RU2092611C1 - Method of treating cutting tools for organic materials and ceramics - Google Patents

Abstract

FIELD: metallurgy. SUBSTANCE: invention focuses on strengthening system thermal treatment and depositing ceramic materials onto cutting tool that may be of use in production of refractory material products, as well as in instrumentation engineering when treating laminated plastics, in radioelectronics, and in mechanical engineering. According to invention, on cutting surfaces of tool made of hard alloys and titanium alloys, titanium carbonitride layer is applied using vacuum treatment at 840-950 C for 1-2 h in carbon-enriched atmosphere with subsequent deposition of 100-400-mcm ceramic alumina layer onto primarily applied underlayer followed by fusion by means of electron beam or protected laser. Offered technology is feasible in small-scale production enterprises and makes it possible to 2-3 times increase wear-resistant of tool when working with fiber-glass plastics and hot-pressed ceramics. EFFECT: increased wear resistance of cutting tools. 10 cl, 1 dwg

Description

 The invention relates to the field of metallurgy, in particular to complex hardening of a cutting tool by chemical-thermal treatment and spraying with plasma and gas-thermal method of wear-resistant coatings on cutting inserts, inserts and soldered cutters.

 A known method of spraying carbide cutting tools with several intermetallic compounds and aluminum oxide of various modifications (US patent N 1 408536, 01/16/91 analogue).

 The method has limited use, time-consuming, does not exclude peeling in relation to tools of small sections, great brittleness, insufficient wear resistance of the cutting edges.

Another well-known method for applying multilayer coatings to carbide tools (Russian Patent N 2.010.882 analogue) through a sub-layer of titanium carbide deposited by plasma spraying on which two modifications Al ₂ O ₃ is sprayed has similar disadvantages and does not provide sufficient wear resistance for a brazed tool even with cutting non-metallic materials. Similar disadvantages of the two methods described above inherent in the technology of hardening tools by spraying aluminum oxide are inherent in the method according to (EPP N 0408 535 from 01/19/90).

 Closest to the claimed is a method of processing a tool for processing organic materials, comprising the formation of a solid sublayer and subsequent spraying of ceramics with heat treatment and the formation of intermediate layers (ЕВП N 0 430 872.-05.06.91 prototype).

 The disadvantages of the method are non-universality, unstable hardness, porosity of the layers, low adhesion to the base metal of the first sublayer, as a consequence of the above, low wear resistance when cutting laminated plastics and ceramics.

 The purpose of the invention is the increase of wear resistance and strength while improving manufacturability and reducing the complexity of processing.

 To achieve this goal, it is planned to create a sublayer on the cutting surfaces of the tool, which is coherently bonded to the base metal, by conducting vacuum chemical-thermal treatment, and then spraying a layer of aluminum oxide with subsequent zone heat treatment by highly concentrated energy sources.

 The essence of the processes that make it possible to increase the physicomechanical characteristics of a multilayer coating is that during diffusion carbonitriding, the sublayer is saturated with carbon and nitrogen, and excess carbonitrides increase its hardness. At the same time, it is firmly bound to the base, does not peel off, as in the known methods, is a high-strength substrate for the ceramic layer.

The deposited Al ₂ O ₃ ceramics has high hardness, but is porous and heterogeneous, only by subsequent zone fusion with an electron beam or laser with inert gas protection it is possible to form alund modifications, comparable in strength and microhardness to diamond. As a result, the cutting faces acquire very high hardness with the best bond strength between the ceramic layer and the base, which significantly increases the operational properties of the tool when cutting fiberglass, organic materials and thin-walled ceramic products.

 The method was practically implemented in the manufacture of cutting elements and inserts for equipping cutters, in the manufacture of soldered boring cutters with a cutting part from VT-23, VT-14 titanium alloys, as well as from VK-60M and TKN-20 hard alloys.

The drawing shows the cutters passing after processing according to the proposed method after deposition of Al ₂ O ₃ and after ELU fusion of the ceramic layer.

 Example 1. Cutters suitable for processing ceramic billets of hot-pressed BHP containing boron nitride and silicon dioxide in equal amounts were processed according to the developed technology.

In the beginning, VT-23 titanium alloy plates were soldered to holders made of 4X5MFS steel and, after sharpening to the specified geometry, vacuum carbonitriding was carried out at a temperature of 880 ^° C for 2 hours in a pyrolysis atmosphere of monoethanolamine under a vacuum of 120 mm Hg.

 Then, after cooling and sandblasting, a ceramic layer of aluminum oxide with a thickness of 200 μm was sprayed on a UPN installation through a sublayer of titanium-aluminum intermetallic 10 μm. Reflowing along the front cutting edge was carried out on an ELU-5 electron-beam welding unit with heating over the entire thickness of the layer.

