Abstract

The spherical plain bearing test bench is a necessary detecting equipment in the research process of self-lubricating spherical plain bearings. The varying environmental temperatures cause the thermal deformation of the wear-depth detecting system of bearing test benches and then affect the accuracy of the wear-depth detecting data. However, few researches about the spherical plain bearing test benches can be found with the implementation of the detecting error compensation. Based on the self-made modular spherical plain bearing test bench, two main causes of thermal errors, the friction heat of bearings and the environmental temperature variation, are analysed. The thermal errors caused by the friction heat of bearings are calculated, and the thermal deformation of the wear-depth detecting system caused by the varying environmental temperatures is detected. In view of the above results, the environmental temperature variation is the main cause of the two error factors. When the environmental temperatures rise is 10.3 °C, the thermal deformation is approximately 0.01 mm. In addition, the comprehensive compensating model of the thermal error of the wear-depth detecting system is built by multiple linear regression (MLR) and time series analysis. Compared with the detecting data of the thermal errors, the comprehensive compensating model has higher fitting precision, and the maximum residual is only 1 μm. A comprehensive compensating model of the thermal error of the wear-depth detecting system is proposed, which provides a theoretical basis for the improvement of the real-time wear-depth detecting precision of the spherical plain bearing test bench.

Highlights

  • The self-lubricating spherical plain bearings are special journal bearings which inlay or bond the self-lubricating solid materials between the inner and outer races

  • Hu et al [5] made a comprehensive compensating model for the wear-depth detecting system of the spherical plain bearing test bench based on the multi-body kinematics and verified its accuracy by FEM, but didn’t compensate the thermal errors, either

  • Based on the self-made modular spherical plain bearing test bench, this paper calculates the thermal errors caused by the friction heat of the spherical plain bearing and the assistant rolling bearing, and detects the thermal deformation of the detecting system caused by the environmental temperature variation

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Summary

Introduction

The self-lubricating spherical plain bearings are special journal bearings which inlay or bond the self-lubricating solid materials between the inner and outer races. Which affect the real-time wear-depth detecting precision of the spherical plain bearing test bench, Hu et al Chin. Zhou [4] built the thermal error compensation model of the spherical plain bearing test bench under the high temperature operating condition, but did not verify the fitting precision and the applicability of this model, nor compensated the thermal errors. Hu et al [5] made a comprehensive compensating model for the wear-depth detecting system of the spherical plain bearing test bench based on the multi-body kinematics and verified its accuracy by FEM, but didn’t compensate the thermal errors, either. Based on the self-made modular spherical plain bearing test bench, this paper calculates the thermal errors caused by the friction heat of the spherical plain bearing and the assistant rolling bearing, and detects the thermal deformation of the detecting system caused by the environmental temperature variation. According to the above experimental data, the comprehensive compensating model of the thermal error of the weardepth detecting system is built by MLR and time series analysis, and the applicability of the comprehensive compensating model is verified in the experiment

Wear‐Depth Detecting Principle of Spherical Plain Bearings
Thermal Error Verification of the Wear‐Depth Detecting System
Comprehensive Compensation Model of the Thermal
Conclusions

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