轴流压气机转子叶片非同步振动研究进展

doi:10.7527/S1000-6893.2022.28044

Abstract

Abstract:

The unsteady fluid-solid-thermal-acoustic coupling problem of aeroengines involves multiple aspects such as engine performance， airworthiness， and safety， which are unavoidable in the independent development of high performance aeroengines. Non-synchronous vibration of compressor rotor blades is a new type of aeroelasticity problem， involving multidisciplinary intersection. With the increase of aerodynamic load and decrease of damping， new high performance compressors have encountered the non-synchronous vibration problem， leading to excessive vibration stress of the rotor blade， and the blade fracture failure caused by it is also common. However， its mechanism and control method have not been fully understood. The phenomena and characteristics of non-synchronous vibration of axial compressor blades are reviewed and summarized. Then， the research progress of the generation mechanism， influence factors and suppression methods of non-synchronous vibration is reviewed， aiming to expand the theoretical understanding of the non-synchronous vibration induced by unstable flow， as well as to improve the independent design and troubleshooting abilities of advanced aeroengines. Finally， the future development of this field is prospected.

Key words: axial compressor, non-synchronous vibration of rotor blade, flow instabilities, aeroelasticity, vibration suppression

CLC Number:

V231.1

Songbai WANG, Yong CHEN, Yadong WU, Shaoping ZHANG, Zhipeng CAO. Research progress on non-synchronous vibration of axial compressor rotor blade[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(17): 28044-028044.

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Research progress on non-synchronous vibration of axial compressor rotor blade

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