Equivalent factor of energy management strategy for fuel cell hybrid electric vehicles based on Q-Learning

doi:10.3969/j.issn.1674-8484.2022.04.020

Abstract

Abstract:

An energy management strategy based on equivalent factor Q-learning algorithm was proposed to improve the fuel economy of fuel cell hybrid electric vehicles (FCHEVs) and maintain the battery energy balance. The objective function of minimizing equivalent hydrogen consumption and maintaining battery state of charge (SOC) was constructed to establish the energy flow conversion balance model of FCHEVs power source, and the equivalent factor of hydrogen consumption was obtained through the energy conversion balance mechanism. The transfer probability matrix of required power was solved under urban dynamometer driving schedule + world light vehicle test cycle (UDDS+WLTC) conditions, and the output power of fuel cells and batteries was optimized offline by Q-learning algorithm. The forward simulation model was established based on MATLAB/Simulink platform, and the vehicle simulation was carried out under different working conditions. The results show that the equivalent of the hydrogen consumption per 100 km is 0.730 kg under WLTC cycle conditions in the proposed strategy, which is close to that based on the dynamic programming (DP) control strategy, and the SOC is kept within a reasonable range, which verifies the effectiveness of the proposed strategy. And the adaptability of the proposed control strategy is also verified in the actual working conditions of Xining City.

Key words: fuel cell hybrid electric vehicle (FCHEV), equivalent factor, Q-learning algorithm, energy management

CLC Number:

U469.7

YIN Yanli, ZHANG Xinxin, PAN Xiaoliang, ZHAN Shen, HUANG Xuejiang, WANG Fuzhen. Equivalent factor of energy management strategy for fuel cell hybrid electric vehicles based on Q-Learning[J]. Journal of Automotive Safety and Energy, 2022, 13(4): 785-795.

Figures/Tables 18

References 18

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整车	整车质量	1.399 t
	迎风面积	2.0 m2
	风阻因数	0.335
	滚动阻力因数	0.008 6
	车轮半径	0.282 m
传动系统	主减速器速比	8.879
传动系统	传动效率	0.90
燃料电池	最大功率	50 kW
燃料电池	DC/DC转换器效率	0.94
蓄电池	额定容量	12 Ah
蓄电池	额定转速	10⁴ r/min
电机	最大功率	75 kW
电机	最大转矩	272 Nm

整车	整车质量	1.399 t
	迎风面积	2.0 m2
	风阻因数	0.335
	滚动阻力因数	0.008 6
	车轮半径	0.282 m
传动系统	主减速器速比	8.879
传动系统	传动效率	0.90
燃料电池	最大功率	50 kW
燃料电池	DC/DC转换器效率	0.94
蓄电池	额定容量	12 Ah
蓄电池	额定转速	10⁴ r/min
电机	最大功率	75 kW
电机	最大转矩	272 Nm

控制策略	100 km耗氢量 g	最终SOC %
DP	0.686	60.8
QL	0.730	59.4
RB	0.798	57.8

控制策略	100 km耗氢量 g	最终SOC %
DP	0.686	60.8
QL	0.730	59.4
RB	0.798	57.8

策略	耗氢量 kg	100 km耗氢量 kg	与DP算法对比 %
λ_var -DP	0.181	0.886	-
λ_var -Q	0.195	0.953	+7.52
λ_cv-Q	0.199	0.972	+9.68