Air evacuation and resin impregnation in semi-pregs: effects of feature dimensions

IF 1.8 Q3 ENGINEERING, MANUFACTURING

Advanced Manufacturing: Polymer & Composites Science Pub Date : 2020-04-02 DOI:10.1080/20550340.2020.1768348

S. Schechter, Lessa K. Grunenfelder, S. Nutt

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引用次数: 3

Abstract

Abstract Prepregs with discontinuous resin (semi-pregs) impart robustness to vacuum-bag-only processing of composites. Limited guidance exists for evaluating advantageous resin patterns (i.e. dry space dimensions required to achieve both efficient air evacuation and full resin infiltration during cure). A flow front model was developed based on resin cure kinetics and rheological behavior, and then determined maximum dry space dimensions for semi-pregs under a range of realistic manufacturing conditions. Model predictions were validated in situ. Under controlled laboratory cure conditions, small surface openings (≤3.7 mm) resulted in full resin infiltration. Under adverse conditions (resin with accrued out-time), the maximum opening size dropped 40% (to ≤2.2 mm). Using a mathematical model, air evacuation time was calculated for various feature sizes using permeability measurements. Model predictions were tested and verified via fabrication of laminates. This methodology can be applied to other resin systems to guide vacuum-bag-only prepreg design and support robust production of composites. Graphical Abstract

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半浸渍中空气排出和树脂浸渍:特征尺寸的影响

具有不连续树脂的预浸料(半浸料)对纯真空袋复合材料的加工具有很强的鲁棒性。评估有利的树脂模式(即在固化过程中实现有效的空气排出和完全树脂渗透所需的干燥空间尺寸)的指导是有限的。基于树脂固化动力学和流变学行为建立了流动锋模型，并在一系列实际制造条件下确定了半浸渍料的最大干空间尺寸。模型预测在现场得到了验证。在受控的实验室固化条件下，小的表面开口(≤3.7 mm)导致树脂完全渗透。在不利条件下(有超时的树脂)，最大开口尺寸下降40%(≤2.2 mm)。利用数学模型，利用渗透率测量计算了不同特征尺寸的空气排出时间。通过层压板的制造对模型预测进行了测试和验证。该方法可以应用于其他树脂系统，以指导真空袋预浸料的设计，并支持复合材料的稳健生产。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