A heuristic power optimization method for photovoltaic systems

2014 North American Power Symposium (NAPS) Pub Date : 2014-11-24 DOI:10.1109/NAPS.2014.6965454

J. Icenhower, M. Zarghami, M. Vaziri

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引用次数: 1

Abstract

California is striving to increase penetration of Distributed Generation (DG) to 33% by 2020. This effort is to promote energy independence of the state of California and to lead the country to be more environmentally conscious. However, integrating DG and increasing penetration to high levels will negatively impact the grid. One issue that has been discussed is that DG may supply more power than is demanded by the load. This may cause overvoltage issues at the buses where the DG is connected and also may cause power to flow from the distribution to the transmission system. Current legislation dictates DG to operate at unity power factor and prohibits DG to inject or absorb reactive power. This is to ensure that the Utilities can control system voltage and that the customers do not regulate voltage at the interconnection points. However, when considering system performance, this legislation is not ideal. The mission of this paper is to provide convincing data that will demonstrate the benefits of controlling reactive power for better system performance. Furthermore, it will provide a heuristic method that calculates near-optimum dispatch of DG in the distribution system in a fast approach which could potentially be implemented in practical, real-time applications.

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光伏系统的启发式功率优化方法

加州正在努力到2020年将分布式发电(DG)的渗透率提高到33%。这一努力是为了促进加州的能源独立，并引领全国更有环保意识。然而，整合DG和提高渗透率将对电网产生负面影响。已经讨论过的一个问题是DG可能提供比负载所需更多的功率。这可能会在连接DG的总线上导致过电压问题，也可能导致电力从配电流向传输系统。现行法规规定DG必须以单位功率因数运行，并禁止DG注入或吸收无功功率。这是为了确保公用事业公司可以控制系统电压，而客户不调节互连点的电压。然而，当考虑系统性能时，这种立法并不理想。本文的任务是提供令人信服的数据，以证明控制无功功率对提高系统性能的好处。此外，它将提供一种启发式方法，以一种快速的方法计算配电系统中DG的近最佳调度，这种方法可能在实际的实时应用中实现。

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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2014 North American Power Symposium (NAPS)

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