On-orbit thermal deformation prediction for a high-resolution satellite camera

•On-orbit thermal deformation analysis of a satellite camera is presented.•A thermal-structural finite element analysis model is established.•Thermal deformation of the optical system is revealed by numerical simulation.•The thermal vacuum test results validate the effective of the simulation method...

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Bibliographic Details
Published in:Applied thermal engineering 2021-08, Vol.195, p.117152, Article 117152
Main Authors: Zhang, Heng, Zhao, Xuemin, Mei, Qiang, Wang, Yue, Song, Shaoyun, Yu, Feng
Format: Article
Language:English
Subjects:
Aerospace environments
Cameras
Deformation
Dynamic response
Finite element method
Function analysis
Geosynchronous orbits
Heat conductivity
Heat transfer
High resolution
Image quality
Mathematical models
Modulation transfer function
Orbital stability
Satellite camera
Satellites
Solar radiation
Stability analysis
Structural analysis
Studies
Temperature
Thermal deformation
Thermal environments
Thermal vacuum test
Thermal vacuum tests
Thermomechanical analysis
Vacuum tests
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Summary:•On-orbit thermal deformation analysis of a satellite camera is presented.•A thermal-structural finite element analysis model is established.•Thermal deformation of the optical system is revealed by numerical simulation.•The thermal vacuum test results validate the effective of the simulation method. Thermal-structural analysis of satellite camera in the early design phase as well as during the later experimental verification is important due to the extreme thermal environment. The purpose of this work is to numerically investigate the thermal deformation for a high-resolution satellite camera under solar radiation. Based on the on-orbit thermal environment of the geosynchronous orbit, thermal-structural finite element model of the satellite camera is developed and opto-thermo-mechanical analysis of the optical system is proposed. Transient temperature distributions of the satellite camera under different extreme heat loads are obtained. Mirror deformations, translation and rotation have been introduced to the optical analysis and modulation transfer function analysis has been performed. Numerical simulation results reveal the dynamic response of the optical system under transient temperature and the thermal vacuum test predicts the imagery quality of the satellite camera, which can provide guidance for designers to analyze the on-orbit stability for the optical camera.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2021.117152