Thermal-Mechanical Analysis of Hybrid Spindle System Based on FEM

Wan Shan Wang; Peng Guan; Tian Biao Yu

doi:10.4028/www.scientific.net/AMR.565.644

Paper Titles

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Simulation of Temperature Field Induced in Localized Ultra-High Frequency Induction Brazing of Diamond Tools
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Study of Acoustic System Characteristics of Ultrasonic Machining Based on Similarity Principle
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Thermal-Mechanical Analysis of Hybrid Spindle System Based on FEM
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Study on Microstructure and Friction of Bimetal 1.5Cr4.8Ni with Cast Iron and Low Carbon Steel
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Research on Digital Filters for Si Wafer Surface Profile Measurement - Design of Filters by Total Variation
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Application of Automatic Ultrasonic Wall Thickness Measurement System in Nuclear Fuel Encrust Tube Billet Wall Abrasive Grinding
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 565Thermal-Mechanical Analysis of Hybrid Spindle...

Thermal-Mechanical Analysis of Hybrid Spindle System Based on FEM

Abstract:

The deformation of the spindle system is the main factor affecting the accuracy of ultra-high speed grinding. To calculate the deformation of ultra-high-speed grinding spindle system is required to consider not only the formation of structural deformation, but also the thermal deformation. Using the simulation method, oil temperature and grinding force are calculated in this paper. Based on these two factors, the thermal-mechanical deformation of the hybrid spindle system is analyzed and calculated with the method of FEM. the This article uses simulation methods, analysis and calculation of the oil film temperature rise and the grinding force caused by deformation of the liquid and hydrostatic spindle system factors. The methods presented in this paper can be used in digital design of various kinds of spindle systems, in order to improve the accuracy of the spindle system design.