材料科学
分层(地质)
复合材料
刚度
有限元法
弯曲
韧性
纤维拔出
纤维增强塑料
断裂(地质)
失效模式及影响分析
胶粘剂
内聚力模型
还原(数学)
海水
数值分析
断裂韧性
碳纤维增强聚合物
计算机模拟
降级(电信)
环氧树脂
结构工程
碳钢
数值模拟
抗弯刚度
水分
纤维
材料性能
作者
Pengfei Liu,Zhibiao Guo
标识
DOI:10.1177/07316844251404089
摘要
This study investigates the delamination failure mechanisms of T700/8911 carbon fiber reinforced polymer (CFRP) composites in seawater environments through combined experimental and numerical approaches. Three-point bending tests were conducted on specimens with [0° 16 //0° 16 ], [0°/90°] 4s //[0°/90°] 4s and [15°/-15°] 4s //[15°/-15°] 4s layup patterns under both ambient (25°C) and accelerated hygrothermal conditions (70°C temperature and 95% relative humidity). Experimental results revealed that moisture absorption caused a 23–37% reduction in interfacial bond strength. This reduction significantly altered failure modes from classical delamination to predominant interfacial debonding. The finite element model developed in ABAQUS incorporated humidity-dependent cohesive zone parameters and modified traction-separation laws, achieving excellent correlation with experimental data. Key findings demonstrate that hygrothermal exposure increases interlaminar fracture toughness while reducing in-plane modulus, leading to higher critical loads (28–35% increase) but lower stiffness in the linear elastic stage. The cohesive zone modeling approach successfully captured the three-phase delamination process: initial elastic deformation, critical crack initiation, and stable propagation. Analysis of mode mix ratios showed cohesive elements transition from shear-dominated to tensile-dominated damage as delamination progresses. The study establishes quantitative thresholds for interfacial stiffness reduction (15–20%) and provides a validated modeling framework for predicting performance degradation of marine composites, offering valuable insights for designing durable offshore structures in seawater environments.
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