Behaviour of steel cushions subjected to combined actions

Ercan Yüksel; Faruk Karadoğan; Hasan Özkaynak; Arastoo Khajehdehi; Ahmet Güllü; Eleni Smyrou; İhsan Engin Bal

doi:10.1007/s10518-017-0217-4

Behaviour of steel cushions subjected to combined actions

Ercan Yüksel^*, Faruk Karadoğan, Hasan Özkaynak, Arastoo Khajehdehi, Ahmet Güllü, Eleni Smyrou, İhsan Engin Bal

^*Corresponding author for this work

Department of Civil Engineering

Research output: Contribution to journal › Article › peer-review

28 Citations (Scopus)

Abstract

Mild steel is relatively low-cost and easily accessible material to fabricate some structural members. It would be a significant advantage if seismic energy dissipaters that are used in structures constructed in the earthquake prone areas, could also be produced on site. In this paper, a promising seismic energy dissipater made of mild steel, so-called steel cushion (SC) is presented. It is provided experimental and analytical responses of SCs subjected to bi-axial loadings. SC rolls under the lateral loading that allows relocation of the plasticized cross-section. Henceforth, SC dissipates considerable amount of seismic energy. A series of tests were performed to achieve experimentally the behavior of SC subjected to longitudinal and transversal loading. Finite Element Models (FEMs) were also generated to reproduce the experimental backbone curves and to predict the bi-directional response properties for discrete transversal forces and plate thicknesses. Closed-form equations were derived to determine yield and ultimate forces and the corresponding displacements as well as location of the plasticized sections. The behavior of SC could either be projected by the FEMs with the exhibited parameters or by means of the proposed closed-form equations and the normalized design chart.

Original language	English
Pages (from-to)	707-729
Number of pages	23
Journal	Bulletin of Earthquake Engineering
Volume	16
Issue number	2
DOIs	https://doi.org/10.1007/s10518-017-0217-4
Publication status	Published - Feb 2018

Bibliographical note

Publisher Copyright:
© Springer Science+Business Media B.V. 2017.

Funding

Acknowledgements The research presented herein was conducted in the framework of the FP7 project ‘‘SAFECLADDING: ‘‘Improved Fastening Systems of Cladding Wall Panels of Precast Buildings in Seismic Zones’’ Research for SME Associations, Grant Agreement Number 314122, which was coordinated by Dr. Alessio Rinoldi from BIBM, Belgium. The financial support provided by the Commission of the European Communities through this project is greatly appreciated. The experimental study was conducted at the Structural and Earthquake Engineering Laboratory of Istanbul Technical University (STEELab). The supports of Laboratory staff and graduate students are gratefully acknowledged.

Funders	Funder number
BIBM
Commission of the European Communities
Seventh Framework Programme	314122

Keywords

Dissipater
Mild steel
Seismic energy dissipation
Steel cushion

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10.1007/s10518-017-0217-4

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title = "Behaviour of steel cushions subjected to combined actions",

abstract = "Mild steel is relatively low-cost and easily accessible material to fabricate some structural members. It would be a significant advantage if seismic energy dissipaters that are used in structures constructed in the earthquake prone areas, could also be produced on site. In this paper, a promising seismic energy dissipater made of mild steel, so-called steel cushion (SC) is presented. It is provided experimental and analytical responses of SCs subjected to bi-axial loadings. SC rolls under the lateral loading that allows relocation of the plasticized cross-section. Henceforth, SC dissipates considerable amount of seismic energy. A series of tests were performed to achieve experimentally the behavior of SC subjected to longitudinal and transversal loading. Finite Element Models (FEMs) were also generated to reproduce the experimental backbone curves and to predict the bi-directional response properties for discrete transversal forces and plate thicknesses. Closed-form equations were derived to determine yield and ultimate forces and the corresponding displacements as well as location of the plasticized sections. The behavior of SC could either be projected by the FEMs with the exhibited parameters or by means of the proposed closed-form equations and the normalized design chart.",

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AU - Özkaynak, Hasan

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AU - Güllü, Ahmet

AU - Smyrou, Eleni

AU - Bal, İhsan Engin

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N2 - Mild steel is relatively low-cost and easily accessible material to fabricate some structural members. It would be a significant advantage if seismic energy dissipaters that are used in structures constructed in the earthquake prone areas, could also be produced on site. In this paper, a promising seismic energy dissipater made of mild steel, so-called steel cushion (SC) is presented. It is provided experimental and analytical responses of SCs subjected to bi-axial loadings. SC rolls under the lateral loading that allows relocation of the plasticized cross-section. Henceforth, SC dissipates considerable amount of seismic energy. A series of tests were performed to achieve experimentally the behavior of SC subjected to longitudinal and transversal loading. Finite Element Models (FEMs) were also generated to reproduce the experimental backbone curves and to predict the bi-directional response properties for discrete transversal forces and plate thicknesses. Closed-form equations were derived to determine yield and ultimate forces and the corresponding displacements as well as location of the plasticized sections. The behavior of SC could either be projected by the FEMs with the exhibited parameters or by means of the proposed closed-form equations and the normalized design chart.

AB - Mild steel is relatively low-cost and easily accessible material to fabricate some structural members. It would be a significant advantage if seismic energy dissipaters that are used in structures constructed in the earthquake prone areas, could also be produced on site. In this paper, a promising seismic energy dissipater made of mild steel, so-called steel cushion (SC) is presented. It is provided experimental and analytical responses of SCs subjected to bi-axial loadings. SC rolls under the lateral loading that allows relocation of the plasticized cross-section. Henceforth, SC dissipates considerable amount of seismic energy. A series of tests were performed to achieve experimentally the behavior of SC subjected to longitudinal and transversal loading. Finite Element Models (FEMs) were also generated to reproduce the experimental backbone curves and to predict the bi-directional response properties for discrete transversal forces and plate thicknesses. Closed-form equations were derived to determine yield and ultimate forces and the corresponding displacements as well as location of the plasticized sections. The behavior of SC could either be projected by the FEMs with the exhibited parameters or by means of the proposed closed-form equations and the normalized design chart.

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Behaviour of steel cushions subjected to combined actions

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