Multi-scale modelling of concrete structures affected by alkali-silica reaction: Coupling the mesoscopic damage evolution and the macroscopic concrete deterioration

A finite-element approach based on the first-order FE2 homogenisation technique is formulated to analyse the alkali-silica reaction-induced damage in concrete structures, by linking the concrete degradation at the macro-scale to the reaction extent at the meso-scale. At the meso-scale level, concrete is considered as a heterogeneous material consisting of aggregates embedded in a mortar matrix. The mechanical effects of the Alkali-Silica Reaction (ASR) are modelled through the application of temperature-dependent eigenstrains in several localised spots inside the aggregates, and the mechanical degradation of concrete is modelled using continuous damage model, which is capable of reproducing the complex ASR crack networks. Then, the effective stiffness tensor and the effective stress tensor for each macroscopic finite element are computed by homogenising the mechanical response of the corresponding representative volume element (RVE). Convergence between macro- and meso-scales is achieved via an iterative procedure. A 2D model of an ASR laboratory specimen is analysed as a proof of concept. The model is able to account for the loading applied at the macro-scale and the ASR-product expansion at the meso-scale. The results demonstrate that the macroscopic stress state influences the orientation of damage inside the underlying RVEs. The effective stiffness becomes anisotropic in cases where damage is aligned inside the RVE. (C) 2020 The Authors. Published by Elsevier Ltd.

Experiments-based multi-scale modeling of the alkali-silica reaction in concrete

Mauro Corrado, Emil Gallyamov, Jean-François Molinari, Roozbeh Rezakhani

In this study, we investigate the mechanical behavior of large concrete structures affected by the alkali-silica reaction. Particularly, concrete dams are explored. Their permanent contact with water, and thus increased humidity, promotes the ASR. Seasonal variation of the environmental temperature causes different levels of concrete damage in “cold” and “warm” zones. In order to study the behavior of such structures, a thermo-mechanical multi-scale numerical model is developed. It is based on the algorithm proposed by CubaRamos. Simulations are performed at the macro- and meso-scales, both of which are handled by the finiteelement method. An elastic thermo-mechanical simulation, performed at the macro-scale, results in a temperature and displacement field. This information at every integration point of the macro-scale is communicated to a corresponding representative volume element (RVE) at the meso-scale. The temperature value is used to determine the gel expansion rate for the following time step. Advancement of the ASR at the level of RVEs leads to gel expansion, deformation of the matrix, and growth of cracks. Given the solution of an RVE problem, homogenized material properties are extracted and communicated to the corresponding integration point of the macro-structure. In the next loading step, the latter behaves according to local states of material throughout a structure.Concrete damaging process is locally driven by gel volume increase, which in its turn depends on therate of alkali-silica reaction. An equation used to relate the ambient temperature and the amount of available reactants to the gel strain rate is inspired by the Arrhenius law. Parameters of this equation are calibrated based on the experiments by Gautam & Panesar. Cracks in concrete are handled by a continuum damage model. Convergence of the static solution in the presence of multiple cracks is achieved by modification of the sequential linear analysis proposed by Rots and Invernizzi. The cement paste at the meso-scale behaves viscoelastically, which causes relaxation of stresses and reduction in the level of damage. For this purpose, an algorithm coupling the SLA with the general viscoelastic model is developed.

2019

Meso-scale finite element modeling of Alkali-Silica-Reaction

Emil Gallyamov, Jean-François Molinari, Roozbeh Rezakhani

The Alkali-Silica Reaction (ASR) in concrete is a chemical reaction, which produces an expansive product, generally called “ASR gel”, and causes cracking and damage in concrete over time. Affecting numerous infrastructures all around the world, ASR has been the topic of much research over the past decades. In spite of that, many aspects of this reaction are still unknown. In this numerical-investigation paper, a three-dimensional concrete meso-structure model is simulated using the finite-element method. Coarse aggregates, cement paste, and ASR gel are explicitly represented. A temperature dependent eigen-strain is applied on the simulated ASR gel pockets to capture their expansive behavior. This applies pressure on the surrounding aggregates and the cement paste, leading to cracks initiation and propagation. Free expansion of concrete specimens due to ASR is modeled and validated using experimental data. Influence of different key factors on damage generation in aggregates and paste and macroscopic expansion are discussed.

