Continuation Power Flow: a Parameterization Technique and Adaptive Step Size Control

2021 IEEE URUCON Pub Date : 2021-11-24 DOI:10.1109/urucon53396.2021.9647090

A. B. Neto, Luís Roberto Almeida Gabriel Filho, D. Alves

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Abstract

The electricity sector, especially in emerging countries, has experienced several transformations, mainly resulting from the increase in electricity demand. These events encourage more investment in the generation sector and cause increasing concerns with the development and improvement of tools for static voltage stability analysis of electrical power systems. This paper presents a new geometric parameterization technique for continuation power flow (CPF) that works based on the addition of a new plane formed by the variables of voltage magnitudes and total real power losses (Pa). The new plane features a linear aspect around the maximum loading point (MLP), eliminating the Jacobian matrix (J) singularity at the maximum loading point, allowing to obtain the solution trajectory (P-V curve) without any need to change the parameter, which is a common procedure in the currently available CPF. Intending to define a simple and efficient step size control procedure, the distance value between the center of the set of lines and the total real power losses is calculated. This value defines the appropriate step size for the system. The results obtained by applying the proposed technique to the IEEE 14-bus system and one real large system of the 904-bus show its effectiveness.

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连续潮流:参数化技术与自适应步长控制

电力部门，特别是在新兴国家，经历了几次转变，主要是由于电力需求的增加。这些事件鼓励了对发电部门的更多投资，并引起了人们对电力系统静态电压稳定性分析工具的开发和改进的日益关注。本文提出了一种新的连续潮流几何参数化技术，该技术基于电压幅值和总实际功率损耗(Pa)组成的新平面的添加。新平面在最大加载点(MLP)周围具有线性外形，消除了最大加载点处的雅可比矩阵(J)奇点，无需改变参数即可获得解轨迹(P-V曲线)，这是目前可用的CPF中常见的程序。为了定义一种简单有效的步长控制方法，计算了线组中心与实际总损耗之间的距离值。该值定义了系统的适当步长。将该技术应用于IEEE 14总线系统和904总线的实际大型系统，结果表明了该技术的有效性。

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 IEEE URUCON

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