The Research into the Effect of Conditions of Combined Electric Powered Diamond Processing on Cutting Power

D.V. Lobanov; Pavel V. Arkhipov; A.S. Yanyushkin; Vadim Skeeba

doi:10.4028/www.scientific.net/KEM.736.81

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 736The Research into the Effect of Conditions of...

The Research into the Effect of Conditions of Combined Electric Powered Diamond Processing on Cutting Power

Abstract:

The paper presents results of the investigation into efficiency of high-tensile composite materials grinding with metal bonded diamond abrasive tools, as well as it demonstrates the necessity to stabilize diamond disks cutting properties in order to reduce cutting power, since it is one of important economic indicators of processing. The comparative analysis of preliminary studies of various diamond processing methods reveals that the minimal cutting power is observed when using the combined method of electric powered diamond processing which includes electrochemical grinding and simultaneous continuous electrochemical dressing of the grinding disk surface. Further research into the suggested method reveals relevant mathematical dependences of metal-bonded diamond disks cutting power and electric modes. The analysis of the results shows that combining of hard-alloy surface electrochemical dissolution and electrochemical dressing of the disk surface facilitates mechanical cutting with high effectiveness and little effort. This leads to substantial reduction of cutting power as compared with other methods. The reasonable electric modes are discovered which provide the minimal cutting power without reducing efficiency of the process and quality of finished product.

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Periodical:

Key Engineering Materials (Volume 736)

Pages:

81-85

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.736.81

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Online since:

June 2017

Authors:

D.V. Lobanov*, Pavel V. Arkhipov, A.S. Yanyushkin, Vadim Skeeba

Keywords:

Cutting Power, Diamond Processing, Grinding, Hard-Alloy Materials, Metal-Bonded

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* - Corresponding Author

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