Optimal Power Flow With Dynamic Line Rating Using Quadratically Constrained Quadratic Program Method

2021 1st International Conference on Electronic and Electrical Engineering and Intelligent System (ICE3IS) Pub Date : 2021-10-15 DOI:10.1109/ice3is54102.2021.9649715

Nurdin Sugiantoro, R. S. Wibowo, V. Lystianingrum, Eki Rovianto, S. Triwijaya

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引用次数: 1

Abstract

This research integrates the dynamic line rating system into an optimal power flow problem. The application is to calculate the line rating using the heat balance equation based on its temperature rating. As a result, line rating that is usually static can be dynamic that makes the value higher so the system would be better. But because of this, the problem of optimal power flow becomes more difficult because of the addition of temperature variable control and heat balance equation constraint that are quite complex. The modelling also requires considering transmission losses into the Direct Current Optimal Power Flow (DCOPF) problem. This study uses a quadratically constrained quadratic program method in a direct current optimal power flow problem considering transmission losses with the integration of dynamic line rating based on the heat balance equation. Testing method are performed on IEEE 9 bus and 30 bus system. The results show that the method used can accommodate the heat balance equation and show that the integration of dynamic line rating makes the system more economical.

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基于二次约束二次规划方法的动态线路额定最优潮流

本研究将动态线路额定值系统整合为最优潮流问题。应用程序是根据其温度额定值使用热平衡方程来计算线路额定值。因此，通常是静态的线路额定值可以是动态的，这使得该值更高，从而使系统更好。但由于加入了较为复杂的变温控制和热平衡方程约束，使得最优潮流问题变得更加困难。该模型还要求在直流最优潮流问题中考虑传输损耗。在热平衡方程的基础上，采用二次约束二次规划方法求解考虑输电损耗的直流最优潮流问题。在ieee9总线和ieee30总线系统上进行了测试。结果表明，所采用的方法能够适应热平衡方程，并表明动态线路额定值的集成使系统更加经济。

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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2021 1st International Conference on Electronic and Electrical Engineering and Intelligent System (ICE3IS)

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