An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind

X. Z. Cui; M. Y. Xiao; Z. D. Duan

doi:10.1007/978-3-031-97435-9_23

An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind

X. Z. Cui^*
, M. Y. Xiao
, Z. D. Duan

^*Corresponding author for this work

School of Intelligent Civil and Ocean Engineering, Harbin Institute of Technology Shenzhen

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Electrical transmission tower-line systems form the backbone of our modern society, facilitating the seamless distribution of power over vast distances. The failure of any transmission tower among the line system can result in regional disruptions to power supply. Thunderstorm wind events pose significant threats to the structural integrity of transmission towers, making their fragility analysis crucial for ensuring the reliability and resilience of the power distribution systems. Deriving the fragility curve of transmission towers involves assessing the evolution of the joint probability density function of their responses. The structural response of these towers during the thunderstorm wind event always exhibits nonlinear characteristics; therefore, the nonlinear time-history analysis by using the finite element analysis is always adopted. However, conducting the time-history analysis for such scenarios is notably time-consuming, especially when combine the Monte Carlo simulation techniques and time-history analysis for fragility analysis. In the present study, an efficient procedure for the fragility analysis of the transmission tower subjected to bidirectional thunderstorm wind is described. The modeling of the wind field involves decomposing the thunderstorm wind into a time-varying mean wind velocity and a residual nonstationary fluctuation. The time-varying mean wind velocity is extracted from recorded thunderstorm wind data, and the variation along height is assumed to be proportional to the derived time-varying mean wind velocity. The nonstationary fluctuation is modeled as spatiotemporally varying by considering the incoherent effect and simulated using spectral representation method. For the modeling of the transmission tower, the uncertainty involved in yield strength and elastic modulus is considered. The proposed procedure incorporates a probability concentration-based simulation, combining aspects of the point estimate method and Latin hypercube sampling. Additionally, it employs a weighted (kernel) smoothing technique using simulated samples to estimate the evolution of joint probability density functions for tower responses. Finally, the time-dependent distribution of the transmission tower‘s top displacement subjected to thunderstorm wind is presented, demonstrating the effectiveness of the proposed procedure in assessing and understanding the vulnerability of these vital structures to such wind events.

Original language	English
Title of host publication	Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering
Editors	Ehab Elsalakawy, Ahmed Elshaer, Ayman El Ansary
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	261-273
Number of pages	13
ISBN (Print)	9783031974342
DOIs	https://doi.org/10.1007/978-3-031-97435-9_23
State	Published - 2025
Externally published	Yes
Event	Canadian Society of Civil Engineering Annual Conference, CSCE 2024 - Niagara Falls, Canada Duration: 5 Jun 2024 → 7 Jun 2024

Publication series

Name	Lecture Notes in Civil Engineering
Volume	694 LNCE
ISSN (Print)	2366-2557
ISSN (Electronic)	2366-2565

Conference

Conference	Canadian Society of Civil Engineering Annual Conference, CSCE 2024
Country/Territory	Canada
City	Niagara Falls
Period	5/06/24 → 7/06/24

Keywords

Fragility analysis
Kernel smoothing
Thunderstorm wind
Transmission tower

Access to Document

10.1007/978-3-031-97435-9_23

Cite this

Cui, X. Z., Xiao, M. Y., & Duan, Z. D. (2025). An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind. In E. Elsalakawy, A. Elshaer, & A. El Ansary (Eds.), Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering (pp. 261-273). (Lecture Notes in Civil Engineering; Vol. 694 LNCE). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-97435-9_23

Cui, X. Z. ; Xiao, M. Y. ; Duan, Z. D. / An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind. Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering. editor / Ehab Elsalakawy ; Ahmed Elshaer ; Ayman El Ansary. Springer Science and Business Media Deutschland GmbH, 2025. pp. 261-273 (Lecture Notes in Civil Engineering).

