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Processing the Working Parts of Tools Used in Construction Industry Using High Energy Methods

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Abstract:

This paper considers the effect of hardening of throwaway cutting inserts made of hard alloy T15K6 using continuous laser impact at various modes. Tests were carried outon inserts made of hard alloy T15K6. The cutting properties of the inserts were determined by cutting on a T612 vertical milling machine. A face mill with a diameter of 100 mm with mechanical mounting of tested inserts was used as a tool.Dry milling was performed using two inserts. At that, cutting mode was of impact natureas the mill diameter was larger than the width of machined workpiece. Number of passes – 5. Cutting modes:v = 197 m/min, h = 1 mm, S = 160 mm/min, b = 90 mm. Machiningwasperformedonworkpieces made of 40X grade steel (GOST 4543-71). Workpiecedimensions– 160x60x90 mm. During the machining, hard alloy inserts moved beyond the workpiece edge and cut into it from the other side. One of the main performance characteristics of hard alloys is material rigidity (modulus of elasticity, Е). Tests were carried out after various types of laser impact at bending and material rigidity was determined by strain gauging. Decreasein the slopeofstraight-lineportionofrelativestrain-versus-stress curve at bending indicates the decrease in hard alloys’ modulus of elasticity after laser processing. Small defect structure is being formed.

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Periodical:

Materials Science Forum (Volume 992)

Pages:

647-651

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.992.647

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Online since:

May 2020

Authors:

S.I. Bogodukhov*, E.S. Kozik, E.B. Shvidenko, B.S. Garipov

Keywords:

Bending Strength, Deoxidation of Salt Baths, Hardening, Hardness, Heat Treatment, Salt Baths, Tempering

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© 2020 Trans Tech Publications Ltd. All Rights Reserved

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