Experimental studies to validate an improved approach to the design of acceleration-sensitive nonstructural element
Experimental studies to validate an improved approach to the design of acceleration-sensitive nonstructural element
Nonstructural components in buildings can be subjected to very large acceleration and deformation demands during earthquakes. This is particularly true for flexible components that are tuned or nearly tuned to one of the modal frequencies of the supporting structure. To control the seismic demands in these situations, the authors have proposed a new design approach in which the connections between the structure and the nonstructural element are designed and detailed to experience nonlinearities to limit force and deformation demands. This paper summarizes an experimental campaign sponsored by the Seismology and Earthquake Engineering Research Infrastructure Alliance for Europe (SERA) aimed at validating the proposed design approach. The research project involved subjecting 14 different specimens representing nonstructural elements, with masses ranging from approximately 200 kg to 800 kg, to severe floor motions recorded during the 1989 Loma Prieta and the 1994 Northridge earthquakes in three instrumented buildings in California. A total of 45 individual tests were carried out. The tests were conducted at the EQUALS laboratory shake table at the University of Bristol. Mass and stiffness were carefully selected in each specimen to have vibration periods that resulted in both non-tuned and tuned components to modal frequencies of the supporting structure. Furthermore, some of the tuned tests involved components tuned to the fundamental mode while others were tuned to the second mode of vibration of the supporting structure to examine possible differences. Lateral strength and primary energy dissipation were provided by two steel plates with rotations restrained at both ends and loaded out-of-plane. The tests demonstrated how the proposed approach greatly reduces force and acceleration demands while also reducing lateral displacement demands. Furthermore, tests also demonstrated that the proposed approach reduces the response sensitivity to the period ratio of the nonstructural element to that of the supporting structure leading to a reduction in seismic demands uncertainty.
206-213
Applied Technology Council
Elkady, Ahmed
8e55de89-dff4-4f84-90ed-6af476e328a8
Vamvatsikos, Dimitrios
abdb7624-1aab-4244-8bbc-c72c5a7f935c
Lignos, Dimitrios G.
9f55ad65-7b12-4ad6-972c-5a967ec0497b
Kazantzi, Athanasia
6bec107e-7301-472d-a322-ea07300e939a
Miranda, Eduardo
35bee145-203d-41c3-a86c-65582afd08bb
7 December 2022
Elkady, Ahmed
8e55de89-dff4-4f84-90ed-6af476e328a8
Vamvatsikos, Dimitrios
abdb7624-1aab-4244-8bbc-c72c5a7f935c
Lignos, Dimitrios G.
9f55ad65-7b12-4ad6-972c-5a967ec0497b
Kazantzi, Athanasia
6bec107e-7301-472d-a322-ea07300e939a
Miranda, Eduardo
35bee145-203d-41c3-a86c-65582afd08bb
Elkady, Ahmed, Vamvatsikos, Dimitrios, Lignos, Dimitrios G., Kazantzi, Athanasia and Miranda, Eduardo
(2022)
Experimental studies to validate an improved approach to the design of acceleration-sensitive nonstructural element.
Heintz, Jon A. and Filiatrault, Andre
(eds.)
In Proceedings of Fifth International Workshop on Seismic Performance of Non-Structural Elements (SPONSE).
Applied Technology Council.
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Nonstructural components in buildings can be subjected to very large acceleration and deformation demands during earthquakes. This is particularly true for flexible components that are tuned or nearly tuned to one of the modal frequencies of the supporting structure. To control the seismic demands in these situations, the authors have proposed a new design approach in which the connections between the structure and the nonstructural element are designed and detailed to experience nonlinearities to limit force and deformation demands. This paper summarizes an experimental campaign sponsored by the Seismology and Earthquake Engineering Research Infrastructure Alliance for Europe (SERA) aimed at validating the proposed design approach. The research project involved subjecting 14 different specimens representing nonstructural elements, with masses ranging from approximately 200 kg to 800 kg, to severe floor motions recorded during the 1989 Loma Prieta and the 1994 Northridge earthquakes in three instrumented buildings in California. A total of 45 individual tests were carried out. The tests were conducted at the EQUALS laboratory shake table at the University of Bristol. Mass and stiffness were carefully selected in each specimen to have vibration periods that resulted in both non-tuned and tuned components to modal frequencies of the supporting structure. Furthermore, some of the tuned tests involved components tuned to the fundamental mode while others were tuned to the second mode of vibration of the supporting structure to examine possible differences. Lateral strength and primary energy dissipation were provided by two steel plates with rotations restrained at both ends and loaded out-of-plane. The tests demonstrated how the proposed approach greatly reduces force and acceleration demands while also reducing lateral displacement demands. Furthermore, tests also demonstrated that the proposed approach reduces the response sensitivity to the period ratio of the nonstructural element to that of the supporting structure leading to a reduction in seismic demands uncertainty.
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Elkady_et_al_Full_Paper_SPONSE_Workshop
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Published date: 7 December 2022
Venue - Dates:
5th international workshop on the seismic performance of non-structural elements, Stanford University, Palo Alto, United States, 2022-12-05 - 2022-12-07
Identifiers
Local EPrints ID: 499031
URI: http://eprints.soton.ac.uk/id/eprint/499031
PURE UUID: 35e2269d-8888-4aa0-b85d-14cfa2d3f61b
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Date deposited: 07 Mar 2025 17:36
Last modified: 22 Aug 2025 02:27
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Contributors
Author:
Dimitrios Vamvatsikos
Author:
Dimitrios G. Lignos
Author:
Athanasia Kazantzi
Author:
Eduardo Miranda
Editor:
Jon A. Heintz
Editor:
Andre Filiatrault
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