@inproceedings{e1733d515a2a47eea61332d1559a4c75,

title = "An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind",

abstract = "Electrical transmission tower-line systems form the backbone of our modern society, facilitating the seamless distribution of power over vast distances. The failure of any transmission tower among the line system can result in regional disruptions to power supply. Thunderstorm wind events pose significant threats to the structural integrity of transmission towers, making their fragility analysis crucial for ensuring the reliability and resilience of the power distribution systems. Deriving the fragility curve of transmission towers involves assessing the evolution of the joint probability density function of their responses. The structural response of these towers during the thunderstorm wind event always exhibits nonlinear characteristics; therefore, the nonlinear time-history analysis by using the finite element analysis is always adopted. However, conducting the time-history analysis for such scenarios is notably time-consuming, especially when combine the Monte Carlo simulation techniques and time-history analysis for fragility analysis. In the present study, an efficient procedure for the fragility analysis of the transmission tower subjected to bidirectional thunderstorm wind is described. The modeling of the wind field involves decomposing the thunderstorm wind into a time-varying mean wind velocity and a residual nonstationary fluctuation. The time-varying mean wind velocity is extracted from recorded thunderstorm wind data, and the variation along height is assumed to be proportional to the derived time-varying mean wind velocity. The nonstationary fluctuation is modeled as spatiotemporally varying by considering the incoherent effect and simulated using spectral representation method. For the modeling of the transmission tower, the uncertainty involved in yield strength and elastic modulus is considered. The proposed procedure incorporates a probability concentration-based simulation, combining aspects of the point estimate method and Latin hypercube sampling. Additionally, it employs a weighted (kernel) smoothing technique using simulated samples to estimate the evolution of joint probability density functions for tower responses. Finally, the time-dependent distribution of the transmission tower{\textquoteleft}s top displacement subjected to thunderstorm wind is presented, demonstrating the effectiveness of the proposed procedure in assessing and understanding the vulnerability of these vital structures to such wind events.",

keywords = "Fragility analysis, Kernel smoothing, Thunderstorm wind, Transmission tower",

author = "Cui, \{X. Z.\} and Xiao, \{M. Y.\} and Duan, \{Z. D.\}",

note = "Publisher Copyright: {\textcopyright} Canadian Society for Civil Engineering 2025.; Canadian Society of Civil Engineering Annual Conference, CSCE 2024 ; Conference date: 05-06-2024 Through 07-06-2024",

year = "2025",

doi = "10.1007/978-3-031-97435-9\_23",

language = "英语",

isbn = "9783031974342",

series = "Lecture Notes in Civil Engineering",

publisher = "Springer Science and Business Media Deutschland GmbH",

pages = "261--273",

editor = "Ehab Elsalakawy and Ahmed Elshaer and \{El Ansary\}, Ayman",

booktitle = "Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering",

address = "德国",

}

Cui, XZ, Xiao, MY & Duan, ZD 2025, An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind. in E Elsalakawy, A Elshaer & A El Ansary (eds), Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering. Lecture Notes in Civil Engineering, vol. 694 LNCE, Springer Science and Business Media Deutschland GmbH, pp. 261-273, Canadian Society of Civil Engineering Annual Conference, CSCE 2024, Niagara Falls, Canada, 5/06/24. https://doi.org/10.1007/978-3-031-97435-9_23

An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind. / Cui, X. Z.; Xiao, M. Y.; Duan, Z. D.
Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering. ed. / Ehab Elsalakawy; Ahmed Elshaer; Ayman El Ansary. Springer Science and Business Media Deutschland GmbH, 2025. p. 261-273 (Lecture Notes in Civil Engineering; Vol. 694 LNCE).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind

AU - Cui, X. Z.

AU - Xiao, M. Y.

AU - Duan, Z. D.

N1 - Publisher Copyright: © Canadian Society for Civil Engineering 2025.

