Thai Hung LE, PhD in materials science, lecturer at University ofScience and Technology, Hanoi, Vietnam. My research is thecomposite materials, metal forming and modeling and simulation inmaterials. Denis FAVIER and Laurent ORGEAS, professor at Laboratory of Sols, Solides, Structures-Risques (3S-R), University of Grenoble in France.
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Composite Materials. Rheology and microstructures of thermoset polymer composites filled with mineral fillers and reinfor
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- Nombre de pages184
- FormatPoche
- PrésentationBroché
- Poids0.279 kg
- Dimensions15,0 cm × 22,0 cm × 1,1 cm
- ISBN978-613-1-53345-7
- EAN9786131533457
- Date de parution08/09/2010
- CollectionOMN.UNIV.EUROP.
- ÉditeurUniv Européenne
Résumé
In this work, the rheology and the microstructures of thermoset polymer composites reinforced with glass fibres, such as Bulk Moulding Compounds (BMC) and Sheet Moulding Compounds (SMC), are analysed. Firstly, the rheology of BMC is studied by using dedicated simple and plane strain compression rheometers. Experimental results emphasize the influences of the strain rate, the type of mineral fillers, the volume fraction of fibres as well as the temperature on the BMC rheology.
1D and 3D non-linear viscoelastic rheological models are proposed to reproduce the behaviour of BMC. Secondly, the microstructures of compression moulded SMC plates are analysed by using X-ray phase contrast microtomography. The influences of processing conditions on residual porosity, matrix migration, breakage, bending, compression and orientation of glass-fibre bundles are underlined, allowing a discussion on the relevance of assumptions used to establish rheological models proposed in the literature.
1D and 3D non-linear viscoelastic rheological models are proposed to reproduce the behaviour of BMC. Secondly, the microstructures of compression moulded SMC plates are analysed by using X-ray phase contrast microtomography. The influences of processing conditions on residual porosity, matrix migration, breakage, bending, compression and orientation of glass-fibre bundles are underlined, allowing a discussion on the relevance of assumptions used to establish rheological models proposed in the literature.