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Journals & Magazines >IEEE Transactions on Power De... >Volume: 19 Issue: 3

Transmission system parameters optimization-sensitivity analysis of secondary arc current and recovery voltage

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M.C. Tavares; C.M. Portela
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Abstract:

This paper shows the importance of optimizing the transmission system parameters from its conception, considering the relevant options and possibilities, in order to have...Show More

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Abstract:

This paper shows the importance of optimizing the transmission system parameters from its conception, considering the relevant options and possibilities, in order to have a better cost-performance result. The presented results were obtained in the study of a real transmission system expansion, based on a 865-km long line. The single-phase auto-reclosing (SPAR) procedure was one of the aspects carefully studied, in order to assure adequate transmission reliability. The secondary arc current was mitigated through the traditional solution of using the neutral reactor on the existing shunt reactor banks, which permitted the reduction of the secondary arc current to acceptable values, assuring natural arc extinction and successful SPAR. The method of obtaining the optimized value for the neutral reactor and its implications on the system performance are important aspects, and are discussed in this paper.
Published in: IEEE Transactions on Power Delivery ( Volume: 19, Issue: 3, July 2004)
Page(s): 1464 - 1471
Date of Publication: 28 June 2004

ISSN Information:

DOI: 10.1109/TPWRD.2004.829158
References is not available for this document.
Contents

I. Introduction

When planning a new transmission system, or a system expansion, it is important to think carefully in all the aspects, which can imply in a better performance and also in lower cost. In order to obtain the best cost-performance result, it is important to consider altogether the relevant options and possibilities in the first stages of study, when the basic system conception is defined. In fact, some interesting solutions imply in joint measures and coordinated choices, and can hardly be detected if different aspects are dealt with separately or sequentially, as is done in many system studies. The joint evaluation of different aspects is critical when nonconventional solutions are considered, as is the case of long-distance transmission systems, for which extrapolation of common practice would lead to solutions quite far from optimum. As an example, we present some aspects of a real transmission system-expansion study. This system has some specific constraints, which are summarized as follows.

The previous electric system supplies some small loads.

A new load, which shall be mainly a static load, is located 865 km from the main generation plant.

The load will be 400 MW at the beginning and may increase in the future to 800 MW.

The load shall be attended through a single 420-kV three-phase transmission line.

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