Experimental evaluation of T-peel strength on functionally graded Al5083 and HDPE tri-laminated composites fabricated by colding-assisted friction stir additive manufacturing

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Hadi Tagimalek, Masoud Mahmoodi
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Abstract

Functionally graded composites offer impressive promise in overcoming the inherent weaknesses of Metal-polymer hybrid structures. In this study, functionally graded 5083 aluminum (Al5083) and high-density polyethylene (HDPE) tri-laminated composites were fabricated by colding-assisted friction stir additive manufacturing (CA-FSAM) and friction stir additive manufacturing (FSAM). Functionally graded laminate composites have been used to overcome these drawbacks by varying the thickness of the raw laminate. The thickness changes in the user sheets were functionally 0.75 mm compared to the previous laminate. Finally, the initial sheets were transformed to three thicknesses: 3, 2.25, and 1.5 mm. The bond strength between the sheets was measured using the T-peel test. In the T-peel test, the initial crack length was 25 mm and the length of the weld zone was 111 mm. The results showed that the bond strength between the laminates improved with cooling after the CA-FSAM process. The bond strength is essentially determined by the amount of covalent bonding, which, in turn, is a function of the density on the treated surface. Dislocation forest at the surface of the tri-laminate composite can be considered a consequence of T-peel test. The joining mechanism could be ascribed to mechanical interlocking, adhesion bonding at the interface of the Al5083 alloy and HDPE polymer, and metal-chip reinforcement in HDPE of the stir zone. The maximum force (Fmax) obtained in the FSAM and CA-FSAM specimens were 1057.58 and 1254.20 N, respectively. Average force of T-peel test (Favg peel) obtained in the FSAM and CA-FSAM specimens was 984.36 and 1024.32 N, respectively.

通过冷辅助摩擦搅拌快速成型技术制造的功能分级 Al5083 和高密度聚乙烯三层复合材料的 T 型剥离强度实验评估
功能梯度复合材料在克服金属-聚合物杂化结构的固有弱点方面提供了令人印象深刻的希望。采用冷辅助搅拌摩擦增材制造(CA-FSAM)和搅拌摩擦增材制造(FSAM)制备了5083铝(Al5083)和高密度聚乙烯(HDPE)三层复合材料。功能梯度层压板复合材料已被用来克服这些缺点,通过改变厚度的原始层压板。与之前的层压板相比,用户板的厚度变化在功能上为0.75 mm。最后,最初的薄片被转换成三种厚度:3、2.25和1.5毫米。采用t型剥离试验测定板材之间的粘结强度。t型剥离试验中,初始裂纹长度为25 mm,焊缝区长度为111 mm。结果表明:CA-FSAM工艺冷却后,层板间的结合强度有所提高;结合强度本质上是由共价键的数量决定的,而共价键的数量又是处理表面上密度的函数。三层复合材料表面的位错林可以认为是t剥离试验的结果。连接机理可归结为机械联锁、Al5083合金与HDPE聚合物界面的粘附结合以及搅拌区HDPE中的金属切屑增强。FSAM和CA-FSAM试样的最大受力(Fmax)分别为1057.58 N和1254.20 N。FSAM和CA-FSAM试件的平均t剥离力(Favg peel)分别为984.36 N和1024.32 N。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.10
自引率
9.80%
发文量
58
审稿时长
44 days
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