具有制氢和储氢功能的PV PSO MPPT /燃料电池/电池混合系统的能量管理策略

Q4 Biochemistry, Genetics and Molecular Biology Journal of Biomolecular Techniques Pub Date : 2023-09-02 DOI:10.51173/jt.v5i3.890
None Faris Nasser Shaker, None Adel A. Obed, None Ahmed J. Abid, None Ameer L. Saleh, None Reheel J. Hassoon
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引用次数: 0

摘要

由于可再生能源的高不确定性,以及能源和储能系统的多样性,必须寻求一个控制器来管理所有这些可再生能源和这种混合储能。本文提出了一种可再生能源管理系统,该系统采用平面度控制、PID和PSO技术,跟踪光伏阵列的最大功率点,并对储能元件进行管理。采用两种储能方式:电池储能和氢罐储能。所提出的(Nero-fuzzy)控制器还可以通过控制碱性电解槽和储氢罐的压力来智能安全地填充储氢罐。这种组合系统的主要目的是获得电力稳定性。由于PV是主要的发电源,PSO MPPT是在不同辐射和温度条件下PV最优输出功率的系统。燃料电池已被用于补偿由于天气条件或直流负载的高功率需求而缺乏控制时损失的能量。电池被耦合到直流母线上,以快速响应电源需求。当辐射强度为1000w /m2时,光伏发电功率为18kw,可满足负载供电,电解槽运行功率为7kw,并可为蓄电池充电。而在辐射变化时,240w /m2时,太阳能电池板产生4.3 kW的电能,负载4.7 kW的电能。电池首先工作,因为它反应迅速,然后燃料电池工作,以产生替代它,这足以运行负载。结果表明,在不同的天气条件和负荷情况下,电网具有稳定、快速的响应能力。
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Energy Management Strategy for PV PSO MPPT / Fuel Cell/Battery Hybrid System with Hydrogen Production and Storage
Due to the high uncertainty of renewable energy sources, and the diversity of energy sources and storage systems, it is mandatory to seek a controller that manages all these renewable energy sources and this hybrid energy storage. This paper proposed a renewable energy management system using flatness control and PID and PSO technologies that track the maximum power point from the PV array and manages the energy storage elements. Two energy storage are adopted: battery storage and hydrogen tank. The proposed (Nero-fuzzy) controller also works to fill the hydrogen storage tank wisely and safely by controlling the alkaline electrolyzer and the tank's pressure. The main aim of this combined system is to attain power stability. Since the PV is the primary production source, a PSO MPPT is a proposed system for optimum power delivered by the PV under different radiation and temperature conditions. The fuel cell has been used to compensate for the energy lost when there is a lack of control due to weather conditions or high-power demand by the DC load. A battery was coupled to the DC bus to respond quickly to the power requirement. When the radiation intensity is 1000 W/m2, the PV will generate enough 18 kW to supply the load, run the electrolyzer 7 kW, and charge the batteries. While in the radiation change, when it is 240 W/m2, the solar panels produce (4.3 kW) and the load (4.7 kW). The battery works first because of its quick response, and then the fuel cell works to generate instead of it, which is sufficient to operate the load only. The results show a stable and fast response grid under different weather conditions and load scenarios.
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来源期刊
Journal of Biomolecular Techniques
Journal of Biomolecular Techniques Biochemistry, Genetics and Molecular Biology-Molecular Biology
CiteScore
2.50
自引率
0.00%
发文量
9
期刊介绍: The Journal of Biomolecular Techniques is a peer-reviewed publication issued five times a year by the Association of Biomolecular Resource Facilities. The Journal was established to promote the central role biotechnology plays in contemporary research activities, to disseminate information among biomolecular resource facilities, and to communicate the biotechnology research conducted by the Association’s Research Groups and members, as well as other investigators.
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