A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method

Sara Mirzabagheri; Andrew Kevin Kenneth Doyle; Amir Mofidi; Omar Chaallal

doi:10.14359/51740622

A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method

Sara Mirzabagheri
, Andrew Kevin Kenneth Doyle
, Amir Mofidi
, Omar Chaallal

Research output: Contribution to Book/Report types › Contribution to conference proceedings › peer-review

2 Citations (Scopus)

Abstract

Embedded Through-Section (ETS) method is a shear rehabilitation technique for concrete structures involving pre-drilling vertical holes into a reinforced concrete member and installing FRP bars to be bonded using epoxy adhesive. Due to the lack of reliable models for predicting the ETS FRP bond behaviour, developing an accurate model to predict the maximum pull-out force of the ETS technique was deemed a knowledge gap. In this study, the main parameters used in an analytical bond-slip model proposed by the authors were obtained empirically and evaluated against the existing experimental results in the literature. To be able to calculate the maximum pull-out force for ETS FRP bars with different materials, a fracture mechanics-based bond model was defined in terms of the joints' geometrical and material properties, to allow the model to predict the performance of any FRP type with any concrete compressive strength. By using data in the available literature on FRP ETS pull-out tests, statistical analysis was utilized to fit the parameters against experimental data. The proposed model was able to produce superior analytical predictions of the experimental test data when compared to the existing bond models for ETS FRP bars.

Original language	English
Title of host publication	Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024
Editors	Ayman M. Okeil, Pedram Sadeghian, John J. Myers, Maria D. Lopez
Publisher	American Concrete Institute
Pages	141-155
Number of pages	15
ISBN (Electronic)	9781641952439
DOIs	https://doi.org/10.14359/51740622
Publication status	Published - 2024
Externally published	Yes
Event	16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 at the ACI Spring 2024 Convention - New Orleans, United States Duration: 24 Mar 2024 → 28 Mar 2024

Publication series

Name	American Concrete Institute, ACI Special Publication
Volume	SP-360
ISSN (Print)	0193-2527

Conference

Conference	16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 at the ACI Spring 2024 Convention
Country/Territory	United States
City	New Orleans
Period	24/03/24 → 28/03/24

!!!Keywords

Bond-Slip
Deep Embedment
Embedded Through-Section
FRP Bars
Fracture Mechanics
Pull-out Force
Shear Strengthening

Access to Document

10.14359/51740622

Cite this

Mirzabagheri, S., Doyle, A. K. K., Mofidi, A., & Chaallal, O. (2024). A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method. In A. M. Okeil, P. Sadeghian, J. J. Myers, & M. D. Lopez (Eds.), Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 (pp. 141-155). (American Concrete Institute, ACI Special Publication; Vol. SP-360). American Concrete Institute. https://doi.org/10.14359/51740622

Mirzabagheri, Sara ; Doyle, Andrew Kevin Kenneth ; Mofidi, Amir et al. / A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method. Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024. editor / Ayman M. Okeil ; Pedram Sadeghian ; John J. Myers ; Maria D. Lopez. American Concrete Institute, 2024. pp. 141-155 (American Concrete Institute, ACI Special Publication).

@inproceedings{9e80a971174144b4984700ecadc45228,

title = "A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method",

abstract = "Embedded Through-Section (ETS) method is a shear rehabilitation technique for concrete structures involving pre-drilling vertical holes into a reinforced concrete member and installing FRP bars to be bonded using epoxy adhesive. Due to the lack of reliable models for predicting the ETS FRP bond behaviour, developing an accurate model to predict the maximum pull-out force of the ETS technique was deemed a knowledge gap. In this study, the main parameters used in an analytical bond-slip model proposed by the authors were obtained empirically and evaluated against the existing experimental results in the literature. To be able to calculate the maximum pull-out force for ETS FRP bars with different materials, a fracture mechanics-based bond model was defined in terms of the joints' geometrical and material properties, to allow the model to predict the performance of any FRP type with any concrete compressive strength. By using data in the available literature on FRP ETS pull-out tests, statistical analysis was utilized to fit the parameters against experimental data. The proposed model was able to produce superior analytical predictions of the experimental test data when compared to the existing bond models for ETS FRP bars.",

keywords = "Bond-Slip, Deep Embedment, Embedded Through-Section, FRP Bars, Fracture Mechanics, Pull-out Force, Shear Strengthening",

author = "Sara Mirzabagheri and Doyle, \{Andrew Kevin Kenneth\} and Amir Mofidi and Omar Chaallal",

note = "Publisher Copyright: {\textcopyright} 2024 American Concrete Institute. All rights reserved.; 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 at the ACI Spring 2024 Convention ; Conference date: 24-03-2024 Through 28-03-2024",

