The effects of major solar integration on a 21-Bus system: Technology review and PSAT simulations

SoutheastCon 2017 Pub Date : 2017-03-01 DOI:10.1109/SECON.2017.7925361

B. Belcher, Benjamin J. Petry, T. Davis, K. Hatipoglu

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引用次数: 4

Abstract

The world's energy needs are changing and so are the methods by which it generates power. Photovoltaic Cells are leading this revolution by harnessing the power of the sun and transforming it into DC power. Integrating this “too good to be true” power source into the grid has been in the mind of those who plan for future grid alterations for a while and the need for seamless integration has arrived. Power systems and power-flow through the grid are planned precisely and do not respond well to sudden changes. Large-scale PV grid integration is challenging and requires preparation to deal with the intermittency of power production. This paper analyzes an IEEE 21-Bus power system with regards to power-flow and small to large scale integration of PV generation. The pros and cons of this addition are researched and documented here as well as simulations of PV integration using Matlab's Power System Analysis Toolbox (PSAT) software. There are a few correction methods that attempt to solve some of the known problems with adding solar generation into the grid such as tap-changer transformers, capacitor banks, and synchronous condensers. Besides normal analysis, this paper also presents one of these correction methods into simulation to show how part of the large-scale integration problem can be corrected.

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主要太阳能集成对21总线系统的影响:技术回顾和PSAT模拟

世界的能源需求正在发生变化，其发电方式也在发生变化。光伏电池通过利用太阳能并将其转化为直流电，引领了这场革命。将这种“好得令人难以置信”的电源集成到电网中，已经在那些计划未来电网改造的人的脑海中存在了一段时间，无缝集成的需求已经到来。电力系统和通过电网的电力流是精确规划的，不能很好地应对突然变化。大规模光伏并网具有挑战性，需要为应对电力生产的间歇性做好准备。本文分析了IEEE 21总线电力系统的潮流和光伏发电的小到大规模集成。本文对这一特性的优缺点进行了研究和记录，并使用Matlab的电力系统分析工具箱(PSAT)软件对PV集成进行了模拟。有一些校正方法试图解决一些已知的问题，如分接开关变压器、电容器组和同步冷凝器。除常规分析外，本文还将其中一种校正方法应用到仿真中，以说明如何对部分大规模积分问题进行校正。

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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SoutheastCon 2017

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