar 2024 18:48
Export record
Altmetrics
Contributors
Author:
Haitao Min
Author:
Yuanbin Yu
Author:
Zhongmin Zhao
Author:
Tao Xu
Author:
Yang Chen
Author:
Xinyong Li
Author:
Zhang Cong
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics