Effective cure cycle development via flow optimization and advanced cure environments

IF 1.8 Q3 ENGINEERING, MANUFACTURING

Advanced Manufacturing: Polymer & Composites Science Pub Date : 2020-09-01 DOI:10.1080/20550340.2020.1815276

D. Kim, S. Nutt

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引用次数: 1

Abstract

Abstract Out-time and moisture absorption in prepregs are generally unavoidable in an industrial setting, where prepreg layup can take weeks. The resin cross-linking and viscosity increase that occurs during out-time can reduce resin flow during a specified cure cycle, causing porosity. In this study, a flow-optimized cure cycle was developed, leveraging both flow level and time during out-of-autoclave (OoA) processing. First, predictive cure kinetics and viscosity models were used to model viscosity evolution under selected cure conditions, accounting for initial out-times and humidity conditioning. To quantify resin flow, an ‘effective flow number’ metric was defined as the integration of inverse viscosity evolution until the resin gelation point. The method described revealed that a rapid heating rate achieved by use of advanced tooling was essential to achieve a high effective flow number. The experimental results showed that the effective flow number is a useful criterion to limit flow-induced defects. The method presented also extends the boundary (by 175%) of the manufacturer’s specified out-life for OoA prepreg materials. Graphical Abstract

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通过流程优化和先进的固化环境，有效开发固化周期

在工业环境中，预浸料的停机时间和吸湿性通常是不可避免的，预浸料的铺层可能需要数周时间。在停机期间发生的树脂交联和粘度增加会减少树脂在特定固化周期内的流动，从而导致孔隙。在这项研究中，开发了一个流量优化的固化周期，同时利用了高压灭菌器外(OoA)处理过程中的流量水平和时间。首先，使用预测固化动力学和粘度模型来模拟选定固化条件下的粘度演变，考虑初始超时时间和湿度调节。为了量化树脂流动，“有效流动数”指标被定义为直到树脂凝胶点的反粘度演变的积分。所描述的方法表明，通过使用先进的工具实现快速加热速度对于实现高有效流数至关重要。实验结果表明，有效流动数是限制流动缺陷的有效准则。所提出的方法还延长了制造商规定的OoA预浸料的寿命边界(延长了175%)。图形抽象

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