Blasting response of the Eiffel Tower

Lachlan Horlyck; Kieran Hayes; Ryan Caetano; Faham Tahmasebinia; Peter Ansourian; Fernando Alonso-Marroquin

doi:10.1063/1.4961101

Blasting response of the Eiffel Tower

Lachlan Horlyck, Kieran Hayes, Ryan Caetano, Faham Tahmasebinia, Peter Ansourian, Fernando Alonso-Marroquin^*

^*Corresponding author for this work

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

1 Scopus citations

Abstract

A finite element model of the Eiffel Tower was constructed using Strand7 software. The model replicates the existing tower, with dimensions justified through the use of original design drawings. A static and dynamic analysis was conducted to determine the actions of the tower under permanent, imposed and wind loadings, as well as under blast pressure loads and earthquake loads due to an explosion. It was observed that the tower utilises the full axial capacity of individual members by acting as a 'truss of trusses'. As such, permanent and imposed loads are efficiently transferred to the primary columns through compression, while wind loads induce tensile forces in the windward legs and compressive forces in the leeward. Under blast loading, the tower experienced both ground vibrations and blast pressures. Ground vibrations induced a negligibly small earthquake loading into the structure which was ignored in subsequent analyses. The blast pressure was significant, and a dynamic analysis of this revealed that further research is required into the damping qualities of the structure due to soil and mechanical properties. In the worst case scenario, the blast was assumed to completely destroy several members in the adjacent leg. Despite this weakened condition, it was observed that the tower would still be able to sustain static loads, at least for enough time for occupant evacuation. Further, an optimised design revealed the structure was structurally sound under a 46% reduction of the metal tower's mass.

Original language	English
Title of host publication	Numerical Methods in Civil Engineering
Subtitle of host publication	Dynamics of Structures 2016
Editors	Fernando Alonso-Marroquin
Publisher	American Institute of Physics Inc.
ISBN (Electronic)	9780735414204
DOIs	https://doi.org/10.1063/1.4961101
State	Published - 11 Aug 2016
Externally published	Yes
Event	Numerical Methods in Civil Engineering: Dynamics of Structures 2016 - Sydney, Australia Duration: 23 May 2016 → 1 Jun 2016

Publication series

Name	AIP Conference Proceedings
Volume	1762
ISSN (Print)	0094-243X
ISSN (Electronic)	1551-7616

Conference

Conference	Numerical Methods in Civil Engineering: Dynamics of Structures 2016
Country/Territory	Australia
City	Sydney
Period	23/05/16 → 1/06/16

Bibliographical note

Publisher Copyright:
© 2016 Author(s).

ASJC Scopus subject areas

General Physics and Astronomy

Access to Document

10.1063/1.4961101

Cite this

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title = "Blasting response of the Eiffel Tower",

abstract = "A finite element model of the Eiffel Tower was constructed using Strand7 software. The model replicates the existing tower, with dimensions justified through the use of original design drawings. A static and dynamic analysis was conducted to determine the actions of the tower under permanent, imposed and wind loadings, as well as under blast pressure loads and earthquake loads due to an explosion. It was observed that the tower utilises the full axial capacity of individual members by acting as a 'truss of trusses'. As such, permanent and imposed loads are efficiently transferred to the primary columns through compression, while wind loads induce tensile forces in the windward legs and compressive forces in the leeward. Under blast loading, the tower experienced both ground vibrations and blast pressures. Ground vibrations induced a negligibly small earthquake loading into the structure which was ignored in subsequent analyses. The blast pressure was significant, and a dynamic analysis of this revealed that further research is required into the damping qualities of the structure due to soil and mechanical properties. In the worst case scenario, the blast was assumed to completely destroy several members in the adjacent leg. Despite this weakened condition, it was observed that the tower would still be able to sustain static loads, at least for enough time for occupant evacuation. Further, an optimised design revealed the structure was structurally sound under a 46\% reduction of the metal tower's mass.",

author = "Lachlan Horlyck and Kieran Hayes and Ryan Caetano and Faham Tahmasebinia and Peter Ansourian and Fernando Alonso-Marroquin",

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Horlyck, L, Hayes, K, Caetano, R, Tahmasebinia, F, Ansourian, P & Alonso-Marroquin, F 2016, Blasting response of the Eiffel Tower. in F Alonso-Marroquin (ed.), Numerical Methods in Civil Engineering: Dynamics of Structures 2016., 020003, AIP Conference Proceedings, vol. 1762, American Institute of Physics Inc., Numerical Methods in Civil Engineering: Dynamics of Structures 2016, Sydney, Australia, 23/05/16. https://doi.org/10.1063/1.4961101

Blasting response of the Eiffel Tower. / Horlyck, Lachlan; Hayes, Kieran; Caetano, Ryan et al.
Numerical Methods in Civil Engineering: Dynamics of Structures 2016. ed. / Fernando Alonso-Marroquin. American Institute of Physics Inc., 2016. 020003 (AIP Conference Proceedings; Vol. 1762).

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

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AB - A finite element model of the Eiffel Tower was constructed using Strand7 software. The model replicates the existing tower, with dimensions justified through the use of original design drawings. A static and dynamic analysis was conducted to determine the actions of the tower under permanent, imposed and wind loadings, as well as under blast pressure loads and earthquake loads due to an explosion. It was observed that the tower utilises the full axial capacity of individual members by acting as a 'truss of trusses'. As such, permanent and imposed loads are efficiently transferred to the primary columns through compression, while wind loads induce tensile forces in the windward legs and compressive forces in the leeward. Under blast loading, the tower experienced both ground vibrations and blast pressures. Ground vibrations induced a negligibly small earthquake loading into the structure which was ignored in subsequent analyses. The blast pressure was significant, and a dynamic analysis of this revealed that further research is required into the damping qualities of the structure due to soil and mechanical properties. In the worst case scenario, the blast was assumed to completely destroy several members in the adjacent leg. Despite this weakened condition, it was observed that the tower would still be able to sustain static loads, at least for enough time for occupant evacuation. Further, an optimised design revealed the structure was structurally sound under a 46% reduction of the metal tower's mass.

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Blasting response of the Eiffel Tower

Abstract

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