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Prediction of thermal cracking in concrete structures reinforced with GFRP

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNAbstract

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Prediction of thermal cracking in concrete structures reinforced with GFRP. / EL-Zaroug, Omar; Forth, John; Ye, Jianqiao.
FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures . ed. / Joaquim Barros. Elsevier, 2013.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNAbstract

Harvard

EL-Zaroug, O, Forth, J & Ye, J 2013, Prediction of thermal cracking in concrete structures reinforced with GFRP. in J Barros (ed.), FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures . Elsevier, 11th International Symposium of Fiber Reinforced Polymers for Reinforced Concrete Structures (FRPRCS11), Guimarães, Portugal, 26/06/13.

APA

EL-Zaroug, O., Forth, J., & Ye, J. (2013). Prediction of thermal cracking in concrete structures reinforced with GFRP. In J. Barros (Ed.), FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures Elsevier.

Vancouver

EL-Zaroug O, Forth J, Ye J. Prediction of thermal cracking in concrete structures reinforced with GFRP. In Barros J, editor, FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures . Elsevier. 2013

Author

EL-Zaroug, Omar ; Forth, John ; Ye, Jianqiao. / Prediction of thermal cracking in concrete structures reinforced with GFRP. FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures . editor / Joaquim Barros. Elsevier, 2013.

Bibtex

@inbook{3ba74a596a994eb0be98fa69b20acabc,
title = "Prediction of thermal cracking in concrete structures reinforced with GFRP",
abstract = "A nonlinear finite element (NLFE) simulation using DIANA software [1] was performed in order to estimate the temperature which produced the first transverse crack at the bar surface and the corresponding tensile stress. It was also used to predict the extent and direction of the thermally induced cracking due to thermal incompatibility between the concrete and GFRP bars when the temperature increases. The NLFE results were verified by comparing the output of the proposed 2D NLFE model with experimental results. The results confirmed the influence of temperature variations on the state of stress within the GFRP reinforced concrete slabs, and the necessity for a recommended minimum concrete cover to avoid the formation of through cracks. The NLFE model generally shows good agreement with the experimental results for a concrete cover of 1.5 x bar diameter db.",
author = "Omar EL-Zaroug and John Forth and Jianqiao Ye",
year = "2013",
month = jun,
language = "English",
editor = "{ Barros}, { Joaquim }",
booktitle = "FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures",
publisher = "Elsevier",
note = "11th International Symposium of Fiber Reinforced Polymers for Reinforced Concrete Structures (FRPRCS11) ; Conference date: 26-06-2013 Through 28-06-2013",

}

RIS

TY - CHAP

T1 - Prediction of thermal cracking in concrete structures reinforced with GFRP

AU - EL-Zaroug, Omar

AU - Forth, John

AU - Ye, Jianqiao

PY - 2013/6

Y1 - 2013/6

N2 - A nonlinear finite element (NLFE) simulation using DIANA software [1] was performed in order to estimate the temperature which produced the first transverse crack at the bar surface and the corresponding tensile stress. It was also used to predict the extent and direction of the thermally induced cracking due to thermal incompatibility between the concrete and GFRP bars when the temperature increases. The NLFE results were verified by comparing the output of the proposed 2D NLFE model with experimental results. The results confirmed the influence of temperature variations on the state of stress within the GFRP reinforced concrete slabs, and the necessity for a recommended minimum concrete cover to avoid the formation of through cracks. The NLFE model generally shows good agreement with the experimental results for a concrete cover of 1.5 x bar diameter db.

AB - A nonlinear finite element (NLFE) simulation using DIANA software [1] was performed in order to estimate the temperature which produced the first transverse crack at the bar surface and the corresponding tensile stress. It was also used to predict the extent and direction of the thermally induced cracking due to thermal incompatibility between the concrete and GFRP bars when the temperature increases. The NLFE results were verified by comparing the output of the proposed 2D NLFE model with experimental results. The results confirmed the influence of temperature variations on the state of stress within the GFRP reinforced concrete slabs, and the necessity for a recommended minimum concrete cover to avoid the formation of through cracks. The NLFE model generally shows good agreement with the experimental results for a concrete cover of 1.5 x bar diameter db.

M3 - Abstract

BT - FRPRCS-11: 11th International Symposiumn on Fibre Reinforced Polymer for Reinforced Concrete Structures

A2 - Barros, Joaquim

PB - Elsevier

T2 - 11th International Symposium of Fiber Reinforced Polymers for Reinforced Concrete Structures (FRPRCS11)

Y2 - 26 June 2013 through 28 June 2013

ER -