Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods

The externally bonded (EB) and the near-surface mounted (NSM) are two well-known methods for strengthening reinforced concrete (RC) beams. Both methods are unfortunately prone to fail prematurely through debonding when the amount of strengthening reinforcement provided is high. In response to this,...

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Main Authors: Shukri, Ahmad Azim, Shamsudin, Mohd Fazaulnizam, Ibrahim, Zainah, Alengaram, Ubagaram Johnson, Hashim, Huzaifa
Format: Article
Published: Brazilian Association of Computational Mechanics 2018
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Online Access:http://eprints.um.edu.my/20668/
https://doi.org/10.1590/1679-78254948
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Institution: Universiti Malaya
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spelling my.um.eprints.206682019-03-13T01:11:41Z http://eprints.um.edu.my/20668/ Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods Shukri, Ahmad Azim Shamsudin, Mohd Fazaulnizam Ibrahim, Zainah Alengaram, Ubagaram Johnson Hashim, Huzaifa TA Engineering (General). Civil engineering (General) The externally bonded (EB) and the near-surface mounted (NSM) are two well-known methods for strengthening reinforced concrete (RC) beams. Both methods are unfortunately prone to fail prematurely through debonding when the amount of strengthening reinforcement provided is high. In response to this, a hybrid method that combines the EB and NSM method was introduced. The method allows the amount of reinforcement needed for EB and NSM methods to be reduced; this, in theory, should lower the interfacial stresses, thus reducing the possibility of debonding failures. While debonding failure can be prevented, certain amounts of debonding would still occur through the interfacial crack (IC) debonding mechanism which can affect the strength and stiffness of hybrid strengthened beams even if it does not directly cause failure. This paper presents a method to simulate IC debonding of hybrid strengthened beams using the moment-rotation approach. The proposed method allows a better prediction of maximum load and stiffness of the beams. The method is also less dependent on empirical formulations compared to the commonly used moment-curvature approach; this allows the method to be applicable to all material and shape of hybrid strengthening reinforcement, assuming correct material models are used. The proposed method was then used to perform parametric studies; among the important findings is the length of IC debonding tend to increase when FRP sheet with higher elastic modulus is used, thus negating most of the benefit from the higher modulus. Brazilian Association of Computational Mechanics 2018 Article PeerReviewed Shukri, Ahmad Azim and Shamsudin, Mohd Fazaulnizam and Ibrahim, Zainah and Alengaram, Ubagaram Johnson and Hashim, Huzaifa (2018) Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods. Latin American Journal of Solids and Structures, 15 (9). e78. ISSN 1679-7817 https://doi.org/10.1590/1679-78254948 doi:10.1590/1679-78254948
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic TA Engineering (General). Civil engineering (General)
spellingShingle TA Engineering (General). Civil engineering (General)
Shukri, Ahmad Azim
Shamsudin, Mohd Fazaulnizam
Ibrahim, Zainah
Alengaram, Ubagaram Johnson
Hashim, Huzaifa
Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
description The externally bonded (EB) and the near-surface mounted (NSM) are two well-known methods for strengthening reinforced concrete (RC) beams. Both methods are unfortunately prone to fail prematurely through debonding when the amount of strengthening reinforcement provided is high. In response to this, a hybrid method that combines the EB and NSM method was introduced. The method allows the amount of reinforcement needed for EB and NSM methods to be reduced; this, in theory, should lower the interfacial stresses, thus reducing the possibility of debonding failures. While debonding failure can be prevented, certain amounts of debonding would still occur through the interfacial crack (IC) debonding mechanism which can affect the strength and stiffness of hybrid strengthened beams even if it does not directly cause failure. This paper presents a method to simulate IC debonding of hybrid strengthened beams using the moment-rotation approach. The proposed method allows a better prediction of maximum load and stiffness of the beams. The method is also less dependent on empirical formulations compared to the commonly used moment-curvature approach; this allows the method to be applicable to all material and shape of hybrid strengthening reinforcement, assuming correct material models are used. The proposed method was then used to perform parametric studies; among the important findings is the length of IC debonding tend to increase when FRP sheet with higher elastic modulus is used, thus negating most of the benefit from the higher modulus.
format Article
author Shukri, Ahmad Azim
Shamsudin, Mohd Fazaulnizam
Ibrahim, Zainah
Alengaram, Ubagaram Johnson
Hashim, Huzaifa
author_facet Shukri, Ahmad Azim
Shamsudin, Mohd Fazaulnizam
Ibrahim, Zainah
Alengaram, Ubagaram Johnson
Hashim, Huzaifa
author_sort Shukri, Ahmad Azim
title Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
title_short Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
title_full Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
title_fullStr Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
title_full_unstemmed Simulating Intermediate Crack Debonding on RC Beams Strengthened with Hybrid Methods
title_sort simulating intermediate crack debonding on rc beams strengthened with hybrid methods
publisher Brazilian Association of Computational Mechanics
publishDate 2018
url http://eprints.um.edu.my/20668/
https://doi.org/10.1590/1679-78254948
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