Computational homogenization of micro-structural damage due to frost in hardened cement paste

M. Hain; Peter Wriggers

doi:10.1016/j.finel.2007.11.020

Computational homogenization of micro-structural damage due to frost in hardened cement paste

M. Hain^*
, Peter Wriggers

^*Korrespondierende*r Autor*in für diese Arbeit

Institut für Kontinuumsmechanik

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Abstract

Based on a micro-structural finite-element model using computer-tomography scans at micrometer length-scale, damage due to frost within hardened cement paste (HCP) is evaluated. In order to verify the microscopic constitutive equations, a multi-scale model is introduced which allows a comparison with experimental data at macro-level. Subsequently, damage due to frost is simulated numerically: the water-filled pores of HCP increase in volume during a freezing process which yields an inelastic material behavior. Numerical simulations at micro-structural level are performed for different moistures and temperatures, and an effective correlation between moisture, temperature and the inelastic material behavior is obtained. Finally, thermo-mechanical coupling is introduced and an effective constitutive equation for HCP is developed using the abovementioned temperature-moisture-damage correlation.

Originalsprache	Englisch
Seiten (von - bis)	233-244
Seitenumfang	12
Fachzeitschrift	Finite Elements in Analysis and Design
Jahrgang	44
Ausgabenummer	5
DOIs	https://doi.org/10.1016/j.finel.2007.11.020
Publikationsstatus	Veröffentlicht - 1 März 2008

ASJC Scopus Sachgebiete

Analysis
Allgemeiner Maschinenbau
Computergrafik und computergestütztes Design
Angewandte Mathematik

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10.1016/j.finel.2007.11.020

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title = "Computational homogenization of micro-structural damage due to frost in hardened cement paste",

abstract = "Based on a micro-structural finite-element model using computer-tomography scans at micrometer length-scale, damage due to frost within hardened cement paste (HCP) is evaluated. In order to verify the microscopic constitutive equations, a multi-scale model is introduced which allows a comparison with experimental data at macro-level. Subsequently, damage due to frost is simulated numerically: the water-filled pores of HCP increase in volume during a freezing process which yields an inelastic material behavior. Numerical simulations at micro-structural level are performed for different moistures and temperatures, and an effective correlation between moisture, temperature and the inelastic material behavior is obtained. Finally, thermo-mechanical coupling is introduced and an effective constitutive equation for HCP is developed using the abovementioned temperature-moisture-damage correlation.",

keywords = "Damage due to frost, Hardened cement paste, Micro-structure, Multi-scale model",

author = "M. Hain and Peter Wriggers",

note = "Funding information: Financial support from the Deutsche Forschungsgemeinschaft (German Research Foundation) under contract number SPP1122 is gratefully appreciated. The Bundesanstalt f{\"u}r Materialforschung undpr{\"u}fung (Dr. Urs M{\"u}ller) in Berlin assigned the micro-CT scans of HCP, which were tested at the European Synchrotron Radiation Facility in Grenoble by Dr. Lukas Helfen. All experimental results of HCP were performed by the Institut f{\"u}r Bauforschung (Director: Prof. Brameshuber) at RWTH Aachen, Germany. Special thanks are addressed to Matthias Koster who generated the artificially saturated micro-structures of HCP.",

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AU - Hain, M.

AU - Wriggers, Peter

N1 - Funding information: Financial support from the Deutsche Forschungsgemeinschaft (German Research Foundation) under contract number SPP1122 is gratefully appreciated. The Bundesanstalt für Materialforschung undprüfung (Dr. Urs Müller) in Berlin assigned the micro-CT scans of HCP, which were tested at the European Synchrotron Radiation Facility in Grenoble by Dr. Lukas Helfen. All experimental results of HCP were performed by the Institut für Bauforschung (Director: Prof. Brameshuber) at RWTH Aachen, Germany. Special thanks are addressed to Matthias Koster who generated the artificially saturated micro-structures of HCP.

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AB - Based on a micro-structural finite-element model using computer-tomography scans at micrometer length-scale, damage due to frost within hardened cement paste (HCP) is evaluated. In order to verify the microscopic constitutive equations, a multi-scale model is introduced which allows a comparison with experimental data at macro-level. Subsequently, damage due to frost is simulated numerically: the water-filled pores of HCP increase in volume during a freezing process which yields an inelastic material behavior. Numerical simulations at micro-structural level are performed for different moistures and temperatures, and an effective correlation between moisture, temperature and the inelastic material behavior is obtained. Finally, thermo-mechanical coupling is introduced and an effective constitutive equation for HCP is developed using the abovementioned temperature-moisture-damage correlation.

KW - Damage due to frost

KW - Hardened cement paste

KW - Micro-structure

KW - Multi-scale model

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