航天器隔热罩在高温气流中的性能预测

Q3 Engineering

Journal of Mechanical Engineering Research and Developments Pub Date : 2019-06-28 DOI:10.30564/JMER.V2I1.763

L. I. Gracheva

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引用次数: 1

摘要

对材料与介质相互作用机制的基本理解是建立在实验研究与给定模型或结构的实际操作条件之间的对应基础上的。我们根据模拟航天器再入大气层条件下获得的材料的物理性质所带来的计算来估计热屏蔽结构的性能。热屏蔽是一种层状外壳，由玻璃纤维与酚醛树脂基体制成。弹性和热物理特性都随温度变化而变化。利用弹性理论方程、导热系数方程和数值分析同时求解三维问题，定义了圆柱形屏蔽体在高温气流作用下的热应力状态。考虑到再入大气层的温度、加热速率、气体介质压力等参数，给出了通过热涂层的应力分布的依赖关系。

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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Predicting performance of a thermal shield of a spacecraft in a high-temperature gas flow

A fundamental understanding of the mechanism of material interaction with a medium is based on correspondence between experimental studies and actual operating conditions of a given model or a structure. We estimated performance of thermal shield structures based on computations brought about considering physical properties of materials obtained under conditions simulating re-entry of a spacecraft into the atmosphere.A thermal shield is considered of a layered type shell, made of fiber glass with phenol-phormaldehide matrix. Both elastic and thermo-physical characteristics are varied depending on the temperature change.A thermal-stressed state of a cylindrical shield subjected to action of a high-temperature gas flow, is defined based on solving a 3D problem simultaneously using equations of theory of elasticity, thermal conductivity, and numerical analysis. Results are given as dependencies of stress distributions through the thermal coating, taking into account such parameters of atmosphere in re-entry as temperature, heating rate, pressure of a gaseous medium.

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来源期刊

Journal of Mechanical Engineering Research and Developments Engineering-Computational Mechanics

自引率

0.00%

发文量

审稿时长

9 weeks

期刊介绍： The scopes of the journal include, but are not limited to, the following topics: • Thermal Engineering and Fluids Engineering • Mechanics • Kinematics, Dynamics, & Control of Mechanical Systems • Mechatronics, Robotics and Automation • Design, Manufacturing, & Product Development • Human and Machine Haptics Specific topics of interest include: Advanced Manufacturing Technology, Analysis and Decision of Industry & Manufacturing System, Applied Mechanics, Biomechanics, CAD/CAM Integration Technology, Complex Curve Design, Manufacturing & Application, Computational Mechanics, Computer-aided Geometric Design & Simulation, Fluid Dynamics, Fluid Mechanics, General mechanics, Geomechanics, Industrial Application of CAD, Machinery and Machine Design, Machine Vision and Learning, Material Science and Processing, Mechanical Power Engineering, Mechatronics and Robotics, Artificial Intelligence, PC Guided Design and Manufacture, Precision Manufacturing & Measurement, Precision Mechanics, Production Technology, Quality & Reliability Engineering, Renewable Energy Technologies, Science and Engineering Computing, Solid Mechanics, Structural Dynamics, System Dynamics and Simulation, Systems Science and Systems Engineering, Vehicle Dynamic Performance Simulation, Virtual-tech Based System & Process-simulation, etc.