Design and control of air supply system for PEMFC UAV based on dynamic decoupling strategy

Zhao Dongdong; Xia Lei; Dang HanbinWu ZezhongLi Haiyan

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Design and control of air supply system for PEMFC UAV based on dynamic decoupling strategy

机译：Design and control of air supply system for PEMFC UAV based on dynamic decoupling strategy

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The oxygen excess ratio (OER) and air pressure of the proton exchange membrane fuel cell (PEMFC) cathode need to be relatively stable to improve energy conversion and utilization. However, the OER and air pressure adjustments are coupled in the centrifugal compression system and the fluctuations of OER and pressure may cause oxygen starvation and destroy the pressure balance between anode and cathode respectively, affecting the output power and service life of PEMFC. When the PEMFC unmanned aerial vehicle (UAV) performs the mission, the nonlinearity and time-varying characteristics of the model bring greater challenges to the design and control of air supply system for PEMFC UAV. Firstly, in view of nonlinear factors such as the variable space environments and different load conditions, an air supply system model suitable for PEMFC UAV is established. Secondly, in order to supply stable voltage to the UAV load and the air compressor through the DC/DC power converter as well as reduce PEMFC output power loss and device stress, a four-phase interleaved boost converter (IBC) and controller are designed. The devised IBC and its control scheme are beneficial to decrease energy loss and strengthen the anti-interference ability for high-power PEMFC applications. What's more, based on the air compressor dynamic model as well as the analysis of the static and dynamic characteristics of PEMFC system, the power consumption relationships among the external UAV load, the internal compressor load, and the stack source are analyzed in detail. Then, when considering the strong coupling and nonlinearity of the mass flow and the pressure under the variable-altitude centrifugal compression system, we propose a dynamic decoupling strategy for OER and pressure control based on fuzzy logic. Finally, compared with the results of PI controllers and feedforward compensation decoupling controllers, the fuzzy decoupling controllers can realize the rapid adjustment of OER and maintain the stability of air pressure robustly.

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来源
《Energy conversion & management》 |2022年第2期|115159.1-115159.17|共17页
作者
Zhao Dongdong; Xia Lei; Dang HanbinWu ZezhongLi Haiyan;
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作者单位

Northwestern Polytech Univ, Sch Automat, Rd Dongxiang, Xian 710129, Peoples R China;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种英语
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关键词
Proton exchange membrane fuel cell unmanned; aerial vehicle (PEMFC UAV); Four-phase interleaved boost converter (IBC); Oxygen excess ratio (OER) and pressure control; Fuzzy decoupling control;

Design and control of air supply system for PEMFC UAV based on dynamic decoupling strategy

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