Finite Element Analysis of Structural Parameter Effects on Stiffness Nonlinearity Behavior in Aero-Engine Elastic Rings

• Published in: Aerospace Vol. 12; no. 4; p. 338
• Main Authors: Shi, Yihang, Li, Jiaqi, Yang, Zhongyu, Feng, Yinli
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.04.2025
• Subjects: aero-engine rotor system; Aerospace engines; Analysis; Assembly; Clearances; Deformation; Design; Design optimization; elastic ring; Engineering; Finite element analysis; Finite element method; Investigations; Load; Nonlinearity; Numerical analysis; Parameters; plastic deformation; Rotors; Stiffness; stiffness nonlinearity; Stress concentration; structural parameters; Systems stability; Vibration; Vibration control; China
• ISSN: 2226-4310; 2226-4310
• DOI: 10.3390/aerospace12040338

Elastic rings are extensively utilized in aero-engine rotor systems owing to their compact size and ease of assembly, where they play a critical role in vibration suppression during engine operation. The dynamic behavior of elastic rings is governed by their structural parameters, with stiffness being a pivotal factor influencing the rotor system’s performance. This study employs finite element methods to investigate the effects of elastic ring structural parameters, particularly the geometric features of bosses and internal/external assembly clearances, on stiffness nonlinearity, with a focus on its mechanisms and contributing factors. The results reveal that stiffness nonlinearity emerges when the whirling radius exceeds a critical threshold. Specifically, increasing the boss width, reducing the boss height, or augmenting the number of bosses all attenuate stiffness nonlinearity under identical whirling radii. Furthermore, external clearances exhibit a stronger capability to suppress stiffness nonlinearity compared to internal clearances. Engineering insights suggest that maintaining a small clearance fit during assembly effectively mitigates stiffness nonlinearity, thereby enhancing the rotor’s dynamic performance. This study elucidates the stiffness nonlinearity behavior of elastic rings in practical applications and provides actionable guidance for their design and operational optimization in rotor systems.