Abstract:

In this study, we prepared weight-free, epoxy-recinated glass/cave tissue hybrid composite plates, which contain TiC by 1, 3% and 5%, reinforced by titanium carbon (TiC). All prepared composite panels have experimentally and numerically studied mechanical characteristics and impact behavior measurements. Composite plates are prepared by manual deposit method. Flat aramid fiber with a surface area of 207g/m2 (Kevlars 49), 300g/m2 surface area of glass fiber and F-1564 epoxy rhines are used as supplementary and matrix material.   To determine the mechanical characteristics of the composite panels, the elasticity module, the sliding module and the poision ratio are obtained with the universal drawing test device. Composite panels are cut in size 100x100 mm. The samples with a 12 layer plate are ranked in 3 rows of kevlar 1 rows of glass fiber layer. The measurement data obtained by the ANSYS dynamic analysis program is compared numerically.   As a result, the power-break, power-time, absorbed energy-time and speed-time graphs obtained under the 10J, 20J and 30J shock energies were obtained in the shock test. Mechanical and shock tests on TiC-added hybrid composite plates, added in different concentration rates, showed that 3% weight of TiC-added composite plates absorbed 15% more energy in the elasticity module of the pure composite plates and 6% more energy in the healing and shock resistance. Fiber distribution and breakdown are observed in all samples under the load applied while no degradation has been observed on the bottom of the composite panels. The results obtained by numerical analysis have found a compatible relationship between the results of the experiment.

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