材料科学
复合材料
复合数
弯曲
纤维
铝
管(容器)
曲面(拓扑)
吸收(声学)
碳纤维复合材料
工作(物理)
杠杆
光学显微镜
表面能
抗弯刚度
相似性(几何)
纤维增强复合材料
作者
Mohammadali Rastak,Suong V. Hoa
标识
DOI:10.1016/j.compositesb.2025.113175
摘要
Hybrid aluminum/thermoplastic composite tubes manufactured by automated fiber placement (AFP) are promising energy-absorbing members, yet their performance is governed by the aluminum–laminate interface. We study two nominally identical lay-ups that differ only in the first ply at the aluminum surface (CF/PEEK vs. GF/PEEK) and link interfacial quality to the four-point-bending response. Optical microscopy shows that the GF/PEEK first ply produces smaller gaps at the interface. Correspondingly, mechanical tests exhibit higher initial stiffness, higher peak load, and greater energy absorption relative to the CF/PEEK case. A finite-element framework that replicates the test setup varies only the interface condition—no-bond (contact/friction), partial-bond with a zero-thickness cohesive-zone model (CZM), and full-bond—while bracketing failure with two criteria: a conservative maximum-stress trigger and a mode-aware Hashin formulation. The GF/PEEK configuration shows similarity to the defined partial-bond response, the CF/PEEK configuration to the no-bond limit, and the full-bond case defines an achievable upper bound. Overall, the results demonstrate that interfacial condition is an effective lever for improving bending performance in hybrid aluminum/thermoplastic composite tubes.
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