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HomeKey Engineering MaterialsKey Engineering Materials Vol. 887Precast Textured Tool and the Construction of an...

Precast Textured Tool and the Construction of an Intensive Grinding Process Based on It

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Abstract:

The article deals with the construction of an intensive process of grinding materials using a precast textured wheel and a device for the centrifugal giving of lubricating and cooling liquid (LCL) directly to the local contact zones of the cutting and pressing abrasive grains with the processed material. The design of the tool and an effective method of coolant giving to the cutting zone are described, which provide the required roughness of the treated surface and eliminate structural changes in the surface layer under intensive grinding conditions. An increase in the rate of heat removal from the grinding zone is achieved by using a textured tool design, a device for centrifugal giving of coolant and accelerating the liquid to approximately the cutting speed. A method for constructing an intensive grinding process with a precast textured tool has been developed, the implementation of which can significantly increase the processing efficiency. The results of the research are recommended for grinding steels, cast iron and other metals and alloys that are prone to the formation of cauterization, tensile residual stresses and other thermal defects that occur under the influence of high temperature in the grinding zone.

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Periodical:

Key Engineering Materials (Volume 887)

Pages:

389-395

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.887.389

Citation:

Cite this paper

Online since:

May 2021

Authors:

V.G. Gusev*

Keywords:

Cutting Mode, Device for Giving of Coolant, Grinding, Intensive Process, Textured Tool

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© 2021 Trans Tech Publications Ltd. All Rights Reserved

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* - Corresponding Author

[1] Z.I. Kremen, V.G. Yuryev, A.F. Baboshkin, Technology of grinding in mechanical engineering, Sankt-Peterburg. (2007).

[2] Z.I. Kremen, V.G. Iur'ev, Grinding by super abrasives highly plastic alloys, Sankt-Peterburg. (2013).

[3] V.K. Starkov, Grinding by high-porous wheels, Moscow. (2007).

[4] M.J. Jackson, M.P. Hitchiner, High performance grinding and advanced cutting tools. Springer, Verlag. (2012).

[5] E. Oliveira, C. Silva, G.F. Hashimoto, Industrial challenges in grinding, CIRP Annals – Manuf. Tech. (2009) 58 (2) 663–680.

DOI: 10.1016/j.cirp.2009.09.006

[6] A.V. Tyuhta, Combinatorial method for cooling Lubricating fluid supply at flat grinding with periphery wheel, The 13-th Joint Ch.-RU Int. Sci. tech. conf. (2012).

[7] A.V. Tyukhta, Mathematical model of particle interaction of waste by a curtain from coolant at flat grinding by the wheel periphery, RU J. Fund. and appl. problem. of the equip. and tech. (2012) 3-2 (293) 60–67.

[8] A.M. Dolganov, The Perspective grinding tool with vortex cooling, All-RU sci. tech. pr. conf. Novosibirsk. (2006) 72–74.

[9] L.V. Khudobin at all, The lubricant cooling technological means and their applic ation when processing by cutting: the ref. book Moscow Mech. Eng. (2006).

[10] Yu.V. Vasilenko, The current state of the giving technology of coolant when grinding, J. Chief mech. Eng., Moscow, The Panorama pub. House. 2 (2008) 14–19.

[11] V.G. Gusev, A.V. Morozov, Discretization technology of abrasive wheels by laser beam and hydro-abrasive stream, RU J Sci. Int. Tech. in Mech. Eng. 9(73) (2017) 20–27.

[12] A.V. Morozov, Deterioration of the diamond tool at editing of discrete grinding wheels, RU J. Sci. Eng. industry bul. 3 (2016) 59–64.

[13] V.G. Gusev, P.S. Shvagirev, A.V. Morozov, The aerodynamic streams, generated by a discrete face grinding wheel, Int. Sci. Tech. Conf., RU, Tula St. un-ty. 1(2) (2004) 74–79.

[14] A. Morozov, V. Gusev, Discrete Plane Face Grinding, Pen Publ. House, Moscow. (2016).

[15] D.R. Blurtsyan, J.V. Trifonova, I.R. Blurtsyan, at all, Way of internal grinding, RU, Patent 2,182,531, May (2002).

[16] V.G. Gusev, A.V. Kirichek, I.V. Borisov, Grinding way, RU, Copyright certificate. Nov. (1990).

[17] H.N. Li, D. Axinte, Textured grinding wheels: A review, Int. J. of Machine Tools and Manufacture, 109:8–35. http://dx.doi.org/10.1016/j.ijmachtools.2016.07.001.

DOI: 10.1016/j.ijmachtools.2016.07.001

[18] A. Daneshi, B. Azarhoushang, Cylindrical Grinding by Structured Wheels, Mat. Sci. Forum, Trans Tech Publ., Switzerland. 874 (2016) 101–108.

DOI: 10.4028/www.scientific.net/msf.874.101

[19] D. Blurtsyan, Centrifugal Internal Grinding by Assembled Wheel with Radially Mobile Segments, Mat. Sci. Forum, Trans Tech Publ., Switzerland. 874 (2016) 85-91.

DOI: 10.4028/www.scientific.net/msf.874.85

[20] M.J. Jackson, M.P. Hitchiner, High performance grinding and advanced cutting tools, Springer, Verlag. (2012).