2021

Comportement structural des bétons de fibres ultra performants en traction dans des éléments composés

John Wuest

Ultra high performance concretes (UHPFRC) are characterized by a dense matrix and a high fibre content. These materials exhibit exceptional mechanical and durability properties making them an ideal material for rehabilitating existing structures. The primary interest in UHPFRC focuses on their uniaxial tensile performance. When they applied in a cast in place overlay configuration, they provide increased rigidity to the global element and localized protection to the steel reinforcement embedded in the concrete core during the service by minimizing surface cracking and inhibiting the diffusion of aggressive agents. At the ultimate state, and under certain configurations UHPFRC significantly improves the element's carrying capacity. The overall goal of this research is to study the UHPFRC tensile behaviour (hardening and softening behaviours) of characteristic test specimen and to apply this knowledge in analyzing the structural response of various composite elements. The objectives related to this study are: To determine the factors influencing the UHPFRC uniaxial tensile test specimen behaviour To illustrate the importance of UHPFRC tensile hardening and softening responses in UHPFRC structural plates and UHPFRC-reinforced concrete composite beams. To determine the rupture mechanism and overall contribution a UHPFRC overlay offers to a composite UHPFRC-reinforced concrete slab loaded to failure in flexural/punching shear. To study the parameters influencing the UHPFRC uniaxial behaviour in tensile composite structural elements. The behaviour of specimen with different configurations and compositions were studied in uniaxial tensile tests. The variables significantly influencing the fibre orientation were isolated by studying the fibre orientation at localized cuts in the various specimen. These controlling variables include: mixture viscosity, casting method, casting direction, fibre aspect-ratio and element geometry. Furthermore, a meso-level model was developed to predict the uniaxial tensile behaviour and was validated against the experimental test results. With the help of this model, the influence of the main fibre characteristics (Vf, Lf, df) on the resultant fibre orientation and matrix quality were examined. This model has determined that the extent of hardening does not increase linearly with the quantity of fibres but rather follows an asymptotic curve converging to a maximum possible hardening. A second model was developed to randomly orient and place fibres. This model has helped to explain the uniaxial tensile response variability of different mixtures ranging from conventional Fibre Reinforced Concrete (FRC) to UHPFRC. A finite element program has been employed to study the influence the UHPFRC softening behaviour has on the composite structural beam and UHPFRC plate responses. For a flexural plate (length 500mm, width 200mm, height 30mm), the bearing capacity was significantly increased by the very pronounced UHPFRC softening behaviour. Additionally, the UHPFRC layer noticeably increased the rigidity of the composite beam and slab. For example the UHPFRC layer increased the slab bearing capacity by 40% in comparison to a purely reinforced concrete slab by bridging the punching shear mechanism with a UHPFRC membrane effect. The structural responses of the two element types were then further analyzed using a finite element analysis program. An inverse analysis methodology was employed to obtain the UHPFRC tensile material laws in respective composite elements. These findings documented that a similar materials exhibited significantly different responses when applied in different applications. This analysis documents that the UHPFRC layer in a slab closely follows the uniaxial tensile test specimen response, while the UHPFRC layer in a composite beam exhibits a significantly reduced performance. The primary reasons for these variances are: the relative fibre distribution, the interface rugosity, the internal residual stresses and the extent of the maximum stress zone. Recommendations are made concerning the implementation of UHPFRC and the influence the fibre aspect ratio and volume (Vf, Lf, df) imposes on the resulting fibre orientation in different applications. Finally, a method for determining the UHPFRC characteristic curve which is required to design a composite UHPFRC-reinforced concrete element is presented.