摘要
采用炭纤维平纹织物和精细Z pin制备了新型3D炭纤维预制件,炭基体采用等温化学气相沉积和高温煤沥青高压浸渍炭化制备。短梁剪切试验和开口拉剪试验用来表征Z pin增强体对剪切破坏模式的影响。短梁剪切失效模式为假塑性,而拉剪失效模式为非假塑性破坏。分析了产生此现象的机制,短梁剪切假塑性失效由炭/炭复合材料叠层中纤维束内、纤维束间和叠层间微裂纹扩展形成,而产生拉剪失效的单一层间裂纹扩展不引起宏观假塑性现象。采用Z pin作为提高层间剪切强度的增强体间隔1.5mm比间隔2.5mm可提高剪切强度40%~50%,该技术将成为3D炭/炭复合材料预制体制备更为先进的技术。
A novel form of preform consisting of plain weave fabric and z-pin through-thickness reinforcements was prepared. The carbon matrix was derived from a combination of isothermal chemical vapor infiltration and high pressure impregnation-carbonization of coal tar pitch. The interlaminar shear strength of the composites was characterized by a short beam interlaminar shear test and it double edge-notched tensile shear test. Hyper pseudoplastic fracture behavior of short beam interlaminar shear of 3D C/C composites was found, which is ascribed to the propagation of microcracks formed between laminations within and between bundles. Z-pins can have effective control over the progress of pseudoplastic fracture. True shear failure, which is characterized by the double edge-notched tensile test, shows non-pseudoplastic fracture progress that is ascribed to shear sliding occurring only within one interlamination. Both short beam interlaminar strength and double edge-notched tensile strength is 40 50 % higher for a z-pin density of 1.5 turn interval than for a z-pin density of 2.5 mm interval. Employing z-pins as through-thickness reinforcements has advantages over a 3D weave.
出处
《新型炭材料》
SCIE
EI
CAS
CSCD
2004年第2期97-102,共6页
New Carbon Materials
基金
国防预研基金 (51 46 1 0 70 1 0 3ZS50 0 3 )~~