year = "2024",

doi = "10.14359/51740622",

language = "English",

series = "American Concrete Institute, ACI Special Publication",

publisher = "American Concrete Institute",

pages = "141--155",

editor = "Okeil, \{Ayman M.\} and Pedram Sadeghian and Myers, \{John J.\} and Lopez, \{Maria D.\}",

booktitle = "Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024",

}

Mirzabagheri, S, Doyle, AKK, Mofidi, A & Chaallal, O 2024, A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method. in AM Okeil, P Sadeghian, JJ Myers & MD Lopez (eds), Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024. American Concrete Institute, ACI Special Publication, vol. SP-360, American Concrete Institute, pp. 141-155, 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 at the ACI Spring 2024 Convention, New Orleans, United States, 24/03/24. https://doi.org/10.14359/51740622

A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method. / Mirzabagheri, Sara; Doyle, Andrew Kevin Kenneth; Mofidi, Amir et al.
Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024. ed. / Ayman M. Okeil; Pedram Sadeghian; John J. Myers; Maria D. Lopez. American Concrete Institute, 2024. p. 141-155 (American Concrete Institute, ACI Special Publication; Vol. SP-360).

Research output: Contribution to Book/Report types › Contribution to conference proceedings › peer-review

TY - GEN

T1 - A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method

AU - Mirzabagheri, Sara

AU - Doyle, Andrew Kevin Kenneth

AU - Mofidi, Amir

AU - Chaallal, Omar

PY - 2024

Y1 - 2024

N2 - Embedded Through-Section (ETS) method is a shear rehabilitation technique for concrete structures involving pre-drilling vertical holes into a reinforced concrete member and installing FRP bars to be bonded using epoxy adhesive. Due to the lack of reliable models for predicting the ETS FRP bond behaviour, developing an accurate model to predict the maximum pull-out force of the ETS technique was deemed a knowledge gap. In this study, the main parameters used in an analytical bond-slip model proposed by the authors were obtained empirically and evaluated against the existing experimental results in the literature. To be able to calculate the maximum pull-out force for ETS FRP bars with different materials, a fracture mechanics-based bond model was defined in terms of the joints' geometrical and material properties, to allow the model to predict the performance of any FRP type with any concrete compressive strength. By using data in the available literature on FRP ETS pull-out tests, statistical analysis was utilized to fit the parameters against experimental data. The proposed model was able to produce superior analytical predictions of the experimental test data when compared to the existing bond models for ETS FRP bars.

AB - Embedded Through-Section (ETS) method is a shear rehabilitation technique for concrete structures involving pre-drilling vertical holes into a reinforced concrete member and installing FRP bars to be bonded using epoxy adhesive. Due to the lack of reliable models for predicting the ETS FRP bond behaviour, developing an accurate model to predict the maximum pull-out force of the ETS technique was deemed a knowledge gap. In this study, the main parameters used in an analytical bond-slip model proposed by the authors were obtained empirically and evaluated against the existing experimental results in the literature. To be able to calculate the maximum pull-out force for ETS FRP bars with different materials, a fracture mechanics-based bond model was defined in terms of the joints' geometrical and material properties, to allow the model to predict the performance of any FRP type with any concrete compressive strength. By using data in the available literature on FRP ETS pull-out tests, statistical analysis was utilized to fit the parameters against experimental data. The proposed model was able to produce superior analytical predictions of the experimental test data when compared to the existing bond models for ETS FRP bars.

KW - Bond-Slip

KW - Deep Embedment

KW - Embedded Through-Section

KW - FRP Bars

KW - Fracture Mechanics

KW - Pull-out Force

KW - Shear Strengthening

UR - https://www.scopus.com/pages/publications/85209728654

U2 - 10.14359/51740622

DO - 10.14359/51740622

M3 - Contribution to conference proceedings

AN - SCOPUS:85209728654

T3 - American Concrete Institute, ACI Special Publication

SP - 141

EP - 155

BT - Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024

A2 - Okeil, Ayman M.

A2 - Sadeghian, Pedram

A2 - Myers, John J.

A2 - Lopez, Maria D.

PB - American Concrete Institute

T2 - 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024 at the ACI Spring 2024 Convention

Y2 - 24 March 2024 through 28 March 2024

ER -

Mirzabagheri S, Doyle AKK, Mofidi A, Chaallal O. A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method. In Okeil AM, Sadeghian P, Myers JJ, Lopez MD, editors, Proceedings of the 16th International Symposium on Fiber-Reinforced Polymer (FRP) Reinforcement for Concrete Structures, FRPRCS 2024. American Concrete Institute. 2024. p. 141-155. (American Concrete Institute, ACI Special Publication). doi: 10.14359/51740622

A New Bond Model for RC Beams Strengthened with Embedded Through-Section Method

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