GRADIENT-BASED OPTIMIZATION OF SPACECRAFT AND AIRCRAFT THERMAL DESIGN

IF 0.8 Q3 ENGINEERING, AEROSPACE

Aviation Pub Date : 2020-09-11 DOI:10.3846/aviation.2020.13045

Laurynas Mačiulis, R. Belevičius

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引用次数: 0

Abstract

Steady-case thermal analysis plays an important role in dimensioning thermal control systems for spacecrafts and aircrafts. Usually a trial and error approach is used based on engineering judgement and experience. When thermal models become complex or there are conflicting thermal requirements, however, it becomes harder for an engineer to gain insight as to which design decisions will lead to better results. Numerical optimization, on the other hand, could provide a more robust approach for the thermal design of complex spacecraft or aircraft models. In this paper, we suggest a gradientbased multidisciplinary optimization of thermal models where the coupled derivatives of the multidisciplinary system are obtained with the adjoint method. We show that in the case of steady-state thermal analysis, there is an analytic solution of a partial derivatives of implicit heat-transfer equation that can be used to derive total derivatives of the system. We present a practical application of this method by solving a small interplanetary spacecraft thermal optimization problem consisting of one objective, 15 design variables, and 10 constraints. We found that by using gradient-based optimization with exact derivatives, the best results can be achieved by exploring the design space at multiple initial starting points without major computational overhead.

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基于梯度的航天器和飞行器热设计优化

稳态热分析在确定航天器和飞行器热控制系统的尺寸方面起着重要作用。通常采用基于工程判断和经验的试错方法。然而，当热模型变得复杂或存在冲突的热需求时，工程师就更难深入了解哪些设计决策会带来更好的结果。另一方面，数值优化可以为复杂航天器或飞机模型的热设计提供一种更稳健的方法。在本文中，我们提出了一种基于梯度的热模型多学科优化，其中用伴随方法获得了多学科系统的耦合导数。我们证明，在稳态热分析的情况下，隐式传热方程的偏导数有一个解析解，可以用来导出系统的总导数。我们通过求解一个由一个目标、15个设计变量和10个约束条件组成的小型行星际航天器热优化问题，给出了该方法的实际应用。我们发现，通过使用具有精确导数的基于梯度的优化，通过在多个初始起点探索设计空间可以获得最佳结果，而无需大量计算开销。

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

Aviation ENGINEERING, AEROSPACE-

CiteScore

2.40

自引率

10.00%

发文量

审稿时长

15 weeks

期刊介绍： CONCERNING THE FOLLOWING FIELDS OF RESEARCH: ▪ Flight Physics ▪ Air Traffic Management ▪ Aerostructures ▪ Airports ▪ Propulsion ▪ Human Factors ▪ Aircraft Avionics, Systems and Equipment ▪ Air Transport Technologies and Development ▪ Flight Mechanics ▪ History of Aviation ▪ Integrated Design and Validation (method and tools) Besides, it publishes: short reports and notes, reviews, reports about conferences and workshops