Implementation and Calibration of Finite-Length Plastic Hinge Elements for Use in Seismic Structural Collapse Analysis

Filipe L.A. Ribeiro; Luis A.C. Neves; Andre R. Barbosa

doi:10.1080/13632469.2015.1036327

Implementation and Calibration of Finite-Length Plastic Hinge Elements for Use in Seismic Structural Collapse Analysis

Filipe L.A. Ribeiro, Luis A.C. Neves, Andre R. Barbosa

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

16 Citations (Scopus)

Abstract

Finite-length plastic hinge (FLPH) models have shown advantages over the concentrated plasticity hinge (CPH) models. However, empirical phenomenological relationships, such as Modified Ibarra–Medina–Krawinkler (ModIMK) deterioration model, were mainly calibrated for use in CPH models. ModIMK relationships are versatile and have been applied to steel, reinforced concrete, and timber structures. Herein, a calibration procedure of FLPH models and a unified algorithm for use of ModIMK relationships in CPH and FLPH models are presented. Results from included examples validate the proposed algorithms, which were implemented in OpenSees. Additionally, results highlight that FPLH models avoid errors and convergence pitfalls of CPH models.

Original language	English
Pages (from-to)	1197-1219
Number of pages	23
Journal	Journal of Earthquake Engineering
Volume	21
Issue number	8
DOIs	https://doi.org/10.1080/13632469.2015.1036327
Publication status	Published - 17 Nov 2017

Keywords

Calibration
Collapse
Concentrated Plasticity
Deterioration
Finite elements
Finite-length plastic hinge
Frame Models
Seismic analysis

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10.1080/13632469.2015.1036327

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title = "Implementation and Calibration of Finite-Length Plastic Hinge Elements for Use in Seismic Structural Collapse Analysis",

abstract = "Finite-length plastic hinge (FLPH) models have shown advantages over the concentrated plasticity hinge (CPH) models. However, empirical phenomenological relationships, such as Modified Ibarra–Medina–Krawinkler (ModIMK) deterioration model, were mainly calibrated for use in CPH models. ModIMK relationships are versatile and have been applied to steel, reinforced concrete, and timber structures. Herein, a calibration procedure of FLPH models and a unified algorithm for use of ModIMK relationships in CPH and FLPH models are presented. Results from included examples validate the proposed algorithms, which were implemented in OpenSees. Additionally, results highlight that FPLH models avoid errors and convergence pitfalls of CPH models.",

keywords = "Calibration, Collapse, Concentrated Plasticity, Deterioration, Finite elements, Finite-length plastic hinge, Frame Models, Seismic analysis",

author = "Ribeiro, {Filipe L.A.} and Neves, {Luis A.C.} and Barbosa, {Andre R.}",

note = "sem pdf conforme despacho. Portuguese National Science and Technology Foundation through the fellowship SFRH/BD/777722/2011 and grant PTDC/ECM-COM/2911/2012.",

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AU - Ribeiro, Filipe L.A.

AU - Neves, Luis A.C.

AU - Barbosa, Andre R.

N1 - sem pdf conforme despacho. Portuguese National Science and Technology Foundation through the fellowship SFRH/BD/777722/2011 and grant PTDC/ECM-COM/2911/2012.

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N2 - Finite-length plastic hinge (FLPH) models have shown advantages over the concentrated plasticity hinge (CPH) models. However, empirical phenomenological relationships, such as Modified Ibarra–Medina–Krawinkler (ModIMK) deterioration model, were mainly calibrated for use in CPH models. ModIMK relationships are versatile and have been applied to steel, reinforced concrete, and timber structures. Herein, a calibration procedure of FLPH models and a unified algorithm for use of ModIMK relationships in CPH and FLPH models are presented. Results from included examples validate the proposed algorithms, which were implemented in OpenSees. Additionally, results highlight that FPLH models avoid errors and convergence pitfalls of CPH models.

AB - Finite-length plastic hinge (FLPH) models have shown advantages over the concentrated plasticity hinge (CPH) models. However, empirical phenomenological relationships, such as Modified Ibarra–Medina–Krawinkler (ModIMK) deterioration model, were mainly calibrated for use in CPH models. ModIMK relationships are versatile and have been applied to steel, reinforced concrete, and timber structures. Herein, a calibration procedure of FLPH models and a unified algorithm for use of ModIMK relationships in CPH and FLPH models are presented. Results from included examples validate the proposed algorithms, which were implemented in OpenSees. Additionally, results highlight that FPLH models avoid errors and convergence pitfalls of CPH models.

KW - Calibration

KW - Collapse

KW - Concentrated Plasticity

KW - Deterioration

KW - Finite elements

KW - Finite-length plastic hinge

KW - Frame Models

KW - Seismic analysis

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JO - Journal of Earthquake Engineering

JF - Journal of Earthquake Engineering

IS - 8

ER -

Implementation and Calibration of Finite-Length Plastic Hinge Elements for Use in Seismic Structural Collapse Analysis

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Keywords

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