Research and optimization of production cycle of high-precision composite spacecraft antenna reflector

Kosmicheskie apparaty i tekhnologii Pub Date : 2019-06-21 DOI:10.26732/2618-7957-2019-2-59-72

N. A. Berdnikova, O. Belov, А. V. Lopatin

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引用次数: 1

Abstract

The article presents a finite element model of CFRP (carbon fiber reinforcement material) reflector polymerization in autoclave for prediction of its shape after removing from the tool. The simulation was performed in the FEM software environment. The technique has developed in this work provides an opportunity to predict a shape and values of the production deformation of the reflector prior to its manufacture, and, if necessary, to introduce design and technological modifications. Successful verification of the finite-element modeling results of the reflector polymerization was performed using a full-scale experiment. Tool from CFRP has been created to forming the composite antenna reflector. This tool is cheaper than the Invar tool currently used. Also, the CFRP tool requires less time to manufacture. Recommendations for improving the technological process of composite contour antenna reflectors production manufactured on CFRP-tool are developed in the paper. The optimum curing mode of the composite reflector is determined. The research results were used in the performance of experimental design work and in the manufacture of reflectors for the spacecraft.

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高精度复合航天器天线反射器生产周期的研究与优化

本文建立了CFRP（碳纤维增强材料）反射器在高压釜中聚合的有限元模型，用于预测其从工具中移除后的形状。仿真是在有限元软件环境中进行的。这项工作中开发的技术提供了一个机会，可以在制造前预测反射器的形状和生产变形值，并在必要时引入设计和技术修改。使用全尺寸实验成功验证了反射器聚合的有限元建模结果。由碳纤维增强塑料制成的工具已被用于形成复合天线反射器。这个工具比目前使用的Invar工具便宜。此外，CFRP工具需要更少的制造时间。本文提出了改进在CFRP工具上生产复合材料异形天线反射器的工艺流程的建议。确定了复合反射镜的最佳固化方式。研究结果用于实验设计工作和航天器反射器的制造。

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

Kosmicheskie apparaty i tekhnologii

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审稿时长

8 weeks