Dimensioning and Lifetime Prediction Model for a Hybrid, Hydrogen-Based Household PV Energy System Using Matlab/Simulink

IF 0.9 Q4 GEOCHEMISTRY & GEOPHYSICS
Marius C. Möller, S. Krauter
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引用次数: 1

Abstract

This paper presents a model of an energy system for a private household extended by a lifetime prognosis. The energy system was designed for fully covering the year-round energy demand of a private household on the basis of electricity generated by a photovoltaic (PV) system, using a hybrid energy storage system consisting of a hydrogen unit and a lithium-ion battery. Hydrogen is produced with a Proton Exchange Membrane (PEM) electrolyser by PV surplus during the summer months and then stored in a hydrogen tank. Mainly during winter, in terms of lack of PV energy, the hydrogen is converted back into electricity and heat by a fuel cell. The model was created in Matlab/Simulink and is based on real input data. Heat demand was also taken into account and is covered by a heat pump. The simulation period is a full year to account for the seasonality of energy production and demand. Due to high initial costs, the longevity of such an energy system is of vital interest. Therefore, this model was extended by a lifetime prediction in order to optimize the dimensioning with the aim of lifetime extension of a hydrogen-based energy system. Lifetime influencing factors were identified on the basis of a literature review and were integrated in the model. An extensive parameter study was performed to evaluate different dimensionings regarding the energy balance and the lifetime of the three components, electrolyser, fuel cell and lithium-ion battery. The results demonstrate the benefits of a holistic modelling approach and enable a design optimization regarding the use of resources, lifetime and self-sufficiency of the system.
基于Matlab/Simulink的混合氢基家用光伏能源系统尺寸和寿命预测模型
本文提出了一个由终身预测延长的私人家庭能源系统模型。该能源系统的设计是为了在光伏(PV)系统发电的基础上,使用由氢单元和锂离子电池组成的混合储能系统,完全满足私人家庭全年的能源需求。氢气在夏季由PV剩余的质子交换膜(PEM)电解槽产生,然后储存在氢罐中。主要是在冬季,由于缺乏光伏能源,氢被燃料电池转换回电和热。该模型是在Matlab/Simulink中基于实际输入数据建立的。热需求也被考虑在内,并由热泵覆盖。模拟期为一整年,以考虑能源生产和需求的季节性。由于初始成本高,这种能源系统的寿命至关重要。为此,对该模型进行了寿命预测扩展,以实现氢基能源系统寿命延长为目标,对模型进行了尺寸优化。在文献回顾的基础上确定寿命影响因素,并将其整合到模型中。为了评估电解槽、燃料电池和锂离子电池三个组件的能量平衡和寿命,进行了广泛的参数研究。结果证明了整体建模方法的好处,并使设计优化有关资源的使用,寿命和系统的自给自足。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Solar-Terrestrial Physics
Solar-Terrestrial Physics GEOCHEMISTRY & GEOPHYSICS-
CiteScore
1.50
自引率
9.10%
发文量
38
审稿时长
12 weeks
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