An active forming grinding method for cylindrical involute gears based on a second-order transmission error model

Volume 2, Issue 1, February 2019     |     PP. 1-14      |     PDF (1211 K)    |     Pub. Date: March 23, 2019
DOI:    355 Downloads     111987 Views  

Author(s)

Gang Li, Department of Mechanical Engineering, University of Maryland, Baltimore County, Baltimore, MD, USA

Abstract
An active form-grinding method is proposed to obtain excellent and stable contact performance of cylindrical gears by designing modification forms based on a predesigned controllable second-order transmission error function. First of all, a predesigned second-order transmission error polynomial function is assigned to the gear drive. Mathematical models of modified tooth surfaces that can describe their local deviation and ease-off topography are then obtained with the predesigned second-order transmission error function. Moreover, the form-grinding wheel’s profile equation, the coordinate transformation matrix during form-grinding, and settings of computer numerical control form-grinding programs for this active design method can be determined. This approach is ultimately conducted on three involute cylindrical gear pairs to demonstrate its feasibility and effectiveness.

Keywords
Cylindrical gears; Second-order transmission error; Active design; Form-grinding

Cite this paper
Gang Li, An active forming grinding method for cylindrical involute gears based on a second-order transmission error model , SCIREA Journal of Mechanical Engineering. Volume 2, Issue 1, February 2019 | PP. 1-14.

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