Application of the fluid dynamics model to the field of fibre reinforced self-compacting concrete
Publication: Research - peer-review › Paper – Annual report year: 2012
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Application of the fluid dynamics model to the field of fibre reinforced self-compacting concrete. / Svec, Oldrich; Skocek, Jan; Stang, Henrik; Olesen, John Forbes; Thrane, L.N.
2012. Paper presented at Numerical modeling, Aix en Provence, France.Publication: Research - peer-review › Paper – Annual report year: 2012
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TY - CONF
T1 - Application of the fluid dynamics model to the field of fibre reinforced self-compacting concrete
A1 - Svec,Oldrich
A1 - Skocek,Jan
A1 - Stang,Henrik
A1 - Olesen,John Forbes
A1 - Thrane,L.N.
AU - Svec,Oldrich
AU - Skocek,Jan
AU - Stang,Henrik
AU - Olesen,John Forbes
AU - Thrane,L.N.
PY - 2012
Y1 - 2012
N2 - Ability to properly simulate a form filling process with steel fibre reinforced self-compacting concrete is a challenging task. Such simulations may clarify the evolution of fibre orientation and distribution<br/>which in turn significantly influences final mechanical properties of the cast body. We have developed such a computational model and briefly introduce it in this paper. The main focus of the paper is towards validation of the ability of the model to properly mimic the flow of the fibre reinforced self-compacting concrete. An experiment was conducted where a square slab was filled with the fibre reinforced selfcompacting concrete. A computational tomography scanner together with an image analysis were used to obtain a field of fibre orientation tensors. These tensors were compared to the tensors obtained by the simulation. The comparison shows the ability of the model to predict the real behaviour of the self-compacting fibre reinforced concrete.
AB - Ability to properly simulate a form filling process with steel fibre reinforced self-compacting concrete is a challenging task. Such simulations may clarify the evolution of fibre orientation and distribution<br/>which in turn significantly influences final mechanical properties of the cast body. We have developed such a computational model and briefly introduce it in this paper. The main focus of the paper is towards validation of the ability of the model to properly mimic the flow of the fibre reinforced self-compacting concrete. An experiment was conducted where a square slab was filled with the fibre reinforced selfcompacting concrete. A computational tomography scanner together with an image analysis were used to obtain a field of fibre orientation tensors. These tensors were compared to the tensors obtained by the simulation. The comparison shows the ability of the model to predict the real behaviour of the self-compacting fibre reinforced concrete.
ER -