Damage model for monotonic and fatigue response of high strength concrete

A. H. Al-Gadhib; M. H. Baluch; A. Shaalan; A. R. Khan

doi:10.1106/HRAR-ENQW-1LW2-533R

Damage model for monotonic and fatigue response of high strength concrete

A. H. Al-Gadhib^*
, M. H. Baluch
, A. Shaalan
, A. R. Khan

^*Corresponding author for this work

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

55 Scopus citations

Abstract

An anisotropic elasto-damage model for predicting the response of concrete subject to monotonic and fatigue loading is presented in this study. The model utilizes a concrete appropriate damage-effect tensor M in constructing the constitutive equations. The concept of multiple bounding surfaces is used, with a varying size limit fracture surface defining fatigue loading in contrast to a fixed size limit fracture surface for monotonic loading. The model after calibration is shown to predict the monotonic, compressive uniaxial stress-strain path for concretes of various strengths as well as S-N curves depicting the fatigue response of concrete.

Original language	English
Pages (from-to)	57-78
Number of pages	22
Journal	International Journal of Damage Mechanics
Volume	9
Issue number	1
DOIs	https://doi.org/10.1106/HRAR-ENQW-1LW2-533R
State	Published - Jan 2000

ASJC Scopus subject areas

Computational Mechanics
General Materials Science
Mechanics of Materials
Mechanical Engineering

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abstract = "An anisotropic elasto-damage model for predicting the response of concrete subject to monotonic and fatigue loading is presented in this study. The model utilizes a concrete appropriate damage-effect tensor M in constructing the constitutive equations. The concept of multiple bounding surfaces is used, with a varying size limit fracture surface defining fatigue loading in contrast to a fixed size limit fracture surface for monotonic loading. The model after calibration is shown to predict the monotonic, compressive uniaxial stress-strain path for concretes of various strengths as well as S-N curves depicting the fatigue response of concrete.",

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AU - Baluch, M. H.

AU - Shaalan, A.

AU - Khan, A. R.

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Y1 - 2000/1

N2 - An anisotropic elasto-damage model for predicting the response of concrete subject to monotonic and fatigue loading is presented in this study. The model utilizes a concrete appropriate damage-effect tensor M in constructing the constitutive equations. The concept of multiple bounding surfaces is used, with a varying size limit fracture surface defining fatigue loading in contrast to a fixed size limit fracture surface for monotonic loading. The model after calibration is shown to predict the monotonic, compressive uniaxial stress-strain path for concretes of various strengths as well as S-N curves depicting the fatigue response of concrete.

AB - An anisotropic elasto-damage model for predicting the response of concrete subject to monotonic and fatigue loading is presented in this study. The model utilizes a concrete appropriate damage-effect tensor M in constructing the constitutive equations. The concept of multiple bounding surfaces is used, with a varying size limit fracture surface defining fatigue loading in contrast to a fixed size limit fracture surface for monotonic loading. The model after calibration is shown to predict the monotonic, compressive uniaxial stress-strain path for concretes of various strengths as well as S-N curves depicting the fatigue response of concrete.

UR - https://www.scopus.com/pages/publications/0033873086

U2 - 10.1106/HRAR-ENQW-1LW2-533R

DO - 10.1106/HRAR-ENQW-1LW2-533R

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EP - 78

JO - International Journal of Damage Mechanics

JF - International Journal of Damage Mechanics

IS - 1

ER -

Damage model for monotonic and fatigue response of high strength concrete

Abstract

ASJC Scopus subject areas

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