Influence of the Random System Parameters on the Nonlinear Dynamic Characteristics of Gear Transmission System
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Jingyue Wang
,
Haotian Wang
Abstract
In order to analyze the influence of the random parameters of the system on the nonlinear dynamic characteristics of the gear transmission system, considering the random perturbation of damping ratio, gear backlash, meshing frequency, meshing stiffness and the low frequency excitation caused by torque fluctuation, the random vibration equations of three-degree-of-freedom gear transmission system are established according to the Newton’s law. The motion differential equations are solved by the Runge–Kutta method. The effects of different random parameters such as load ratio, tooth frequency ratio, damping ratio, gear backlash and meshing stiffness on the dynamic response of the gear transmission system are analyzed in light and heavy loads and low and high speeds.
Funding statement: The authors gratefully acknowledge the support of programs for the State Key Laboratory of Mechanical Transmissions (SKLMT-KFKT-201605), the Natural Science Foundation of Liaoning Province of China (20170540786), the China Postdoctoral Science Foundation (2017M610497), the Open Foundation of Key Discipline of Mechanical Design and Theory of Shenyang Ligong University (4771004kfx08) and the National Natural Science Foundation of China (51275082).
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© 2017 Walter de Gruyter GmbH, Berlin/Boston
Articles in the same Issue
- Frontmatter
- Influence of Fuel Premixing on Partially Premixed Flames in Porous-Wall Channels
- Self-Aeration Modelling Using a Sub-Grid Volume-Of-Fluid Model
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A Fractional
- Existence Results of Mild Solutions for Impulsive Fractional Evolution Equations with Periodic Boundary Condition
- Numerical Analysis for Heat Transfer Laws of a Wet Multi-disk Clutch During Transient Contact
- An Accelerated Algorithm for Improvement of Adaptation in Nonlinear Adaptive Control
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Articles in the same Issue
- Frontmatter
- Influence of Fuel Premixing on Partially Premixed Flames in Porous-Wall Channels
- Self-Aeration Modelling Using a Sub-Grid Volume-Of-Fluid Model
-
A Fractional
- Existence Results of Mild Solutions for Impulsive Fractional Evolution Equations with Periodic Boundary Condition
- Numerical Analysis for Heat Transfer Laws of a Wet Multi-disk Clutch During Transient Contact
- An Accelerated Algorithm for Improvement of Adaptation in Nonlinear Adaptive Control
- Influence of the Random System Parameters on the Nonlinear Dynamic Characteristics of Gear Transmission System
