含孔复合材料圆柱壳冲击破坏试验与有限元分析

 为了揭示轴向压缩载荷与径向冲击载荷共同作用下复合材料壳体开孔处裂纹的产生机理,开展了含圆孔复合材料圆柱壳冲击试验,并对冲击试验进行了有限元仿真分析。提出复杂冲击载荷作用下的动态响应分析方法,运用LS-DYNA对冲击载荷作用下含圆孔复合材料圆柱壳动态响应过程进行了模拟,采用含刚度退化的Chang-Chang失效准则预测复合材料圆柱壳破坏过程,得到的冲击加速度响应曲线及破坏区域与试验结果一致,验证了本文方法的正确性。对有限元模型进行动力学及静力学破坏分析,结果表明,径向冲击引起的环向拉应力是圆孔边缘破坏区域90°铺层纤维断裂与基体开裂的主要原因,而拉应力只引起0°铺层基体开裂。由破坏起始分析可知,将复合材料圆柱壳90°铺层含量由20%提高至50%,可使结构承载能力增加56%。

Experiments and Finite Element Analysis of Laminated Composite Cylindrical Shells with Circular Hole Subjected to Dynamic Loads

Impact tests of composite cylindrical shells are performed and a finite element analysis is applied to reveal the damage mechanism of composite cylindrical shells with a circular hole subjected to axial compressive and transverse transient dynamic loads.The method of dynamic response analysis is established.First,the LS-DYNA FEM package is used to simulate the mechanical behaviors of composite cylindrical shells under complex impact loads.Subsequently,damage propagation is predicted by the implementation of the Chang-Chang criterion,which reduces the stiffness components of the corresponding failed elements.A good agreement is achieved between the numerical analysis and experimental results.Both the dynamic and static damage analysis indicates that,along the axial edge of the hole,the damage of the 90° layers,including fiber breakage and matrix cracking,is caused mainly by the circumferential tensile stress induced by transverse impact.However,the tensile stress only causes matrix cracking in the 0° layers.The first-element damage analysis shows that the structure bearing capacity of a composite cylindrical shell may be enhanced by 56% if the contents of the circumferential layers are increased from 20% to 50%.