Yazid Yahya scite author profile

Through-thickness polymer pin-reinforced foam core sandwich (FCS) panels are new type of composite sandwich structure as the foam core of this structure was reinforced with cylindrical polymer pins, which also rigidly connect the face sheets. These sandwich panels are made of glass fiber-reinforced polyester face sheets and closed-cell polyurethane foam core with cylindrical polymer pins produced during fabrication process. The indentation and compression behavior of these sandwich panels were compared with common traditional sandwich panel, and it has been found that by reinforcing the foam core with cylindrical polymer pins, the indentation strength, energy absorption, and compression strength of the sandwich panels were improved significantly. The effect of diameter of polymer pins on indentation and compression behavior of both sandwich panels was studied and results showed that the diameter of polymer pins had a large influence on the compression and indentation behavior of through-thickness polymer pin-reinforced FCS panel, and the effect of adding polymer pins to FCS panel on indentation behavior is similar to the effect of increasing the thickness of face sheet. The effect of strain rate on indentation behavior of FCS panel and through-thickness polymer pin-reinforced FCS panel were studied, and results showed that both types of composite sandwich panels are strain rate dependent structure as by increasing strain rate, the indentation properties and energy absorption properties of these structures are increased. POLYM. COMPOS., 37:612-619, 2016.

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Yazid Yahya

Flatwise compression and flexural behavior of foam core and polymer pin-reinforced foam core composite sandwich panels

Comparison of foam core sandwich panel and through‐thickness polymer pin–reinforced foam core sandwich panel subject to indentation and flatwise compression loadings

Microwave absorption properties in epoxy resin Multi Walled Carbon Nanotubes composites

Fracture of laminated woven GFRP composite pressure vessels under combined low-velocity impact and internal pressure

Thermo-mechanical behaviour of smart composite beam under quasi-static loading

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