Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio

Transmission towers are a vital lifeline for modern living and are crucial structures that must remain operational even after a seismic event. However, the towers are largely designed to withstand the effects of wind alone and not earthquakes, and the seismic influences on tower design and construct...

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Main Authors: Kassem M.M., Beddu S., Min W.Q., Tan C.G., Nazri F.M.
Other Authors: 57205114345
Format: Article
Published: MDPI 2023
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spelling my.uniten.dspace-269732023-05-29T17:38:18Z Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio Kassem M.M. Beddu S. Min W.Q. Tan C.G. Nazri F.M. 57205114345 55812080500 57455987100 55597176000 55195912500 Transmission towers are a vital lifeline for modern living and are crucial structures that must remain operational even after a seismic event. However, the towers are largely designed to withstand the effects of wind alone and not earthquakes, and the seismic influences on tower design and construction have hitherto been ignored. The purpose of this study was to evaluate the seismic performance of a latticed steel transmission tower-line system that is subjected to a variety of seismic situations (Far-Field, Near-Field and Repeated Earthquakes) using probabilistic vulnerability functions and Collapse Margin Ratios in accordance with FEMA-P695. Nonlinear Time History Analyses were performed by incorporating an array of 36 strong ground motions to develop the Incremental Dynamic Analysis and to generate the fragility functions for three performance limit states as referenced in FEMA 356. The results showed that the single event seismic performance of the tower is better than its performance after multiple ground motions owing to aftershock impact, while near-field excitations led to greater susceptibility and fragility than far-field scenarios. Thus, near-field ground motion is more harmful to the tower and could result in its failure or collapse with only a small reduction in damage relative to the impact of the aftershock. � 2022 by the authors. Licensee MDPI, Basel, Switzerland. Final 2023-05-29T09:38:17Z 2023-05-29T09:38:17Z 2022 Article 10.3390/app12041984 2-s2.0-85124767713 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85124767713&doi=10.3390%2fapp12041984&partnerID=40&md5=f92966280c6310a840a1ab9019a41af1 https://irepository.uniten.edu.my/handle/123456789/26973 12 4 1984 All Open Access, Gold MDPI Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
description Transmission towers are a vital lifeline for modern living and are crucial structures that must remain operational even after a seismic event. However, the towers are largely designed to withstand the effects of wind alone and not earthquakes, and the seismic influences on tower design and construction have hitherto been ignored. The purpose of this study was to evaluate the seismic performance of a latticed steel transmission tower-line system that is subjected to a variety of seismic situations (Far-Field, Near-Field and Repeated Earthquakes) using probabilistic vulnerability functions and Collapse Margin Ratios in accordance with FEMA-P695. Nonlinear Time History Analyses were performed by incorporating an array of 36 strong ground motions to develop the Incremental Dynamic Analysis and to generate the fragility functions for three performance limit states as referenced in FEMA 356. The results showed that the single event seismic performance of the tower is better than its performance after multiple ground motions owing to aftershock impact, while near-field excitations led to greater susceptibility and fragility than far-field scenarios. Thus, near-field ground motion is more harmful to the tower and could result in its failure or collapse with only a small reduction in damage relative to the impact of the aftershock. � 2022 by the authors. Licensee MDPI, Basel, Switzerland.
author2 57205114345
author_facet 57205114345
Kassem M.M.
Beddu S.
Min W.Q.
Tan C.G.
Nazri F.M.
format Article
author Kassem M.M.
Beddu S.
Min W.Q.
Tan C.G.
Nazri F.M.
spellingShingle Kassem M.M.
Beddu S.
Min W.Q.
Tan C.G.
Nazri F.M.
Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
author_sort Kassem M.M.
title Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
title_short Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
title_full Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
title_fullStr Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
title_full_unstemmed Quantification of the Seismic Behavior of a Steel Transmission Tower Subjected to Single and Repeated Seismic Excitations Using Vulnerability Function and Collapse Margin Ratio
title_sort quantification of the seismic behavior of a steel transmission tower subjected to single and repeated seismic excitations using vulnerability function and collapse margin ratio
publisher MDPI
publishDate 2023
_version_ 1806428370006704128
score 13.214268