Author:
Xie Di,Wang Liangliang,Zhang Zhi,Wang Shoumo,Kang Longyun,Yao Jigang
Abstract
Power battery test equipment is widely used to produce and test new energy vehicles and storage containers. To address the problem of DC bus voltage fluctuations that affect the accuracy of output voltage and current, a high-accuracy bus voltage control strategy is based on nonlinear extended state observation (NLESO) and terminal silding mode controller (TSMC) load current estimation. Simulation and experimental results show that the control strategy has a good suppression effect on the DC bus voltage fluctuation and can effectively improve the accuracy of the DC side output voltage and current. Grid voltage differential feedforward is adopted, which can achieve fast suppression of DC bus voltage fluctuations in power battery test equipment and meet the high precision output requirements of the system DC bus.
Subject
Economics and Econometrics,Energy Engineering and Power Technology,Fuel Technology,Renewable Energy, Sustainability and the Environment
Reference24 articles.
1. Current-sharing and DC bus voltage control system design of paralleled DC-DC converters;Aksenov,2016
2. Enhancement of DC-bus voltage regulation in cascaded converter system by a new sensorless load current feedforward control scheme;Ali;IET power electron.,2021
3. Design of an adaptive feedforward control scheme for the DC bus voltage control of single phase grid connected converters;Baazoug,2018
4. Ripple eliminator to smooth DC-bus voltage and reduce the total capacitance required;Cao;IEEE Trans. Ind. Electron.,2015
5. Synchronization control of complex network based on extended observer and sliding mode control;Changchao;IEEE Access,2020