Fast vibro-acoustic simulation methods of satellite components

• Published in: Aircraft engineering Vol. 94; no. 10; pp. 1636 - 1645
• Main Authors: Zhang, Jie, Xie, Weihua, Wang, Yakun, Zhou, Jiang, Yin, Jiacong
• Format: Journal Article
• Language: English
• Published: Bradford Emerald Publishing Limited 05.12.2022; Emerald Group Publishing Limited
• Subjects: Acoustic simulation; Acoustics; Finite element method; Ground tests; Investigations; Launching; Methods; Model accuracy; Satellites; Simulation; Statistical energy analysis; Vibration response; Components; Finite element (FE); Satellite; Vibro-acoustic analysis; Statistical energy analysis (SEA)
• ISSN: 1748-8842; 1758-4213; 1748-8842
• DOI: 10.1108/AEAT-08-2021-0248

Purpose This paper aims to fast predict vibration responses of specific locations in the satellite subject to acoustic environment. It proposes a set of vibro-acoustic simulation methods of satellite components to represent their conditions in the whole satellite during the ground tests or launching. This study aims to use vibro-acoustic models of satellite components to replace that of hard modeling and time-consuming whole satellite when only local responses are concerned. Design/methodology/approach This paper adopted experimental and numerical studies, with the latter based on the finite element (FE), statistical energy analysis (SEA) and FE-SEA hybrid theories. The vibro-acoustic model of the whole satellite was built and verified by experimental data. Based on the whole satellite model and experimental results, the fast vibro-acoustic simulation methods of all kinds of typical satellite components were discussed. Findings This paper shows that the models about satellite components not only show high consistency but also reduce 61.6% to 99.8% times compared with the whole satellite model. The recommended fast simulation methods for all kinds of typical satellite components were given in comprehensive consideration of the model accuracy, time required and response accessibility. Originality/value This paper fulfils an identified need to perform fast vibro-acoustic prediction of the local positions in satellites.