Numerical benchmark campaign of COST Action TU1404 – microstructural modelling

Mateusz Wyrzykowski,Guang Ye,Cyrille Dunant,Peng Gao,Vit Smilauer,Bernhard Pichler,Luca Valentini,Laurent Charpin,Adrien Hilaire,Shashank Bishnoi,Túlio Honório,Miguel Azenha,Karolina Hajkova,Julien Sanahuja,Christian Hellmich,Markus Königsberger

doi:10.21809/rilemtechlett.2017.44

Abstract

This paper presents the results of the numerical benchmark campaign on modelling of hydration and microstructure development of cementitious materials. This numerical benchmark was performed in the scope of COST Action TU1404 “Towards the next generation of standards for service life of cement-based materials and structures”. Seven modelling groups took part in the campaign applying different models for prediction of mechanical properties (elastic moduli or compressive strength) in cement pastes and mortars. The simulations were based on published experimental data. The experimental data (both input and results used for validation) were open to the participants. The purpose of the benchmark campaign was to identify the needs of different models in terms of input experimental data, verify predictive potential of the models and finally to provide reference cases for new models in the future. The results of the benchmark show that a relatively high scatter in the predictions can arise between different models, in particular at early ages (e.g. elastic Young’s modulus predicted at 1 d in the range 6-20 GPa), while it reduces at later age, providing relatively good agreement with experimental data. Even though the input data was based on a single experimental dataset, the large differences between the results of the different models were found to be caused by distinct assumed properties for the individual phases at the microstructural level, mainly because of the scatter in the nanoindentation-derived properties of the C-S-H phase.

Highlights

The campaign reported here has been performed within the activities of the COST Action TU1404 “Towards the generation of standards for service life of cement‐based materials and structures” [1]
One of the major tools for reaching this objective is by means of developing and validating numerical models that allow one to predict the evolution of material properties and eventually their service life performance in a real structure
The benchmark was based on an experimental dataset published previously, i.e. both the input data and the experimental results were open to the participants

Summary

Introduction

The campaign reported here has been performed within the activities of the COST Action TU1404 “Towards the generation of standards for service life of cement‐based materials and structures” [1]. Virtual Cement and Concrete Ageing Analysis Toolbox (Vi(CA)2T v2) is based on the concept of a "virtual lab" or "virtual material": from the mix design details, it is able to estimate physical properties (such as the evolution of hydration heat, capillary porosity or water content) and mechanical behaviors (such as the evolution of the Young’s modulus, or basic creep). To do so, it embeds two kinds of models: Cement paste hydration models: combining chemistry and kinetics, from the initial mix design information (including clinker composition), the amounts of phases (different anhydrous phases, various hydrates, water and porosity) and the hydration macroscopic properties (temperature, released heat) are estimated as a function of time. It is worth noting that the model was applied without fitting any parameters

Micromechanical homogenization

Micromechanical analytical model

Micromechanical numerical model

HYMOSTRUC3D model

Results and discussion

Conclusions