Abstract
This paper presents the application of an active energy management strategy to a hybrid system consisting of a proton exchange membrane fuel cell (PEMFC), battery, and supercapacitor. The purpose of energy management is to control the battery and supercapacitor states of charge (SOCs) as well as minimizing hydrogen consumption. Energy management should be applied to hybrid systems created in this way to increase efficiency and control working conditions. In this study, optimization of an existing model in the literature with different meta-heuristic methods was further examined and results similar to those in the literature were obtained. Ant lion optimizer (ALO), moth-flame optimization (MFO), dragonfly algorithm (DA), sine cosine algorithm (SCA), multi-verse optimizer (MVO), particle swarm optimization (PSO), and whale optimization algorithm (WOA) meta-heuristic algorithms were applied to control the flow of power between sources. The optimization methods were compared in terms of hydrogen consumption and calculation time. Simulation studies were conducted in Matlab/Simulink R2020b (academic license). The contribution of the study is that the optimization methods of ant lion algorithm, moth-flame algorithm, and sine cosine algorithm were applied to this system for the first time. It was concluded that the most effective method in terms of hydrogen consumption and computational burden was the sine cosine algorithm. In addition, the sine cosine algorithm provided better results than similar meta-heuristic algorithms in the literature in terms of hydrogen consumption. At the same time, meta-heuristic optimization algorithms and equivalent consumption minimization strategy (ECMS) and classical proportional integral (PI) control strategy were compared as a benchmark study as done in the literature, and it was concluded that meta-heuristic algorithms were more effective in terms of hydrogen consumption and computational time.
Highlights
The amount of fossil fuels is limited in nature
Based on the above reasoning, the current paper presents energy management and optimization of the triple hybrid system consisting of battery, supercapacitor, and fuel cell stack, using ant lion optimizer (ALO) [32], moth-flame optimization (MFO) [33], dragonfly algorithm (DA) [34], multi-verse optimizer (MVO) [35], particle swarm optimization (PSO) [36], whale optimization algorithm (WOA) [37], and sine cosine algorithm (SCA) [38]
Energy management and optimization has been applied to the system shown in Figure 1, which consists of battery, supercapacitor, and fuel cell stack
Summary
The amount of fossil fuels is limited in nature. In addition, it has harmful effects such as air pollution and greenhouse effects. Some meta-heuristic algorithms have been applied to the hybrid system consisting of battery, supercapacitor, and fuel cell stack, as used in this study [26,28,29,30,31]. Based on the above reasoning, the current paper presents energy management and optimization of the triple hybrid system consisting of battery, supercapacitor, and fuel cell stack, using ant lion optimizer (ALO) [32], moth-flame optimization (MFO) [33], dragonfly algorithm (DA) [34], multi-verse optimizer (MVO) [35], particle swarm optimization (PSO) [36], whale optimization algorithm (WOA) [37], and sine cosine algorithm (SCA) [38]. In the system used in this study, the battery and fuel cell stack are connected to the system through DC/DC converters, and the supercapacitor is directly connected to the DC bus For this reason, active energy management was applied to the hybrid system.
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