Abstract
In power gear honing, the random distribution of abrasive grains on the tooth surface of the honing wheel is the main factor that influences the machining performance of high-quality hardened gears. In order to investigate the micro-edge cutting performance of the active abrasive grains on the workpiece gear, the real honing process is simplified into a micro-edge cutting model with random distribution of active abrasive grains in the cells of the meshing area by obtaining the random distribution states such as the position, orientation and quantity of the honing wheel teeth. The results show that although the active abrasive grains are distributed at different locations, they all experience three types of material removal—slip rubbing, plowing and cutting—allowing the gear honing process to have the combined machining characteristics of grinding, lapping and polishing. The active abrasive grains in first contact produce high honing force, high material removal efficiency and poor surface roughness on the machined workpiece, while the latter ones have the opposite effects. The dislocation angle affects the chip shape and chip discharging direction, and the highest honing force and material removal efficiency is achieved with a dislocation angle of 135°. The higher the number of active abrasive grains in a given contact area, the higher the material removal efficiency.
Highlights
Precision hardened gears are widely used and in great demand in fields such as high-performance automobiles and high-end robots, which have high requirements for the lifespan, transmission efficiency, and load capacity of gears
Power gear honing is a new technology that offers an alternative to grinding for precision-hardened gears, which has the advantages of improving the geometric accuracy of tooth orientation and tooth shape, prolonging the working life of gears, reducing transmission noise and increasing the bearing capacity of tooth surfaces [1,2,3,4]
An equivalent model of micro-edge honing with randomly distributed active abrasive grains was established
Summary
Precision hardened gears are widely used and in great demand in fields such as high-performance automobiles and high-end robots, which have high requirements for the lifespan, transmission efficiency, and load capacity of gears. The geometric characteristics of active abrasive grains on the surface of grinding wheels play an important role in the removal of workpiece materials, grinding force, surface roughness, machining efficiency and surface quality, and the grinding mechanism of active abrasive grains offers valuable insights into the machining characteristics of gear honing [22,23,24,25]. It is still challenging to study the influence of parameters such as the distribution state, geometric characteristics and the number of CBN abrasive grains on honing performance This is because the abrasive grains are randomly distributed on the honing wheel, and the geometry is irregular and the spatial meshing motion is complicated, which makes the micro-cutting process between the abrasive grains and the workpiece more complex [1,4]. The finite-element method is applied to simulate the process of removing the workpiece material by multi-abrasive grains along the contact traces, and the material removal performances, such as material removal rate, chip breakage and surface roughness influenced by active abrasive grains, are explored and discussed
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
