Effect of Bearing Support Parameters on the Radial and Angular Deformation of Rotor Shaft Gear Based on CRDRS Support Configuration with Intermediate Bearing Support

Effect of Bearing Support Parameters on the Radial and Angular Deformation of Rotor Shaft Gear Based on CRDRS Support Configuration with Intermediate Bearing Support

The rotor shaft is a critical component responsible for transmitting engine power to the helicopter’s rotor. Deformation of the rotor shaft can affect the meshing performance of the output stage gears in the main gearbox, thereby affecting load transfer efficiency. By adjusting the support parameter...

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Bibliographic Details
Main Authors: Xiaojie Yuan, Xiaoyu Che, Rupeng Zhu, Weifang Chen
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Machines
Subjects:
CRDRS
support position
support stiffness
radial deformation
angular deformation
Online Access:https://www.mdpi.com/2075-1702/13/6/513
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Summary:The rotor shaft is a critical component responsible for transmitting engine power to the helicopter’s rotor. Deformation of the rotor shaft can affect the meshing performance of the output stage gears in the main gearbox, thereby affecting load transfer efficiency. By adjusting the support parameters of the rotor shaft, deformation at critical positions can be minimized, and the meshing performance of the output stage gears can be improved. Therefore, it is imperative to investigate the influence of rotor shaft support parameters on the deformation of the rotor shaft. This paper takes coaxial reversing dual rotor shaft (CRDRS) support configuration with intermediate bearing support as object. Utilizing Timoshenko beam theory, a rotor shaft model is developed, and static equations are derived based on the Lagrange equations. The relaxation iteration method is employed for a two-level iterative solution, and the effects of bearing support positions and support stiffness on the radial and angular deformations of rotor shaft gears under two support configurations, simply supported outer rotor shaft–cantilever-supported inner rotor shaft, and simply supported outer rotor shaft–simply supported inner rotor shaft, are analyzed. The findings indicate that the radial and angular deformations of gear <i>s</i><sub>1</sub> are consistently smaller than those of gear <i>s</i><sub>2</sub> in the CRDRS system. This difference is particularly pronounced in the selection of support configuration. The bearing support position plays a dominant role in gear deformation, exhibiting a monotonic linear relationship. In contrast, although adjustments in bearing support stiffness also follow a linear pattern in influencing deformation, their impact is relatively limited. Overall, optimal design should prioritize the adjustment of bearing positions, particularly the layout of <i>b</i><sub>3</sub> relative to <i>s</i><sub>2</sub>, while complementing it with coordinated modifications to the stiffness of bearings <i>b</i><sub>2</sub>, <i>b</i><sub>3</sub>, and <i>b</i><sub>4</sub> to effectively enhance the static characteristics of the dual-rotor shaft gears.
ISSN:2075-1702

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