Nonsingular terminal sliding mode control strategy of bidirectional DC-DC converter in energy storage system based on the nonlinear disturbance observer

doi:10.19799/j.cnki.2095-4239.2023.0833

Abstract

Abstract:

In DC microgrids based on photovoltaic and energy storage systems, the bidirectional DC-DC converter is a key interface between the energy storage equipment and DC bus, and its performance under the large signal disturbance of photovoltaic output power and load directly affects the stable operation of the DC bus. Therefore, a nonsingular terminal sliding mode control strategy based on a nonlinear disturbance observer is proposed in this study. First, the state-space model of the bidirectional DC-DC converter system is transformed into Brunovsky's standard form using the exact feedback linearization method based on differential geometry theory, and the disturbances are estimated using the nonlinear disturbance observer as the compensation channel. Moreover, we design a nonsingular terminal sliding mode controller and analyze the stability, as well as convergence, of the proposed control strategy based on Lyapunov stability theory. Finally, we perform simulations to prove the effectiveness of the proposed control strategy. The simulation results show that compared with typical nonlinear control methods in the literature, the proposed control strategy has a fast response time, small overshoot, and steady-state error under the large signal disturbance of photovoltaic output power and load.

Key words: DC microgrid, bidirectional DC-DC converter, nonsingular terminal sliding mode control, nonlinear disturbance observer

CLC Number:

TM 46

Yong SU, Yanfeng CHEN. Nonsingular terminal sliding mode control strategy of bidirectional DC-DC converter in energy storage system based on the nonlinear disturbance observer[J]. Energy Storage Science and Technology, 2024, 13(5): 1523-1531.

Figures/Tables 11

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参数	数值
储能电池输出电压V_b/V	200
储能电池容量/Ah	50
直流母线电压v_bus/V	400
电感L/mH	2
电容C/μF	1000
恒功率负载P_CPL/W	3000
阻性负载R/Ω	60
开关频率f/kHz	20
储能电池SOC/%	50
k₁	450
k₂	350
m₁	8500
m₂	1500
λ	1.66

控制策略	工况	过充/V	恢复时间/ms	稳态误差/V
基于NDO的反步控制策略	光伏功率突减	5.8	21	0.03
	阻性负载突减	4.9	26	0.04
	恒功率负载突增	3.7	22	0.03

反步滑模控制策略	光伏功率突减	6.4	6	6.19
	阻性负载突减	5.6	4	5.12
	恒功率负载突增	4.3	5	4.07

本文所提出的控制策略	光伏功率突减	4.2	12	0.03
	阻性负载突减	3.5	14	0.02
	恒功率负载突增	2.7	13	0.02

[1]	Jingchao SHEN, Jian HU, Jingliang HU, Ticao JIAO, Xiaomei QI, Yunpeng WANG, Di YU, Shangqi LIU. Parameter adaptive backstepping control of bidirectional DC-DC converter for DC microgrid energy storage device [J]. Energy Storage Science and Technology, 2022, 11(5): 1512-1522.
[2]	Yu LI, Zhanqiang ZHANG, Keqilao MENG, Haotian WEI. Optimal control strategy for energy storage in island microgrid based on hierarchical control [J]. Energy Storage Science and Technology, 2022, 11(1): 176-184.
[3]	Siyan LIU, Bihua HU. Model predictive control for bidirectional DC-DC converter of hydrogen fuel vehicles [J]. Energy Storage Science and Technology, 2021, 10(6): 2046-2052.