Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally

Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally

The aim of this work was to work out the mechanical stresses within transformer resulting from the extreme short-circuit currents. The forces and stresses set up in transformer windings as the result of exterior or interior short-circuits or of switching operations, are measured in detail. A variety...

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Main Authors: Ashfaq Ahmad, Iqra Javed, Waseem Nazar, M. Asim Mukhtar
Format: Article
Language:English
Published: Elsevier 2018-03-01
Series:Alexandria Engineering Journal
Online Access:http://www.sciencedirect.com/science/article/pii/S1110016816302976
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spelling doaj-4b649c09b5594328a1e61bced71e6adb2021-06-02T09:34:21ZengElsevierAlexandria Engineering Journal1110-01682018-03-01571147157Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & HorizontallyAshfaq Ahmad0Iqra Javed1Waseem Nazar2M. Asim Mukhtar3The University of Lahore, Department of Electronics, 1-km Raiwind Road, Lahore, Pakistan; Corresponding author.University of Management and Technology, Department of Informatics and Systems, Lahore, PakistanThe University of Lahore, Department of Electronics, 1-km Raiwind Road, Lahore, PakistanThe University of Lahore, Department of Electronics, 1-km Raiwind Road, Lahore, PakistanThe aim of this work was to work out the mechanical stresses within transformer resulting from the extreme short-circuit currents. The forces and stresses set up in transformer windings as the result of exterior or interior short-circuits or of switching operations, are measured in detail. A variety of arrangements of windings in large power transformers are described. Points at which mostly high mechanical stresses take place in concentric windings are discussed in detail. Analytical and FEM calculations for individual short circuit forces, axial and radial have been discussed. The result was then compared with actual measurements on a prototype 20 MVA 132/11.5 kV power transformer [15]. Various failure mechanisms due to these forces have been discussed. Design parameters are also discussed, whose values determine the maximum stresses which may occur in any part of the transformer. Effects of irregularity in various parts and various properties of materials have been studied and the usage of appropriate material for withstanding the dynamic effects of SC is discussed. Effect of workmanship errors on short circuit withstand capability has also elucidated. Finally, a complete model is developed. Keywords: Finite element method, Power transformer, Short circuit stress, Mechanical stresses, Axial and radial stresses, High voltage windinghttp://www.sciencedirect.com/science/article/pii/S1110016816302976
collection DOAJ
language English
format Article
sources DOAJ
author Ashfaq Ahmad
Iqra Javed
Waseem Nazar
M. Asim Mukhtar
spellingShingle Ashfaq Ahmad
Iqra Javed
Waseem Nazar
M. Asim Mukhtar
Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
Alexandria Engineering Journal
author_facet Ashfaq Ahmad
Iqra Javed
Waseem Nazar
M. Asim Mukhtar
author_sort Ashfaq Ahmad
title Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
title_short Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
title_full Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
title_fullStr Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
title_full_unstemmed Short Circuit Stress Analysis Using FEM in Power Transformer on H-V Winding Displaced Vertically & Horizontally
title_sort short circuit stress analysis using fem in power transformer on h-v winding displaced vertically & horizontally
publisher Elsevier
series Alexandria Engineering Journal
issn 1110-0168
publishDate 2018-03-01
description The aim of this work was to work out the mechanical stresses within transformer resulting from the extreme short-circuit currents. The forces and stresses set up in transformer windings as the result of exterior or interior short-circuits or of switching operations, are measured in detail. A variety of arrangements of windings in large power transformers are described. Points at which mostly high mechanical stresses take place in concentric windings are discussed in detail. Analytical and FEM calculations for individual short circuit forces, axial and radial have been discussed. The result was then compared with actual measurements on a prototype 20 MVA 132/11.5 kV power transformer [15]. Various failure mechanisms due to these forces have been discussed. Design parameters are also discussed, whose values determine the maximum stresses which may occur in any part of the transformer. Effects of irregularity in various parts and various properties of materials have been studied and the usage of appropriate material for withstanding the dynamic effects of SC is discussed. Effect of workmanship errors on short circuit withstand capability has also elucidated. Finally, a complete model is developed. Keywords: Finite element method, Power transformer, Short circuit stress, Mechanical stresses, Axial and radial stresses, High voltage winding
url http://www.sciencedirect.com/science/article/pii/S1110016816302976
work_keys_str_mv AT ashfaqahmad shortcircuitstressanalysisusingfeminpowertransformeronhvwindingdisplacedverticallyhorizontally
AT iqrajaved shortcircuitstressanalysisusingfeminpowertransformeronhvwindingdisplacedverticallyhorizontally
AT waseemnazar shortcircuitstressanalysisusingfeminpowertransformeronhvwindingdisplacedverticallyhorizontally
AT masimmukhtar shortcircuitstressanalysisusingfeminpowertransformeronhvwindingdisplacedverticallyhorizontally
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