Numerical Filling Predictions and Mechanical Mold Simulations for Composite Manufacturing Techniques: RTM Tool Development
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Key engineering materials. Vol. 651-653 2015. p. 423-432 (Key engineering materials).
Research output: Chapter in Book/Report/Conference proceeding › Chapter › Research
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TY - CHAP
T1 - Numerical Filling Predictions and Mechanical Mold Simulations for Composite Manufacturing Techniques: RTM Tool Development
AU - Grössing, Harald
AU - Konstantopoulos, Spiridon
AU - Schledjewski, Ralf
PY - 2015
Y1 - 2015
N2 - This paper presents the development of a novel omega-shaped resin transfer molding (RTM) tool, which is especially designed to host different types of sensors and to avoid common problems of RTM (e.g. uneven heating, low tool durability, deflection). Permeability measurements were executed in order to get real permeability measurements for numerical mold filling simulations. Three different kinds of flow behaviors (isotropic, orthotropic and anisotropic) were considered as filling patterns and the flow front predictions. Due to the U-shaped composite part design, the mold curvature effects on the flow front propagation caused by the increased fiber volume content in these areas were also taken into account. The tool was designed with a heating ability using purified liquid water guided to a channel circuit within both top and bottom halves of the tool. Deflection and heat transfer simulations were performed with the finite element method (FEM). All three executed simulations (filling, heat transfer and deflection) were used as a guideline for the final mold design.
AB - This paper presents the development of a novel omega-shaped resin transfer molding (RTM) tool, which is especially designed to host different types of sensors and to avoid common problems of RTM (e.g. uneven heating, low tool durability, deflection). Permeability measurements were executed in order to get real permeability measurements for numerical mold filling simulations. Three different kinds of flow behaviors (isotropic, orthotropic and anisotropic) were considered as filling patterns and the flow front predictions. Due to the U-shaped composite part design, the mold curvature effects on the flow front propagation caused by the increased fiber volume content in these areas were also taken into account. The tool was designed with a heating ability using purified liquid water guided to a channel circuit within both top and bottom halves of the tool. Deflection and heat transfer simulations were performed with the finite element method (FEM). All three executed simulations (filling, heat transfer and deflection) were used as a guideline for the final mold design.
KW - FEM Simulations
KW - Liquid Composite Molding
KW - Resin transfer molding
U2 - 10.4028/www.scientific.net/KEM.651-653.423
DO - 10.4028/www.scientific.net/KEM.651-653.423
M3 - Chapter
VL - 651-653
T3 - Key engineering materials
SP - 423
EP - 432
BT - Key engineering materials
ER -