Laser Interferometry Method of Stress Determination in Loaded Cutting Tool Parts

R.Yu. Nekrasov; I.V. Soloviev; U.S. Putilova

doi:10.4028/www.scientific.net/AMM.698.537

Paper Titles

The Influence of Molding Powder Breakup on the Sintered Ceramic Quality
p.513

Investigation of the Process of Mechanical Alloying of Iron by Austenite Forming Elements
p.519

A Scheme for Hydrogen Evolution from Natural Gas
p.525

Experimental Study of Geometrical Parameters of Abrasive Grains in Modeling their Cutting Edges with the Surface of Rotation
p.529

Laser Interferometry Method of Stress Determination in Loaded Cutting Tool Parts
p.537

Features of Velocity and Pressure Fields Formation in the Centrifugal Dust Collector
p.542

A Method of Processing of Involute Profiles of Large-Module Gear Wheels
p.546

Assemblability and Mobility of Bricard’s Linkage Modifications
p.552

Temperature Operation Mode of Hydraulic Pressure Rings for Contact Shoes in Ore-Thermal Furnace
p.557

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 698Laser Interferometry Method of Stress...

Laser Interferometry Method of Stress Determination in Loaded Cutting Tool Parts

Abstract:

A сontinuous growth of the intensity of metal working processes in mechanical engineering, changes in the structure, functionality and cost of technological equipment, an increasing use of high-strength materials which, as a rule, are characterized by low machinability, determine the necessity of an integrated approach both to the studies of the working capacity of cutting tools and to the control of machining conditions in order to achieve maximum technical and economic efficiency in operating automated manufacturing equipment and numerically controlled machine tools.

You might also be interested in these eBooks

Electrical Engineering, Energy, Mechanical Engineering – EEM 2014

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 698)

Pages:

537-541

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.698.537

Citation:

Cite this paper

Online since:

December 2014

Authors:

R.Yu. Nekrasov*, I.V. Soloviev, U.S. Putilova

Keywords:

Cutting Tool, Interferometry, Stress

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] G. S. Andreev, The stress state of the cutting part of the cutter with periodic cutting, Durability of the cutting tool, Moscow, 1969, pp.28-37.

Google Scholar

[2] A. I. Betaneli, Communication method of calculating the strength of the cutting part of the tool, Bulletin of engineering. 2 (1965) 16-18.

Google Scholar

[3] V. F. Bobrov, Determination of stresses in the cutting part of the cutting tools, High-performance cutting in mechanical engineering, Moscow, 1966, pp.228-233.

Google Scholar

[4] A. M. Geniatulin, Holographic method research strained elements of assorted cutters, Optical-geometrical methods in the study of deformations and stresses and their standardization, Gorky, 1982, pp.83-84.

Google Scholar

[5] M. B. Gordon, Methodology and some results of a study of patterns of distribution of the friction forces and tangential stresses on the contact length of the chip from the front surface of the cutter, Issues in the application of cutting fluids in machining metals, Ivanovo, 1965, pp.41-44.

Google Scholar

[6] I. M. Kovenskiy, R. Yu. Nekrasov, U. S. Putilova, Increase management efficiency by processing high-strength steels and alloys on CNC machines, News of higher educational institutions. oil and gas. 2 (2008), pp.116-118.

Google Scholar

[7] V. A. Ostafiev, Calculation of the dynamic strength of the cutting tool, Mechanical engineering, Moscow, (1979).

Google Scholar

[8] O. S. Lomova, Mathematical modeling of structural changes in the surfaces of the workpieces at thermal perturbations in the process of sanding, Omsk scientific bulletin. 2(120) (2013), pp.95-98.

Google Scholar

[9] S. I. Petrushin, I. M. Bobrovich, M. A. Korchuganova, Optimal design of the shape of the cutting blade tools, Tomsk, (1999).

Google Scholar

[10] M. F. Poletika, M. H. Uteshev, Study of the processes of cutting the polarization-optical method, Bulletin of the Tomsk Polytechnic Institute, 1964, pp.114-115.

Google Scholar

[11] S. I. Takhman, Patterns of wear and forecast basis the wear resistance of tools from the standard hard alloys. Mechanics and physics of processes on the surface and in the contact of solid bodies, parts of technological equipment, S. I. Tahman. 3(2010).

Google Scholar

[12] M. H. Uteshev, Y. I. Nekrasov, E. V. Artamonov, Holographic installation for studying the stress-strain state of the cutting tool, Machines and tools. 6(1978), pp.38-39.

Google Scholar

[13] G. L. Hayet, L. V. Sergeev, L. M. Miranzo, The calculation of the strength of the carbide cutter as part of the body, The reliability of the cutting tool, Kiev, (1972).

Google Scholar

[14] V. G. Shalamov, Mathematical modeling in machining of metals, Chelyabinsk, (2007).

Google Scholar

[15] A. S. Yanushkin, S. O. Safonov, D. V. Lobanov, Improvement of technological processes of machine-building productions, Bratsk, (2006).

Google Scholar

[16] Tanaka Voschinobu, Ikawa Naoga, Vasugi Kuniharu Stress analysis in cutting edge Fundamental study of Cutting edge chipping. Ist. Report. Seimitsu Kikai, I. Jap. Soc. Precis.

Google Scholar

[17] A. I. Afonasov, A. A. Lasukov, Elementary Chip Formation in Metal Cutting, Russian Engineering Research. 3 (2014), p.152–155.

DOI: 10.3103/s1068798x14030034

Google Scholar