TY - GEN

T1 - New insights into the moisture effect on the fatigue behavior of concrete

AU - Mahlbacher, Markus

AU - Ali, Mohamed Abubakar

AU - Tomann, Christoph

AU - Oneschkow, Nadja

AU - Aldakheel, Fadi

AU - Noii, Nima

AU - Wriggers, Peter

AU - Lohaus, Ludger

AU - Haist, Michael

N1 - Funding Information: Acknowledgments: This research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project numbers (353757395) (HA 7917/7-2 | LO 751/22-2 | WR 19/58-2), within the Priority Program 2020 ‘Cyclic Deterioration of High-Performance Concrete in an Experimental-Virtual Lab’.

PY - 2022

Y1 - 2022

N2 - Decreasing the environmental effects of concrete construction will require a pronounced reduction in concrete use and thus more slender structures, which in turn are more prone to fatigue. The same is true for offshore structures e.g. the grouted connection in wind-energy systems. The design procedure of fatigue-prone structures today, however, still has to cope with different influences. Investigations carried out by the authors show that a pronounced reduction in load cycles can be observed with increasing moisture content of the concrete. The authors were able to relate the damaging process to water transport processes in the pore system of the concrete. In this contribution, both experimental as well as numerical investigations are presented, which give insights into the fatigue mechanisms. These investigations encompass both macroscopic fatigue tests at various moisture conditions as well as Nuclear Magnetic Resonance Tests (NMR) monitoring water redistribution as a result of cyclic loading. Measurements of gas adsorption give insight into microstructural degradation.

AB - Decreasing the environmental effects of concrete construction will require a pronounced reduction in concrete use and thus more slender structures, which in turn are more prone to fatigue. The same is true for offshore structures e.g. the grouted connection in wind-energy systems. The design procedure of fatigue-prone structures today, however, still has to cope with different influences. Investigations carried out by the authors show that a pronounced reduction in load cycles can be observed with increasing moisture content of the concrete. The authors were able to relate the damaging process to water transport processes in the pore system of the concrete. In this contribution, both experimental as well as numerical investigations are presented, which give insights into the fatigue mechanisms. These investigations encompass both macroscopic fatigue tests at various moisture conditions as well as Nuclear Magnetic Resonance Tests (NMR) monitoring water redistribution as a result of cyclic loading. Measurements of gas adsorption give insight into microstructural degradation.

UR - http://www.scopus.com/inward/record.url?scp=85143906242&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:85143906242

SN - 9782940643158

T3 - fib Symposium

SP - 339

EP - 348

BT - Proceedings for the 6th fib International Congress, 2022- Concrete Innovation for Sustainability

A2 - Stokkeland, Stine

A2 - Braarud, Henny Cathrine

T2 - 6th fib International Congress on Concrete Innovation for Sustainability, 2022

Y2 - 12 June 2022 through 16 June 2022

ER -