During the reflow process, the initial ceramic layer, consisting of modifications γ Al ₂ O ₃ and a Al ₂ O ₃ containing 98% weight of corundum, the surface microhardness increased to H _0.49 1830-1840, the surface cleanliness class increased to P _a 1, 15 microns, porosity is practically excluded, high homogeneity of corundum is achieved.

 The bond strength with the base increased, at the same time, the body strength reached 1450 1490 MPa, the tool had a wear resistance 2 times higher than that of silicon nitride standardized with a ceramic cutting part.

 Example 2. Carbide drills from VK-60M alloy with a diameter of 1.2 mm for drilling holes in boards made of fiberglass STEF were processed according to the proposed method.

Vacuum diffusion treatment was carried out at a temperature of 960 ^o C for 1 h in a bed of graphite flake and Trilon-B 0.5% weight. Then, aluminum oxide-white oxide was sprayed with white plasma spraying a layer of 400 μm, subsequent melting was carried out on a Kvant-16 laser unit with argon injection, the width of the fused edging was 0.3 0.4 mm with a spot overlap of 50%
The treatment made it possible to create a wear-resistant layer on the cutting edges that is firmly bonded to the base metal, the microhardness reached H _0.49 1850, the purity class was no worse than P _and 0.80 μm, and the super-diamond wheel was refined twice.

 When reducing the complexity of hardening processing in comparison with the known method by 1.2 times, the number of machined holes increased to 2730 in comparison with 1420 in the known processing method, cutting edges are excluded.

Example 3. Cutting inserts of prefabricated boring tools of borosil ceramic thin-walled insulators made of TKN-20 tungsten-free carbide were vacuum carburized in an atmosphere of pyrolysis of aniline and triethanolamine at a temperature of 840 ^° C for 1.5 hours, and then sprayed through an interlayer of intermetallic titanium-nickel with a thickness of 5 μm aluminum oxide Al ₂ O _{3 a} layer thickness of 100 μm. Next, vacuum melting was carried out along the contour of the cutting edge with a width of 1.2 mm of the deposited alumina, heating was carried out in a vacuum of 10 ^-4 mm Hg. with a beam power of 5 kW, specific power of 10 ⁷ W / cm ² and a pulse duration of 10 ^-6 s.

 As a result of processing, a homogeneous composition of electrocorundum was obtained on the cutting edge with high microhardness and bond strength 250 380 MPa. In comparison with analogs, the complexity of processing was reduced by 40–50%; the unit costs of preparation, electricity, and processing were reduced by 1.3 times.

The class of surface cleanliness of the cutting faces was no worse than P _a 1.2 microns, and the purity of the processed ceramic thin-walled chamber-insulators of stationary plasma engines increased to 3.5-4 microns. The wear resistance of the tool was 840-910 min or twice as high as when processing by a known method.

Claims (9)

1. A method of processing a cutting tool for processing organic materials and ceramics, comprising forming an alumina layer on the cutting edges of the tool by plasma spraying and then forming a wear-resistant layer, characterized in that prior to forming the alumina layer, a carbonitride layer is formed by chemical-thermal treatment in vacuum at 840 950 ^o C for 1 2 hours, the alumina layer is formed with a thickness of 100 400 microns, and a wear-resistant layer is formed by vacuum fusion of cutting gr any high-energy source of energy.  2. The method according to claim 1, characterized in that a beam, a laser or an ion beam are used as a high-energy source of energy.  3. The method according to claim 1, characterized in that the carbonitride layer is formed on a cutting part made of hard tungsten and titanium cobalt alloys.  4. The method according to claim 1, characterized in that the carbonitride layer is formed on a cutting part made of tungsten-free titanium-containing hard alloys.  5. The method according to claim 1, characterized in that the carbonitride layer is formed on a cutting part made of quenched titanium alloys.  6. The method according to claim 1, characterized in that the carbonitride layer is formed in an atmosphere of ethanolamine pyrolysis.  7. The method according to claim 1, characterized in that. that the carbonitride layer is formed in a bed containing graphite and trilon B. 8. The method according to claim 1. characterized in that the Al ₂ O ₃ sputtering is conducted through a sublayer of intermetallic compounds titanium nickel or titanium aluminum with a thickness of 5 10 μm. 9. The method according to claim 1, characterized in that the vacuum melting is carried out along the contour of the cutting edge continuously in a sequential manner to a width of 0.2 - 2.0 mm
10. The method according to claim 2, characterized in that the laser treatment is carried out with the supply of inert gas.