Analyzing the Mechanisms of Cutting Tool Wear during the Machining of Corrosion-Resistant Steels

P.H. Trung; Julius L. Tchigirinsky

doi:10.4028/www.scientific.net/MSF.973.120

Paper Titles

Influence of Solid Lubricants on the Working Efficiency of a Coated-Carbide Cutting Tool under Interrupted Cutting Conditions
p.96

Influence of the Properties of Hydraulic-Cylinder Barrels Materials on the Formation of Errors during Deep Borehole Drilling
p.101

Optimization of Cutting Conditions for Turning of Ductile Materials to Achieve Favourable Ship Form
p.107

Formation of the Properties of the Surface Layer during Multi-Stage Milling
p.115

Analyzing the Mechanisms of Cutting Tool Wear during the Machining of Corrosion-Resistant Steels
p.120

The Study of the Processing Accuracy after the Grindingof the Inner Ring Raceway with the Abrasive Tool without a Sheaf
p.125

The Peculiar Properties of Obtaining the Abrasive Tool without a Sheaf
p.129

Mechanical Strength of Abrasive Segment Formed by the High-Frequency Discretization of Grinding Wheel
p.134

Hobbing of Cylindrical Wheels without Coolants
p.139

HomeMaterials Science ForumMaterials Science Forum Vol. 973Analyzing the Mechanisms of Cutting Tool Wear...

Analyzing the Mechanisms of Cutting Tool Wear during the Machining of Corrosion-Resistant Steels

Abstract:

The study analyzes physicomechanical and thermophysical properties of hard alloys with due regard to their chemical composition; reveals the dependence of both the cutting properties and regularities of carbide tool wear from cutting conditions and thermophysical properties of tool material; describes a significant impact of not only mechanical but, first and foremost, thermophysical properties of instrumental and structural materials on tool wear; and identifies ways to reduce the wear rate of a cutting tool.

You might also be interested in these eBooks

Innovative Technologies in Engineering: From Design to Competitive Product

View Preview

Info:

Periodical:

Materials Science Forum (Volume 973)

Pages:

120-124

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.973.120

Citation:

Cite this paper

Online since:

November 2019

Authors:

P.H. Trung, Julius L. Tchigirinsky

Keywords:

Advanced Plastic Deformation, Intermediate Diffusion Layer, Tool Wear, Tool Wear Resistance, Wear-Resistant Coating

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Classification of tool materials. Information on: http://studopedia.ru/4_17307_klassifikatsiya-instrumentalnih-materialov.html.

Google Scholar

[2] Zubkov, N.N., Tool materials for edge tool manufacturing, M: Nauka i obrazovaniye, 2013, p.26.

Google Scholar

[3] Talantov, N.V., Physical basics of the processes of tool cutting, wear and failure, М.: Мashinostroyeniye, 1992, p.240.

Google Scholar

[4] Talantov, N.V., Physical basics of the cutting process, Physical processes in metal cutting, Volgograd: VPI, 1984, p.3–37.

Google Scholar

[5] Lipatov, A.A., Patterns of the process of cutting high-alloy steels and ways to improve the performance of carbide tools, Ph.D. Thesis, Volgograd, 1987, p.256.

Google Scholar

[6] Chigirinskiy, Y.L., Hoang Chung Fam, Features of Processing Corrosion Resistant Steels, Materials Science Forum. 870 (2016), pp.598-602.

DOI: 10.4028/www.scientific.net/msf.870.598

Google Scholar

[7] Bykov, Y.M., 1983. Studying the features of the wear of a carbide tool with a wear-resistant coating with the purpose of increasing its operating capacity, Ph.D. Thesis, Volgograd, 1983. p.253.

Google Scholar

[8] Bondarev, A.A., Studying the influence of advanced plastic straining on the efficiency of the process of constructional steels cutting, Ph.D. Thesis, Volgograd, 2016, p.175.

Google Scholar

[9] Norchenko, P.A., Raising the efficiency of austenitic stainless steels cutting with advanced plastic straining, Ph.D. Thesis, Volgograd, 2010. p.127.

Google Scholar