Abstract
In this work, an improved computational method for the prediction of the vibration and noise of a gearbox that considers the flexibility of the shaft is developed. Based on the finite element method (FEM), a coupled dynamic model of a spur gear-shaft-bearing system is established, and the time-varying mesh stiffness (TVMS), the time-varying bearing stiffness (TVBS), and the flexibility of the shaft are considered. The Newmark integration method (NIM) is utilized to obtain the dynamic load of the bearing. Furthermore, the proposed model is validated by experiments. The bearing load is then considered to be the excitation of the housing, and the radiated noise is calculated via the finite element method/boundary element method (FEM/BEM). The effects of the shaft flexibility on the bearing response and radiated noise are discussed based on the proposed method. The results demonstrate that, when the shaft flexibility is considered, the system undergoes the bending vibration of the shaft, and the vibration amplitude and excitation frequency components of the bearing load decrease significantly. Additionally, the main resonance mode of the gearbox is changed, and the radiated noise is enhanced. The effects of the input speed and shaft stiffness on the bearing response and radiated noise are also investigated. The results provide a theoretical basis for the further development of the vibration and noise reduction of gearboxes.
Highlights
Gear systems are characterized by compact structure and high transmission efficiency, and they are widely used in the automotive, aerospace and power generation industries
It is of great significance to estimate and control the vibration and noise of gearboxes to improve the dynamic characteristics of gear systems and design a high-quality silent gearbox
In this paper, a coupled dynamic model of a spur gearshaft-bearing system that considers the flexibility of the shaft is developed based on the Timoshenko beam theory
Summary
Gear systems are characterized by compact structure and high transmission efficiency, and they are widely used in the automotive, aerospace and power generation industries. S. Wang et al.: Improved Computational Method for Vibration Response and Radiation Noise Analysis proposed a comprehensive, fully-coupled dynamic model of a gear-shaft-bearing-case system to determine more accurate bearing responses to predict the noise of the gearbox. The structure and mass of the shaft have always been neglected, and the modal characteristics of the system have usually been computed by considering only the gear torsional vibration; only sparse research has focused on the influence of the shaft flexibility on the vibration dynamic responses and noise of the gearbox. A finite element model for housing is established for the modal analysis calculation, to which boundary conditions should be applied according to the assembly relation of the gearbox. The actual determination of nodes and elements is up to the specific structure and the requirements for calculation
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