Abstract
Meshing power loss is one of the most important parts in power loss calculation of planetary gear set. However, most of the conventional methods assumed the friction coefficient between gears as a constant value in the meshing power loss calculation, and most importantly, the influence of gear tooth surface geometry is usually ignored, for example, roughness. Therefore, a new meshing power loss calculation model for planetary gear set that considers tooth surface roughness is proposed on the basis of elasto-hydrodynamic lubrication method. With the proposed model, a planetary gear set dynamic model that considers friction force between gears is first established to study the time-varying meshing forces, sliding speeds, and curvature radii of the gear pairs. Then, an elasto-hydrodynamic lubrication model of the gear pair contact interface is constructed to investigate and modify the friction force distribution in the gear meshing process of the dynamic model iteratively until the meshing forces converge to stable values. Furthermore, the relationship between the tooth surface roughness and film thickness is studied in the elasto-hydrodynamic lubrication model. After that, the meshing power loss is calculated based on the obtained meshing forces, friction coefficients, sliding speeds, and so on. The results show that there is a sudden growth of the meshing power loss at the end of the meshing cycle, which has a good agreement with the meshing force impact. And, it is found that tooth surface roughness has a direct influence on the meshing power loss of sun–planet gear pair, which yields an increasing tendency as the surface roughness growing.
Highlights
Due to the requirement of reducing carbon emissions and environmental issues, machine efficiency improvement has become a critical research topic in the past decades
The detail simulation parameters of the planetary gear set and the lubrication conditions are listed in Tables 1 and 2; sun gear is taken as the input, and the input speed and load are set to 1000 r/min and 800 N m, respectively, as an example
This article presents a new meshing power loss calculation model for planetary gear set with the elasto-hydrodynamic lubrication (EHL) taken into account, based on which the effect of tooth surface roughness is further studied
Summary
Due to the requirement of reducing carbon emissions and environmental issues, machine efficiency improvement has become a critical research topic in the past decades. Aiming to obtain a more accurate meshing power loss, a new meshing power loss calculation model of a planetary gear set that considers elastic deformation, tooth surface roughness, and lubrication conditions is established in this article. There exist three main steps in the proposed algorithm; first, the dynamic model of the planetary gear set that considers friction force on the tooth surface is presented and established, and the input boundary parameters and the initialized friction coefficients are substituted into the dynamic model to obtain the meshing force, contact radius, sliding speed, and so on. Because there are two meshing types in the planetary gear set: external and internal meshing, the meshing power loss calculation method is discussed based on the two meshing types, and the meshing force, friction force, contact radius, and sliding speed of the gear pair obtained in step 1 and step 2 are applied to derive the meshing power loss. The relative sliding speed between gear 1 and gear 2 can be obtained
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