微电网中电动汽车充电站的混合光伏和BES

2023 20th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON) Pub Date : 2023-05-09 DOI:10.1109/ECTI-CON58255.2023.10153262

N. Thaitae, C. Summatta, P. Prabpal, B. Yosrueangsak, S. Sonasang

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引用次数: 0

摘要

本文提出了一种安装电动汽车的混合动力系统使用方案，以解决混合动力光伏(PV)和储能系统(ESS)的需求充电站问题。该研究采用了一种将该系统混合安装在微电网配电系统中的方法。采用ieee13总线标准，用计算机程序对安装系统进行了测试。该程序在开放式配电(OpenDSS)程序中进行了测试，这是一个配电模拟器。作为微网系统的末班车，680公交车在安装电动汽车充电站、光伏和ESS后24小时内模拟连续加载。在PV大小为0的条件下，开发OpenDSS实现混合。4SkW, 2000kw, ESS尺寸为500kw, 3000kvar。电动汽车电池的功率为4。SkW。工况下的有功功率增加了PV-EV、PV-ESS和PV-ESS- ev工况下的混合动力系统。微电网系统中安装混合动力系统的研究结果。标准与实际系统的比较表明，有功功率和无功功率之和百分比系统的最大值和最小值几乎相同。有相似的值，百分比差异小于1%，而有功和无功系统的功率损耗百分比差异小于1%。安装的混合系统不影响微电网系统中的被测系统。

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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Hybrid PV and BES for EV Charging Stations in Microgrid Systems

This paper presents a solution to hybrid systems usage by installing electric vehicles to solve the hybrid photovoltaic (PV) and energy storage system (ESS) for the demand charging station problem. The research used a method for hybrid installing the system in a microgrid distribution system. The IEEE 13 bus standard was applied to test the installation system with a computer program. The program was tested with the Open electric power distribution (OpenDSS) program, a simulator for electric distribution. It was simulated continuously loading within 24 hours of installation of EV charging station, PV and ESS at 680 bus as it is the last bus of the microgrid system. OpenDSS was developed to implement hybrid under the condition that the PV size is 0. 4SkW, 2000 kW, and the ESS size is 500 kW, 3000 kVAR. The EV battery with a power of 4. SkW. The active power under the condition adds hybrid systems under the condition PV-EV, PV-ESS, and PV-ESS-EV. The results of the study on the installation of hybrid systems in the microgrid system. The comparison between the standard and the installed system showed that the maximum and minimum values of the percentage system were almost the same for the sum of both active and reactive power supply. There are similar values with a percentage difference of less than 1 %, while the power loss in both active and reactive systems have a percentage difference that is less than 1 %. The installed hybrid systems do not affect the tested system in the microgrid systems.

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来源期刊

2023 20th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON)

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