Abstract
Some of the current concrete damage plasticity models in the literature employ a single damage variable for both the tension and compression regimes, while a few more advanced models employ two damage variables. Models with a single variable have an inherent difficulty in accounting for the damage accrued due to tensile and compressive actions in appropriately different manners, and their mutual dependencies. In the current models that adopt two damage variables, the independence of these damage variables during cyclic loading results in the failure to capture the effects of tensile damage on the compressive behavior of concrete and vice-versa. This study presents a cyclic model established by extending an existing monotonic constitutive model. The model describes the cyclic behavior of concrete under multiaxial loading conditions and considers the influence of tensile/compressive damage on the compressive/tensile response. The proposed model, dubbed the enhanced concrete damage plasticity model (ECDPM), is an extension of an existing model that combines the theories of classical plasticity and continuum damage mechanics. Unlike most prior studies on models in the same category, the performance of the proposed ECDPM is evaluated using experimental data on concrete specimens at the material level obtained under cyclic multiaxial loading conditions including uniaxial tension and confined compression. The performance of the model is observed to be satisfactory. Furthermore, the superiority of ECDPM over three previously proposed constitutive models is demonstrated through comparisons with the results of a uniaxial tension-compression test and a virtual test.
Highlights
Numerous experimental and numerical studies have been performed to develop, calibrate, and validate predictive response models for plain and reinforced concrete in structural systems under seismic loading [1,2,3,4,5,6,7,8,9,10,11,12,13]
Neither CDPM, nor the more advanced CDPM2, can describe the influence of prior compressive/tensile damage on the tensile/compressive behavior. This particular shortcoming is addressed in the present study through the development of a new model, namely the enhanced concrete damage plasticity model, that aims to capture the behavior of plain concrete under cyclic multiaxial loading conditions
An ECDPM was proposed for simulating the cyclic behavior of plain concrete under multiaxial loading conditions
Summary
Numerous experimental and numerical studies have been performed to develop, calibrate, and validate predictive response models for plain and reinforced concrete in structural systems under seismic loading [1,2,3,4,5,6,7,8,9,10,11,12,13]. Neither CDPM, nor the more advanced CDPM2, can describe the influence of prior compressive/tensile damage on the tensile/compressive behavior This particular shortcoming is addressed in the present study through the development of a new model, namely the enhanced concrete damage plasticity model (the ECDP model or ECDPM), that aims to capture the behavior of plain concrete under cyclic multiaxial loading conditions. The latter is one of the advantages of ECDPM over the two prior cyclic damage plasticity models [60,61] whose abilities to predict the cyclic response of plain concrete under biaxial and triaxial cyclic compression conditions have neither been demonstrated nor examined in the open literature
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call