TY - GEN

T1 - Influence of water-induced damage mechanisms on the fatigue deterioration of high-strength concrete

AU - Tomann, Christoph

AU - Lohaus, Ludger

AU - Aldakheel, Fadi

AU - Wriggers, Peter

N1 - Funding information: This research was supported by the Federal Ministry of Economic Affairs and Energy and the German Research Foundation (DFG). The authors would like to express their gratitude for the financial support.

PY - 2019/5

Y1 - 2019/5

N2 - Concrete specimens which are submerged in water have a significantly lower fatigue resistance than specimens which are stored and tested in air. This phenomenon was recognised in the past, but how the moisture content in the microstructure of the concrete influences its resistance against fatigue deterioration is still unknown. Well-instrumented fatigue tests on high-strength concrete specimens are conducted to investigate how the moisture content in the microstructure of concrete influences its fatigue resistance and which additional water-induced damage mechanisms are involved in the degradation process. Furthermore, a dependency of different load frequencies is examined. Since water-induced damage mechanisms act on a very small scale, which cannot be directly observed during the tests, a multiscale numerical approach is necessary to describe water-induced damage mechanisms in fatigue-loaded concrete. This paper presents results of fatigue tests on high-strength concrete specimens with different moisture contents and load frequencies tested in air and under water. The number of cycles to failure, the development of stiffness and the acoustic emission are analysed over the degradation process of the concrete. Finally, a numeric modelling approach is presented.

AB - Concrete specimens which are submerged in water have a significantly lower fatigue resistance than specimens which are stored and tested in air. This phenomenon was recognised in the past, but how the moisture content in the microstructure of the concrete influences its resistance against fatigue deterioration is still unknown. Well-instrumented fatigue tests on high-strength concrete specimens are conducted to investigate how the moisture content in the microstructure of concrete influences its fatigue resistance and which additional water-induced damage mechanisms are involved in the degradation process. Furthermore, a dependency of different load frequencies is examined. Since water-induced damage mechanisms act on a very small scale, which cannot be directly observed during the tests, a multiscale numerical approach is necessary to describe water-induced damage mechanisms in fatigue-loaded concrete. This paper presents results of fatigue tests on high-strength concrete specimens with different moisture contents and load frequencies tested in air and under water. The number of cycles to failure, the development of stiffness and the acoustic emission are analysed over the degradation process of the concrete. Finally, a numeric modelling approach is presented.

KW - Fatigue deterioration

KW - High-strength concrete

KW - Microscale model

KW - Moisture content

KW - Phase-field

KW - Porous media

KW - Stiffness

KW - Water-induced degradation mechanisms

UR - http://www.scopus.com/inward/record.url?scp=85066078713&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:85066078713

SP - 1944

EP - 1951

BT - Proceedings of the fib Symposium 2019

A2 - Derkowski, Wit

A2 - Krajewski, Piotr

A2 - Gwozdziewicz, Piotr

A2 - Pantak, Marek

A2 - Hojdys, Lukasz

T2 - fib Symposium 2019: Concrete - Innovations in Materials, Design and Structures

Y2 - 27 May 2019 through 29 May 2019

ER -