Simulative Investigation of the Influence of Different Abrasive Coating Structures in Double Face Grinding

Simulative Investigation of the Influence of Different Abrasive Coating Structures in Double Face Grinding

The double face grinding process is a manufacturing process that is used when machining plane-parallel surfaces, for example during the production of bearing rings, wafers, seal and regulator disks. However, there are challenges when machining extremely hard and large components in terms of the requ...

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Bibliographic Details
Main Authors: Arunan Muthulingam, Eckart Uhlmann
Format: Article
Language:English
Published: Publishing House of Wrocław Board of Scientific Technical Societies Federation NOT 2024-11-01
Series:Journal of Machine Engineering
Subjects:
simulation
double face grinding
abrasive coating structure
Online Access:http://jmacheng.not.pl/Simulative-Investigation-of-the-Influence-of-Different-Abrasive-Coating-Structures,196196,0,2.html
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Summary:The double face grinding process is a manufacturing process that is used when machining plane-parallel surfaces, for example during the production of bearing rings, wafers, seal and regulator disks. However, there are challenges when machining extremely hard and large components in terms of the required workpiece quality and cost-efficiency. Although the ecological disadvantages of the lapping process are present, it is often used to industrially machine such components. Therefore, the influence of different abrasive coating structures on the cooling lubricant flow was examined using Computational Fluid Dynamics (CFD) simulations. The results of the simulation studies are presented in this article. By choosing a suitable abrasive coating structure that ensures an even distribution of the cooling lubricant, the supply of cooling lubricant and chip removal during the grinding process can be improved. The results of the simulation studies show that radial grooves are unsuitable because the flow of cooling lubricant is not evenly distributed in the inner area of the grinding wheel. This can be optimized by selecting involute grooves. By improving the supply of cooling lubricant, the application range of the double face grinding process can be expanded and enables the environmentally friendly machining of extremely hard and large components with plane-parallel functional surfaces.
ISSN:1895-7595
2391-8071

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