Modeling of Secondary Voltage Regulation for 24-hour load flow and dynamic simulation for coordinated voltage control application

2011 IEEE Student Conference on Research and Development Pub Date : 2011-12-01 DOI:10.1109/SCORED.2011.6148735

S. K. S. Abdullah, I. Abidin, I. Musirin, D. M. Nor

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引用次数: 3

Abstract

Effective and efficient management of voltage and reactive power devices is one of the most challenging tasks in power grid operation especially in a large power grid. A Coordinated Voltage Control (CVC) approach that consists of primary voltage control (PVR), secondary voltage control (SVR) and tertiary voltage control (TVR) is the most effective solutions for reactive power and voltage control. CVC refers to an approach in which secondary voltage control or regulations (SVR) is carried out automatically using a control system that would coordinate the various voltage control equipment to achieve a desired voltage at a pilot node in the system. There are various SVR model has been deployed by power utility for their CVC implementation. In Tenaga Nasional Berhad (TNB) power system, coordinated voltage control system is yet to be implemented, but improvement in the approach and methods to performing secondary voltage control are desirable since it could enhance system performance in terms of reliability and security as well as system losses. To demonstrate the capabilities of SVR within TNB grid system, a preliminary studies has been carried out, where new SVR dynamic model has been developed suitable for TNB CVC system implementation. Since voltage control is a real time activity that repeats itself on a daily basis, it was agreed that a more effective approach to study the process of SVR would be to perform simulations on a 24-hour basis where at defined times during the day the SVR would be applied. Two simulations approach has been carried: 24-hour load flow and 24-hour dynamic simulation, both implemented using PSS/E simulation software. From studies conducted, it is clear that implementation of SVR system can bring great potential and benefits to TNB in-term of system loss reduction, better voltage profile, and control and effective utilization of reactive power resources.

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24小时负荷流二次调压建模及电压协调控制动态仿真

电压和无功设备的有效和高效管理是电网运行中最具挑战性的任务之一，特别是在大型电网中。由一次电压控制(PVR)、二次电压控制(SVR)和三次电压控制(TVR)组成的协调电压控制(CVC)方法是无功和电压控制的最有效解决方案。CVC是一种利用控制系统自动进行二次电压控制或调节(SVR)的方法，该控制系统将协调各种电压控制设备，以在系统的一个先导节点上达到所需的电压。电力公司为了实现CVC，已经部署了各种SVR模型。在Tenaga国家电力公司(TNB)电力系统中，协调电压控制系统尚未实施，但需要改进执行二次电压控制的方法和方法，因为它可以在可靠性和安全性以及系统损耗方面提高系统性能。为了证明SVR在TNB网格系统中的能力，本文进行了初步的研究，开发了适合TNB CVC系统实现的新的SVR动态模型。由于电压控制是一种每天重复的实时活动，因此大家一致认为，研究SVR过程的更有效方法是在24小时的基础上进行模拟，在一天中的特定时间应用SVR。采用PSS/E仿真软件实现24小时负荷流仿真和24小时动态仿真两种仿真方法。研究表明，在降低系统损耗、改善电压分布、控制和有效利用无功资源等方面，SVR系统的实施可以为TNB带来巨大的潜力和效益。

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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2011 IEEE Student Conference on Research and Development

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