Load effects in reinforced concrete beam bridges affected by alkali–silica reaction—Constitutive modelling including expansion, cracking, creep and crushing

Simen Sørgaard Kongshaug,Rolf Magne Larssen,Max A.N Hendriks,Terje Kanstad,Gro Markeset

doi:10.1016/j.engstruct.2021.112945

Abstract

Material modelling, from the micro to the macro level, of concrete affected by alkali–silica reaction (ASR) has been devoted a lot of research. However, the application of the material models in structural analyses of reinforced concrete (RC) structures, showing the structural implications/consequences of ASR, has got little attention in the literature. This paper aims to show the relevance of the constitutive model on the calculated load effects—induced by ASR—in statically indeterminate beam structures. For the purpose of the study, a three-span RC beam, inspired by a real bridge in Norway, is analysed. The RC beam is modelled using Euler–Bernoulli beam theory, and numerical solutions are obtained with the finite element method. The effects of ASR on the concrete are accounted for in an expansion based (macro) constitutive model, which also accounts for cracking, creep and compressive non-linearity. In this way, ASR gives an imposed deformation similar to thermal dilation and shrinkage, for which structural effects have been widely studied. As imposed strain gradients tend to cause higher load effects than uniform strains, the effect of ASR gradients, owing to e.g. a moisture gradient, is addressed.It is shown that linear structural analyses (using a linear material model), give conservative results (the greatest load effects) when an ASR strain gradient is imposed. Among the non-linear material effects investigated, it is shown that stress dependent ASR expansion and concrete cracking are important to consider. The stress dependency of the ASR expansion is shown to have a smoothing effect on the imposed ASR strain field, and as a result, reduces the load effects induced by ASR, while cracking results in crack/plastic hinges releasing the stresses in the system.

Highlights

This paper aims to show the relevance of the constitutive model on the calculated load effects—induced by alkali–silica reaction (ASR)—in statically indeterminate beam structures
This paper aims to illustrate the relevance of proper constitutive modelling of the effects of alkali–silica reaction (ASR) in combination with models for creep, cracking and reinforcement yielding, for the calculation of load effects in statically indeterminate beam structures
The objective of this paper is to increase the understanding of the effect of ASR expansion on the calculated load effects for ordinary reinforced concrete (RC) continuous beams, which is important for assessing load effects in beam bridges

Summary

Introduction

This paper aims to illustrate the relevance of proper constitutive modelling of the effects of alkali–silica reaction (ASR) in combination with models for creep, cracking and reinforcement yielding, for the calculation of load effects in statically indeterminate beam structures. ASR in concrete is an important deteriorating mechanism found in existing concrete structures all over the world. The effect of ASR is expansion and degradation of the material, most noticeable in terms of reduced modulus of elasticity and tensile strength, see e.g. the experimental works [1,2,3,4] The most noticeable signs of ASR are surface cracks and displacements leading to e.g. closing of expansion joints and skewed columns. In Norway, ASR in concrete structures was first identified and documented in the late 1970s (mainly in dams and swimming pools). It was not until early 1990s that ASR was accepted as a common deterioration process [5]. ASR may be a potential problem for many concrete structures in the coming decades, and the need for structural assessment follows

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