A time-dependent dynamic model for ball passage vibration analysis of recirculation ball screw mechanism

Ball passage vibration arising during recirculation of rolling elements is a limitation of high-precision performance associated with ball screw. A relatively deep understanding of this phenomenon when rolling balls leave load area and enter circulation channel has been achieved by now. However, few mechanical models are established for calculation of rolling ball contact deformation and force inside nut while moving by taking into account transient phase at import and export of circulation channel. In this work, we present a general time-dependent dynamic model for description of ball motion and axial periodic micro fluctuation within ball screw subjected to external load. The numerical simulation is employed to deal with equation of motion including segmented restoring force function. Effects of applied load, preload and screw rotational speed on dynamic response are discussed theoretically. Reduced vibration amplitude may be realized by small ball diameter and phase difference between ball groupings. Proposed model is experimentally illustrated. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

A general time-dependent dynamic model for describing ball motion and axial periodic micro fluctuation within a ball screw subjected to external load is proposed in this study. The effects of applied load, preload, and screw rotational speed on dynamic response are discussed theoretically, and reducing vibration amplitude is suggested through small ball diameter and phase difference between ball groupings. The proposed model is experimentally validated.