A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation

Cohesive zone models (CZMs) have been used to model composite fracture, metal adhesion failure, concrete cracking and other fracture scenarios. In these applications, CZMs are broadly classified into uncoupled models for pure mode fracture and coupled models incorporating mode I and mode II characte...

Full description

Saved in:
Bibliographic Details
Main Authors: Li, Gen, Tan, Kang Hai, Fung, Tat Ching, Yu, Qing Jun, May, Michael
Other Authors: School of Civil and Environmental Engineering
Format: Article
Language:English
Published: 2022
Subjects:
Online Access:https://hdl.handle.net/10356/160086
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-160086
record_format dspace
spelling sg-ntu-dr.10356-1600862022-07-12T08:01:54Z A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation Li, Gen Tan, Kang Hai Fung, Tat Ching Yu, Qing Jun May, Michael School of Civil and Environmental Engineering Engineering::Civil engineering Cohesive Zone Model FRP‐Concrete Debonding Cohesive zone models (CZMs) have been used to model composite fracture, metal adhesion failure, concrete cracking and other fracture scenarios. In these applications, CZMs are broadly classified into uncoupled models for pure mode fracture and coupled models incorporating mode I and mode II characteristics for mixed-mode fracture. Various coupled dynamic CZMs have been provided for dynamic fracture problems. However, a coupled CZM for FRP-concrete bond interface is still lacking. Such a bond interface contains diverse traction-separation performance in mode I and mode II fracture, as well as dynamic enhancing effect. To bridge this gap, current study proposed a coupled dynamic CZM to analyse FRP-concrete mixed-mode separation. The main objective was to evaluate model response under various mixed-mode ratios, including stress-separation curves and energy dissipation. The model was validated by various FRP-concrete dynamic separation tests, e.g. single-lap shear tests, three-point bending tests and FRP strengthened reinforced concrete (RC) beam subjected to a dynamic loading. Subsequently, the model was applied in finite element analysis (FEA) of an FRP strengthened RC wall under blast scenarios. From the comparison with the test results, the model was shown to be reliable and accurate in simulating the behaviour of FRP-concrete mixed-mode separation. Defence Medical Research Institute, DSTA Nanyang Technological University The authors acknowledge the research scholarship given by Nanyang Technological University and the research grant of the project “Modelling of Fibre‐Reinforced Polymer (FRP) Strengthened Reinforced Concrete Walls subject to Blast and Fragment Loadings” from the Defence Science and Technology Agency (DSTA), Singapore. 2022-07-12T08:01:54Z 2022-07-12T08:01:54Z 2021 Journal Article Li, G., Tan, K. H., Fung, T. C., Yu, Q. J. & May, M. (2021). A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation. Composite Structures, 268, 113872-. https://dx.doi.org/10.1016/j.compstruct.2021.113872 0263-8223 https://hdl.handle.net/10356/160086 10.1016/j.compstruct.2021.113872 2-s2.0-85104302454 268 113872 en Composite Structures © 2021 Published by Elsevier Ltd. All rights reserved.
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Civil engineering
Cohesive Zone Model
FRP‐Concrete Debonding
spellingShingle Engineering::Civil engineering
Cohesive Zone Model
FRP‐Concrete Debonding
Li, Gen
Tan, Kang Hai
Fung, Tat Ching
Yu, Qing Jun
May, Michael
A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
description Cohesive zone models (CZMs) have been used to model composite fracture, metal adhesion failure, concrete cracking and other fracture scenarios. In these applications, CZMs are broadly classified into uncoupled models for pure mode fracture and coupled models incorporating mode I and mode II characteristics for mixed-mode fracture. Various coupled dynamic CZMs have been provided for dynamic fracture problems. However, a coupled CZM for FRP-concrete bond interface is still lacking. Such a bond interface contains diverse traction-separation performance in mode I and mode II fracture, as well as dynamic enhancing effect. To bridge this gap, current study proposed a coupled dynamic CZM to analyse FRP-concrete mixed-mode separation. The main objective was to evaluate model response under various mixed-mode ratios, including stress-separation curves and energy dissipation. The model was validated by various FRP-concrete dynamic separation tests, e.g. single-lap shear tests, three-point bending tests and FRP strengthened reinforced concrete (RC) beam subjected to a dynamic loading. Subsequently, the model was applied in finite element analysis (FEA) of an FRP strengthened RC wall under blast scenarios. From the comparison with the test results, the model was shown to be reliable and accurate in simulating the behaviour of FRP-concrete mixed-mode separation.
author2 School of Civil and Environmental Engineering
author_facet School of Civil and Environmental Engineering
Li, Gen
Tan, Kang Hai
Fung, Tat Ching
Yu, Qing Jun
May, Michael
format Article
author Li, Gen
Tan, Kang Hai
Fung, Tat Ching
Yu, Qing Jun
May, Michael
author_sort Li, Gen
title A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
title_short A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
title_full A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
title_fullStr A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
title_full_unstemmed A coupled dynamic cohesive zone model for FRP-concrete mixed-mode separation
title_sort coupled dynamic cohesive zone model for frp-concrete mixed-mode separation
publishDate 2022
url https://hdl.handle.net/10356/160086
_version_ 1738844890700185600