Abstract
The complex three-shaft three-reducer structural designs of helicopter transmission systems are prone to changes in the relative positions of shafting under the conditions of main rotor and tail rotor loads. These changes will affect the transmission characteristics of the entire transmission system. In this study, the planetary gear trains of helicopters were examined. Due to the fact that these structures are considered to be the most representative structures of the main reducers of helicopters, they were selected as the study objects for the purpose of examining the meshing characteristics of planetary gear trains when the relative positions of the shafting changed due to the position changes of the main rotor shafts under variable load conditions. It was found that by embedding the comprehensive time-varying meshing stiffness values of the main rotor shafts at different positions, a dynamic model of the relative position changes of the planetary gear trains could be established. Then, combined with the multibody dynamics software, the meshing characteristics of the sun gears, and the planetary gears, the planetary gears and the inner ring gears were simulated and analyzed under different inclinations and offsets of the shafting. The results obtained in this study revealed the following: (1) the average meshing force of the gears increased with the increases in the angle inclinations, and the meshing force between the sun gears and the planetary gears increased faster than the meshing force between the planetary gears and the inner ring gears. It was observed that during the changes in the shafting tilt positions, obvious side frequency signals had appeared around the peak of the meshing frequency in the spectrum. Then, with the continuous increases in the tilt position, the peak was gradually submerged; (2) the average meshing force of the gears increased with the increases in the offset, and the increasing trend of the meshing force between the sun gears and the planetary gears was similar to that observed between the planetary gears and the inner ring gears. It was found that when the shafting offset position changed, there were obvious first and second frequency doubling in the spectrum; (3) the mass center orbit radii of the sun gears increased with the increases in the shafting position changes, and the changes in the angular tilt position were found to have greater influencing effects on the mass center orbit radii of the sun gears than the changes in the offset positions. This study’s research findings will provide a theoretical basis for future operational status monitoring of the main transmission systems of helicopters and are of major significance for improvements in the operational stability of helicopter transmission systems, which will potentially ensure safe and efficient operations.
Highlights
The complex three-shaft three-reducer structural designs of helicopter transmission systems are prone to changes in the relative positions of shafting under the conditions of main rotor and tail rotor loads
This study considered to reveal the dynamic response characteristics of the helicopter shaft systems under changes in the relative position, which could potentially provide a theoretical basis for the failure mechanism analysis of the helicopter transmission, the operational status monitoring of the helicopter transmission systems, and be of major significance for improving the operation stability of the helicopter transmission systems and ensuring safe and efficient operations
This study mainly focused on the changes in the gear meshing force with the different tilt positions and offset positions of the main rotor shaft
Summary
The transmission system of helicopters, including the main reducers, intermediate reducers, tail reducers, main rotor shafts, power transmission shafts, and tail transmission shafts (namely, “three shafts and three reducers”), is characterized by compact structures, lightweight, high process precision, high transmission power levels, and high reduction ratios. Parker and Wu mainly used a finite element method to analyze the vibration modes of planetary gear trains, focusing on the effects of such factors as meshing stiffness values and contact ratios on the suppression of system vibrations and noise [24]. In another related study, Chao et al, Liu et al, and Mbarek et al analyzed and studied the dynamic characteristics and meshing stiffness of the planetary gear trains with tooth profile errors, cracks, and other faults [25,26,27]. The results obtained in this research investigation were considered as supplements for the continued improvements of the dynamics of helicopter transmission systems and gear systems
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