Computation of transmission line transients including corona effects

Xiao rong Li; O. P. Malik; Zhi da Zhao

doi:10.1109/61.32677

Computation of transmission line transients including corona effects

Xiao rong Li
, O. P. Malik
, Zhi da Zhao

University of Connecticut
University of Calgary
Zhejiang University

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

An efficient algorithm for computation of transients in parallel multi-conductor transmission systems including corona effects is developed using the finite difference method. A hybrid scheme consisting of both forward and backward differences is used to discretize the telegraphers' equations. This results in a tridiagonal difference equation and turns out to have a regressive solution with good stability and high efficiency. Good agreement is shown between computed and measured results for many cases. The corona model proposed in Ref. [1] is extended to multi-phase cases to match with the algorithm. The two aspects of the corona effect, power loss and change in capacitance, are combined by simply simulating a nonlinear capacitor having the same charge-voltage characteristics as the line in corona.

Original language	English
Pages (from-to)	1816-1822
Number of pages	7
Journal	IEEE Transactions on Power Delivery
Volume	4
Issue number	3
DOIs	https://doi.org/10.1109/61.32677
State	Published - Jul 1989
Externally published	Yes

Keywords

Corona
Transients Computation
Transmission line transients

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10.1109/61.32677

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title = "Computation of transmission line transients including corona effects",

abstract = "An efficient algorithm for computation of transients in parallel multi-conductor transmission systems including corona effects is developed using the finite difference method. A hybrid scheme consisting of both forward and backward differences is used to discretize the telegraphers' equations. This results in a tridiagonal difference equation and turns out to have a regressive solution with good stability and high efficiency. Good agreement is shown between computed and measured results for many cases. The corona model proposed in Ref. [1] is extended to multi-phase cases to match with the algorithm. The two aspects of the corona effect, power loss and change in capacitance, are combined by simply simulating a nonlinear capacitor having the same charge-voltage characteristics as the line in corona.",

keywords = "Corona, Transients Computation, Transmission line transients",

author = "Li, \{Xiao rong\} and Malik, \{O. P.\} and Zhao, \{Zhi da\}",

year = "1989",

month = jul,

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volume = "4",

pages = "1816--1822",

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T1 - Computation of transmission line transients including corona effects

AU - Li, Xiao rong

AU - Malik, O. P.

AU - Zhao, Zhi da

PY - 1989/7

Y1 - 1989/7

N2 - An efficient algorithm for computation of transients in parallel multi-conductor transmission systems including corona effects is developed using the finite difference method. A hybrid scheme consisting of both forward and backward differences is used to discretize the telegraphers' equations. This results in a tridiagonal difference equation and turns out to have a regressive solution with good stability and high efficiency. Good agreement is shown between computed and measured results for many cases. The corona model proposed in Ref. [1] is extended to multi-phase cases to match with the algorithm. The two aspects of the corona effect, power loss and change in capacitance, are combined by simply simulating a nonlinear capacitor having the same charge-voltage characteristics as the line in corona.

AB - An efficient algorithm for computation of transients in parallel multi-conductor transmission systems including corona effects is developed using the finite difference method. A hybrid scheme consisting of both forward and backward differences is used to discretize the telegraphers' equations. This results in a tridiagonal difference equation and turns out to have a regressive solution with good stability and high efficiency. Good agreement is shown between computed and measured results for many cases. The corona model proposed in Ref. [1] is extended to multi-phase cases to match with the algorithm. The two aspects of the corona effect, power loss and change in capacitance, are combined by simply simulating a nonlinear capacitor having the same charge-voltage characteristics as the line in corona.

KW - Corona

KW - Transients Computation

KW - Transmission line transients

UR - https://www.scopus.com/pages/publications/0024705155

U2 - 10.1109/61.32677

DO - 10.1109/61.32677

M3 - 文章

AN - SCOPUS:0024705155

SN - 0885-8977

VL - 4

SP - 1816

EP - 1822

JO - IEEE Transactions on Power Delivery

JF - IEEE Transactions on Power Delivery

IS - 3

ER -

Computation of transmission line transients including corona effects

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Keywords

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