Surface porosity development in tool-side facesheets of honeycomb core sandwich structures during co-cure

IF 1.8 Q3 ENGINEERING, MANUFACTURING

Advanced Manufacturing: Polymer & Composites Science Pub Date : 2022-04-03 DOI:10.1080/20550340.2022.2056313

D. Zebrine, Elana Wadhwani, S. Nutt

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引用次数: 1

Abstract

Abstract Co-cure of honeycomb core sandwich structures combines the consolidation of composite prepreg facesheets with bonding of facesheets to a low-density core in a single thermal cycle for efficient manufacturing. The coupling of multiple process phenomena and the complex geometry of honeycomb cores, however, can lead to defects in cured parts. Effects of co-cure on void formation at the tool-side facesheet surface remain unclear. We employ autoclave processing and an in situ visualization technique to elucidate physical mechanisms by which surface porosity forms, and the effects of pressure on this formation. Results displayed a multi-stage development, including evacuation of entrapped air, followed by evolution and subsequent entrapment of dissolved volatiles in the prepreg resin, and demonstrated the utility of elevated pressure in reducing porosity. These findings describe the physics underlying porosity formation at the tool-facesheet interface, and provide insight into potential mitigation strategies to produce sandwich panels with defect-free facesheet surfaces. Graphical Abstract

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共固化过程中蜂窝芯夹层结构工具侧表面孔隙度的发展

蜂窝芯夹芯结构的共固化将复合预浸料面板的固结与面板与低密度芯的粘合结合在一起，在单热循环中实现高效制造。然而，多种工艺现象的耦合和蜂窝芯的复杂几何形状会导致固化件的缺陷。共固化对工具侧表面孔隙形成的影响尚不清楚。我们采用高压灭菌处理和现场可视化技术来阐明表面孔隙形成的物理机制，以及压力对这种形成的影响。结果显示了一个多阶段的发展过程，包括被困空气的排出，然后是预浸树脂中溶解挥发物的演化和随后的捕获，并证明了高压在降低孔隙率方面的作用。这些发现描述了工具-面板界面孔隙形成的物理原理，并为生产无缺陷面板的夹层板提供了潜在的缓解策略。图形抽象

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来源期刊

Advanced Manufacturing: Polymer & Composites Science ENGINEERING, MANUFACTURING-

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

16 weeks