An experimental investigation was conducted using the double cantilever beam (DCB) test to evaluate the effects of fabric reinforcement and microfiber addition to the matrix on the interlaminar fracture behavior and other mechanical properties of woven fabric composites. A procedure for determination of the mode I fracture toughness {dollar}Gsb{lcub}rm IC{rcub}{dollar} for specimens undergoing large deflections on the DCB test was established, and a technique for interlaminar fracture toughness enhancement by matrix modification with microfiber additives was explored. Major mechanisms contributing to the fracture toughness and microfailure of the composite samples were identified by scanning electron microscopy (SEM) analysis. Results indicated that the addition of 1% to 3% different microfibers to the epoxy matrix increased the interlaminar fracture toughness of glass fabric composites by 75% to 108% and showed no significant effect on other mechanical properties.; A 3-D finite element analysis was performed on a (90,(+45/{dollar}{lcub}-{rcub}45)sb{lcub}n{rcub},(-45/{lcub}+{rcub}45)sb{lcub}n{rcub}90rbracksb{lcub}rm s{rcub}{dollar} class of laminated composites under the edge crack torsion (ECT) test configuration. Valid finite element delamination models were established and formulas for calculating the mode III fracture toughness from 3-D finite element models were developed. The relations between the interlaminar fracture behavior and various configuration parameters were investigated and the effects of point loads, specimen ends, geometry, mode II interference, and friction were evaluated. Results showed that the ECT specimen is mode III dominant, and the distribution of the mode III strain energy release rate {dollar}Gsb{lcub}rm III{rcub}{dollar} in the ECT specimen depends on crack length rather than layup. Specimen ends have significant effect on {dollar}Gsb{lcub}rm III{rcub}{dollar}. Friction between crackfaces induced by point loads is negligible. An ECT test with a new fixture was conducted on carbon/epoxy laminated composite samples to verify the analysis methods and improve the test method. A procedure for specimen layup/crack length selection for valid ECT mode III test was proposed.
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机译:使用双悬臂梁(DCB)试验进行了实验研究,以评估织物增强和向基体中添加超细纤维对机织复合材料的层间断裂行为和其他机械性能的影响。建立了在DCB测试中确定经受大挠曲的试样的I型断裂韧度的确定程序,并通过微纤维基体改性提高层间断裂韧度的技术探索了添加剂。通过扫描电子显微镜(SEM)分析确定了导致复合材料样品断裂韧性和显微破坏的主要机理。结果表明,向环氧树脂基体中添加1%至3%的不同微纤维可使玻璃纤维复合材料的层间断裂韧性提高75%至108%,并且对其他机械性能没有显着影响。对(90,(+ 45 / {dollar} {lcub}-{rcub} 45)sb {lcub} n {rcub},(-45 / {lcub} + {rcub}的3D有限元分析45)sb {lcub} n {rcub} 90rbracksb {lcub} rm s {rcub} {dollar}类层压材料在边缘裂纹扭转(ECT)测试配置下的行为建立了有效的有限元分层模型并计算了模态通过3-D有限元模型建立了Ⅲ型断裂韧度,研究了层间断裂行为与各种构型参数之间的关系,评估了点载荷,试样端部,几何形状,Ⅱ型干涉和摩擦的影响。 ECT样品以III型为主导,并且ECT样品中III型应变能释放速率{dol} Gsb {lcub} rm III {rcub} {dol}的分布取决于裂纹的长度而不是叠层,试件末端具有显着的对{dolal} Gsb {lcub} rm III {rcub} {dollar}的影响。合情合理。用新夹具对碳/环氧层压复合材料样品进行了ECT测试,以验证分析方法并改进测试方法。提出了有效ECT模式III测试的试样铺层/裂纹长度选择程序。
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