Abstract
The thermal conductivity of epoxy resin can be increased by a factor of eight to ten by loading with highly conductive particles. However, higher loadings increase the viscosity of the resin and hamper its use for liquid composite molding processes. Thus, the enhancement of the out-of-plane thermal conductivity of carbon composites manufactured by VARTM and accomplished by matrix filling is limited to about 250%. In order to derive higher increases in out-of-plane thermal conductivity, additional measures have to be taken. These consist of introducing thermally conductive fibers in out-of-plane direction of the preform using a 3D-weaving process. Measured out-of-plane thermal conductivities of 3D-woven fabric composites are significantly increased compared to a typical laminated composite. It has been shown that if introducing highly conductive z-fibers, the use of a particle filled resin is not necessary and furthermore should be avoided due to the manufacturing problems mentioned above. An existing analytical model was altered to predict the effective thermal conductivity as a function of the composite material properties such as the thermal conductivities and volume contents of fibers in in-plane and out-of-plane directions, the thermal conductivity of the loaded resin, the grid-density of the out- of-plane fibers, and material properties of the contacting material. The predicted results are compared with measured data of manufactured samples.
Highlights
Fiber based composites offer the unique ability to tailor material properties locally
The enhancement of the out-of-plane thermal conductivity of carbon composites manufactured by Vacuum Assisted Resin Transfer Molding (VARTM) and accomplished by matrix filling is limited to about 250%
Ma et al investigated carbon fiber epoxy resin composites filled with silicon carbide particles [7]
Summary
Fiber based composites offer the unique ability to tailor material properties locally. Such integral materials reduce the number of components leading to more elegant designs, and to structures that are less costly to manufacture. Z-pinning is a technique to insert pins in thickness direction by mechanically forcing pins through the dry 2D-preform [19] This procedure increases the in-plane delamination resistance, it has detrimental effects on planar reinforcing fibers. The objective of this research is to evaluate the suitability of the increase of the thermal conductivity by improving matrix conductivity and fiber architecture and its prediction
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