Microstructural Damage Characteristic of a Layer-to-Layer Three-Dimensional Angle-Interlock Woven Composite Under Quasi-Static Tensile Loading

• Published in: AUTEX Research Journal Vol. 20; no. 2; pp. 121 - 127
• Main Authors: Ma, Qian, Wang, Ke, Wang, Shu-Dong, Chen, Hong-Wu, Jin, Li-Min, Liu, Hua, Qin, Xiao
• Format: Journal Article
• Language: English
• Published: Lodz Sciendo 01.06.2020; De Gruyter Poland; De Gruyter
• Subjects: finite element analysis (FEA); Materials science; Mechanical properties; quasi-static tensile; Stress concentration; structural failure mechanism; Textiles; three-dimensional angle-interlock woven composite (3DAWC)
• ISSN: 2300-0929; 1470-9589; 2300-0929
• DOI: 10.2478/aut-2019-0012

Three-dimensional angle-interlock woven composites (3DAWCs) are widely used for their excellent mechanical properties. The most significant feature is the existence of the undulated warp yarns along the thickness direction, which makes it interesting to study the mechanical properties in the warp direction. The quasi-static tensile behavior of a layer-to-layer 3DAWC along the undulated warp direction was studied by experimental and finite element analysis (FEA) methods. Based on the experimental results, the typical failure mode involving fibers, resin, and their interfaces was found. According to the FEA results, the stress concentration effect, key structural regions, and microstructural (yarn and resin) damage mechanism were obtained, which provided effective guidance for structural optimization design of the 3DAWC with stronger tensile resistance performance. In addition, the three-step progressive failure process of the 3DAWC under quasi-static tensile load was also described at the “yarn–resin” microstructural level.