Off-axial angle sensitivity of 3D orthogonal woven composite failure behavior subjected to in-plane compressive loading

Abstract

This work investigated off-axial angle effect on in-plane compression behavior of 3D orthogonal woven(3DOW) composite under both quasi-static and dynamic loading. Mechanical responses of 3DOW specimens with different off-axial angles were evaluated using a universal material tester and a split Hopkinson pressure bar(SHPB) testbench. An infrared thermographic camera was used to record temperature rising of the specimens in order to characterize the damage development in quasi-static compression. A yarn-level finite element model considering progressive damage behavior of impregnated yarn, matrix resin and their interface were also established to reveal the deformation behavior and failure mechanism. It is found that the off-axial angle has significant influence on compressive response and failure mode. The modulus and compressive strength of specimens exhibited a decreasing tendency with increase of off-axial angle, while failure strain had a rising trend. In addition, the role of z-yarn was identified in different off-axial angle cases. For on-axial specimen, the z-yarn suppressed out-of-plane deformation of superficial weft yarns failing in kinking mode. It in turn caused intensive z-yarn breakage, which accompanied by high temperature rising. For off-axial specimens, rotation deformation of weft and warp yarns was observed, which was restrained by z-yarn. It leaded to extensive debonding between matrix and yarns and delamination characterized by relative low temperature rising.