TY - GEN
T1 - Investigation of localized damage indicators of a carbon short-fibre reinforced high performance concrete under dynamic and flexural load
AU - Lauff, Philipp
AU - Raith, Manuel
AU - Große, Christian
AU - Rutzen, Matthias
AU - Volkmer, Dirk
AU - Reischmann, Lisa
AU - Weiß, Ursula
AU - Peter, Malte A.
AU - Fischer, Oliver
N1 - Publisher Copyright:
© Federation Internationale du Beton (fib) - International Federation for Structural Concrete, 2019.
PY - 2019
Y1 - 2019
N2 - By using a novel fibre-reinforced cement paste recipe in an additive manufacturing (‘3D-printing’) method, a highly anisotropic material with vastly improved flexural and tensile strength can be created. Extruding the paste through a small nozzle results in unidirectional fibre orientation. A fibre content of 3 vol% results in static flexural strengths of above 100 MPa. High-strength fibre reinforced materials have great potential to be used as small, lightweight construction elements. Those structural members often show susceptibility to oscillating dynamic loads. Using a dynamic-mechanical analyser, miniature samples with a cross-section of 3 mm x 3 mm can be tested for their resistance towards cyclic loading in tests of up to 10 million cycles. Using an ex-situ method, micro-CT scans and optical microscopy are used to check for cracking and other damage indicators. To investigate the tensile fatigue behaviour on macro scale, bone-shaped specimens under pulsating tensile stress with a cross section area of 50 mm x 50 mm are examined. In addition to standard methods, i.e. strain gauges, strain sensors and position sensors, modern and wide range methods like fibre optic sensors, photogrammetry (digital image correlation), acoustic emission analysis and ultrasonic based coda wave interferometry are used. The aim is to describe the local macro crack development. The experimental investigations are accompanied by a multiscale modelling approach incorporating three-dimensional representative volume elements based on micro-CT scans of small test specimens. The representative volume elements reflect the mesoscale in the sense that carbon fibres and otherwise homogenized concrete matrix are distinguished.
AB - By using a novel fibre-reinforced cement paste recipe in an additive manufacturing (‘3D-printing’) method, a highly anisotropic material with vastly improved flexural and tensile strength can be created. Extruding the paste through a small nozzle results in unidirectional fibre orientation. A fibre content of 3 vol% results in static flexural strengths of above 100 MPa. High-strength fibre reinforced materials have great potential to be used as small, lightweight construction elements. Those structural members often show susceptibility to oscillating dynamic loads. Using a dynamic-mechanical analyser, miniature samples with a cross-section of 3 mm x 3 mm can be tested for their resistance towards cyclic loading in tests of up to 10 million cycles. Using an ex-situ method, micro-CT scans and optical microscopy are used to check for cracking and other damage indicators. To investigate the tensile fatigue behaviour on macro scale, bone-shaped specimens under pulsating tensile stress with a cross section area of 50 mm x 50 mm are examined. In addition to standard methods, i.e. strain gauges, strain sensors and position sensors, modern and wide range methods like fibre optic sensors, photogrammetry (digital image correlation), acoustic emission analysis and ultrasonic based coda wave interferometry are used. The aim is to describe the local macro crack development. The experimental investigations are accompanied by a multiscale modelling approach incorporating three-dimensional representative volume elements based on micro-CT scans of small test specimens. The representative volume elements reflect the mesoscale in the sense that carbon fibres and otherwise homogenized concrete matrix are distinguished.
KW - 3D-printing
KW - Carbon fibre reinforced concrete
KW - Fatigue
KW - Fibre orientation
KW - High tensile strength
KW - Multiscale modelling
KW - Simulation
UR - http://www.scopus.com/inward/record.url?scp=85066074534&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85066074534
T3 - Proceedings of the fib Symposium 2019: Concrete - Innovations in Materials, Design and Structures
SP - 1952
EP - 1959
BT - Proceedings of the fib Symposium 2019
A2 - Derkowski, Wit
A2 - Krajewski, Piotr
A2 - Gwozdziewicz, Piotr
A2 - Pantak, Marek
A2 - Hojdys, Lukasz
PB - International Federation for Structural Concrete
T2 - fib Symposium 2019: Concrete - Innovations in Materials, Design and Structures
Y2 - 27 May 2019 through 29 May 2019
ER -