PY - 2025

Y1 - 2025

N2 - Electrical transmission tower-line systems form the backbone of our modern society, facilitating the seamless distribution of power over vast distances. The failure of any transmission tower among the line system can result in regional disruptions to power supply. Thunderstorm wind events pose significant threats to the structural integrity of transmission towers, making their fragility analysis crucial for ensuring the reliability and resilience of the power distribution systems. Deriving the fragility curve of transmission towers involves assessing the evolution of the joint probability density function of their responses. The structural response of these towers during the thunderstorm wind event always exhibits nonlinear characteristics; therefore, the nonlinear time-history analysis by using the finite element analysis is always adopted. However, conducting the time-history analysis for such scenarios is notably time-consuming, especially when combine the Monte Carlo simulation techniques and time-history analysis for fragility analysis. In the present study, an efficient procedure for the fragility analysis of the transmission tower subjected to bidirectional thunderstorm wind is described. The modeling of the wind field involves decomposing the thunderstorm wind into a time-varying mean wind velocity and a residual nonstationary fluctuation. The time-varying mean wind velocity is extracted from recorded thunderstorm wind data, and the variation along height is assumed to be proportional to the derived time-varying mean wind velocity. The nonstationary fluctuation is modeled as spatiotemporally varying by considering the incoherent effect and simulated using spectral representation method. For the modeling of the transmission tower, the uncertainty involved in yield strength and elastic modulus is considered. The proposed procedure incorporates a probability concentration-based simulation, combining aspects of the point estimate method and Latin hypercube sampling. Additionally, it employs a weighted (kernel) smoothing technique using simulated samples to estimate the evolution of joint probability density functions for tower responses. Finally, the time-dependent distribution of the transmission tower‘s top displacement subjected to thunderstorm wind is presented, demonstrating the effectiveness of the proposed procedure in assessing and understanding the vulnerability of these vital structures to such wind events.

AB - Electrical transmission tower-line systems form the backbone of our modern society, facilitating the seamless distribution of power over vast distances. The failure of any transmission tower among the line system can result in regional disruptions to power supply. Thunderstorm wind events pose significant threats to the structural integrity of transmission towers, making their fragility analysis crucial for ensuring the reliability and resilience of the power distribution systems. Deriving the fragility curve of transmission towers involves assessing the evolution of the joint probability density function of their responses. The structural response of these towers during the thunderstorm wind event always exhibits nonlinear characteristics; therefore, the nonlinear time-history analysis by using the finite element analysis is always adopted. However, conducting the time-history analysis for such scenarios is notably time-consuming, especially when combine the Monte Carlo simulation techniques and time-history analysis for fragility analysis. In the present study, an efficient procedure for the fragility analysis of the transmission tower subjected to bidirectional thunderstorm wind is described. The modeling of the wind field involves decomposing the thunderstorm wind into a time-varying mean wind velocity and a residual nonstationary fluctuation. The time-varying mean wind velocity is extracted from recorded thunderstorm wind data, and the variation along height is assumed to be proportional to the derived time-varying mean wind velocity. The nonstationary fluctuation is modeled as spatiotemporally varying by considering the incoherent effect and simulated using spectral representation method. For the modeling of the transmission tower, the uncertainty involved in yield strength and elastic modulus is considered. The proposed procedure incorporates a probability concentration-based simulation, combining aspects of the point estimate method and Latin hypercube sampling. Additionally, it employs a weighted (kernel) smoothing technique using simulated samples to estimate the evolution of joint probability density functions for tower responses. Finally, the time-dependent distribution of the transmission tower‘s top displacement subjected to thunderstorm wind is presented, demonstrating the effectiveness of the proposed procedure in assessing and understanding the vulnerability of these vital structures to such wind events.

KW - Fragility analysis

KW - Kernel smoothing

KW - Thunderstorm wind

KW - Transmission tower

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T3 - Lecture Notes in Civil Engineering

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BT - Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering

A2 - Elsalakawy, Ehab

A2 - Elshaer, Ahmed

A2 - El Ansary, Ayman

PB - Springer Science and Business Media Deutschland GmbH

T2 - Canadian Society of Civil Engineering Annual Conference, CSCE 2024

Y2 - 5 June 2024 through 7 June 2024

ER -

Cui XZ, Xiao MY, Duan ZD. An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind. In Elsalakawy E, Elshaer A, El Ansary A, editors, Proceedings of the Canadian Society for Civil Engineering Annual Conference 2024, Volume 11 - Structural Engineering. Springer Science and Business Media Deutschland GmbH. 2025. p. 261-273. (Lecture Notes in Civil Engineering). doi: 10.1007/978-3-031-97435-9_23

An Efficient Procedure for Fragility Analysis of Transmission Tower Subjected to Thunderstorm Wind

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