Permeability of co-cured honeycomb sandwich skins: effect of gas transport during processing

IF 1.8 Q3 ENGINEERING, MANUFACTURING Advanced Manufacturing: Polymer & Composites Science Pub Date : 2020-08-04 DOI:10.1080/20550340.2020.1802685
Trisha Palit, T. Centea, M. Anders, D. Zebrine, S. Nutt
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引用次数: 2

Abstract

Abstract Potential links between pressure conditions during co-cure of honeycomb sandwich panels, the extent of gas flow through facesheet and bond-line, and the level of permeability in the cured skin were evaluated. Half-sandwich structures comprised of fiber-reinforced polymer facesheets, film adhesive, and core were fabricated using a custom-built lab fixture. Autoclave, bag, and core pressures were varied to produce controlled, constant pressure differences during cure, and the resulting skins were tested for permeability using a fixture constructed to measure gas flow rate across the skins and to locate gas flow pathways. Facesheet cross-sections were analyzed to evaluate porosity. Porosity and the number of gas flow pathways were correlated to permeability, but significant gas flow was possible without high void content or with few channels, as pressure differentials led to complex variations in permeability. Overall, the study provides new insights into gas transport during composites processing and manufacturing, and the results provide guidance for modifying manufacturing processes to ensure part quality.
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共固化蜂窝夹层皮的透气性:加工过程中气体输送的影响
摘要研究了蜂窝夹层板共固化过程中的压力条件、通过面板和粘结线的气体流动程度以及固化表面的渗透性水平之间的潜在联系。半夹层结构由纤维增强聚合物面板、薄膜粘合剂和芯组成,使用定制的实验室夹具制造。在固化过程中,通过改变高压灭菌器、包和岩心的压力来产生可控的、恒定的压力差,并使用一种夹具来测量穿过表皮的气体流速并确定气体流动路径,从而测试所得表皮的渗透性。分析面板横截面以评估孔隙度。孔隙度和气体流动通道的数量与渗透率相关,但由于压力差导致渗透率的复杂变化,在孔隙含量不高或通道较少的情况下,也可能产生显著的气体流动。总体而言,该研究为复合材料加工制造过程中的气体输送提供了新的见解,并为修改制造工艺以确保零件质量提供了指导。
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来源期刊
CiteScore
4.00
自引率
0.00%
发文量
11
审稿时长
16 weeks
期刊最新文献
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