Strengthening the Surface Layer of Tools with State-of-the-Art Technologies

Kostyk, Kateryna; Kostyk, Viktoriia; Kovalev, V. D.

doi:10.15407/ufm.22.01.078

Cited by 5 publications

(2 citation statements)

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“…For making deformations, hardening includes blasting [5], magnetic-pulse processing [6], hardening by explosion [7], smoothing and rolling [8], and ultrasonic treatment [9]. Each hardening processing method based on the deformation effect on the cutting tool has the following characteristics: mechanics of deformation, specific features of formation of geometrical and physical-mechanical properties of the surface layer, and the process conditions.…”

Section: Introductionmentioning

confidence: 99%

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Impact of Magnetic-Pulse and Chemical-Thermal Treatment on Alloyed Steels’ Surface Layer

et al. 2022

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The relevant problem is searching for up-to-date methods to improve tools and machine parts’ performance due to the hardening of surface layers. This article shows that, after the magnetic-pulse treatment of bearing steel Cr15, its surface microhardness was increased by 40–50% compared to baseline. In this case, the depth of the hardened layer was 0.08–0.1 mm. The magnetic-pulse processing of hard alloys reduces the coefficient of microhardness variation from 0.13 to 0.06. A decrease in the coefficient of variation of wear resistance from 0.48 to 0.27 indicates the increased stability of physical and mechanical properties. The nitriding of alloy steels was accelerated 10-fold that of traditional gas upon receipt of the hardened layer depth of 0.3–0.5 mm. As a result, the surface hardness was increased to 12.7 GPa. Boriding in the nano-dispersed powder was accelerated 2–3-fold compared to existing technologies while ensuring surface hardness up to 21–23 GPa with a boride layer thickness of up to 0.073 mm. Experimental data showed that the cutting tool equipped with inserts from WC92Co8 and WC79TiC15 has a resistance relative to the untreated WC92Co8 higher by 183% and WC85TiC6Co9—than 200%. Depending on alloy steel, nitriding allowed us to raise wear resistance by 120–177%, boriding—by 180–340%, and magneto-pulse treatment—by more than 183–200%.

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Section: Introductionmentioning

confidence: 99%

“…All methods of magnetic treatment of tools and machine parts are classified as follows [6]: the processing of static magnetic field (intensity 100-1000 kA/m for exposure 10-300 s); magnetic-pulse processing field (intensity 50-2000 kA/m at a pulse duration of 0.1-10 s).…”

Section: Introductionmentioning

confidence: 99%

Impact of Magnetic-Pulse and Chemical-Thermal Treatment on Alloyed Steels’ Surface Layer

et al. 2022

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New Complex Treatment to Ensure the Operational Properties of the Surface Layers of Machine Parts

Kostyk

Chen

Kostyk

et al. 2022

Lecture Notes in Mechanical Engineering

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Thermomechanical Treatment of Stainless Steel Piston Rings

Volokitin¹

2022

Prog. Phys. Met.

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therMoMechanical treatMent of stainless steel Piston ringswe study the influence of thermomechanical processing, namely, severe plastic de formation by highpressure torsion and cryogenic cooling, on the change of the microstructure and mechanical properties of the piston rings made of AISI316 stain less steel. The deformation of the annular workpieces is carried out in a tool of a new design, the key feature of which is a double helix system. In the first part of the experiment, an estimation simulation of the highpressure torsion process is carried out in a new matrix design. To estimate the process possibility, the main techno logical parameters of the process are varied in order to determine the most optimal conditions. Parameters such as the workpiece heating temperature, the upper striker vertical speed, and the friction coefficient at the contact of the workpiece with the tool are selected. The stress-strain state of the annular workpiece during defor mation is also studied. At the second stage of the study, a laboratory experiment on the annular blanks deformation is performed. The microstructure evolution and mechanical properties of deformed workpieces after 8 cycles of deformation by high pressure torsion at cryogenic temperature are studied. All the metallographic studies are carried out using the modern methods such as transmission electron microscopy and analysis of diffraction patterns of backreflected electrons. As a deformation result, a nanocrystalline structure with a size of 30-40 microns with a large number of largeangle boundaries and a high complex of mechanical properties is obtained. The tensile strength rises from 595 MPa to 1965 MPa, while the yield strength rises from 320 to 1280 MPa. The plasticity value decreases from 55% to 24% as compared to the initial state, but it remains at a sufficient level to be applied.

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Strengthening the Surface Layer of Tools with State-of-the-Art Technologies

Cited by 5 publications

References 60 publications

Impact of Magnetic-Pulse and Chemical-Thermal Treatment on Alloyed Steels’ Surface Layer

Impact of Magnetic-Pulse and Chemical-Thermal Treatment on Alloyed Steels’ Surface Layer

New Complex Treatment to Ensure the Operational Properties of the Surface Layers of Machine Parts

Thermomechanical Treatment of Stainless Steel Piston Rings

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