RU2430987C1 - Procedure for production of multi-layer coating for cutting tool - Google Patents

Abstract

FIELD: metallurgy. ^ SUBSTANCE: three-layer coating is applied on working surfaces of cutting tool by vacuum-plasma-procedure. Carbonitride of titanium and iron is applied as a lower layer at pressure of acetylene in a chamber of the installation 7.510-4 Pa and temperature 600C. The same carbonitride alloyed with silicon is applied as an intermediate layer at pressure of acetylene in the chamber of the installation 7.510-4 Pa and temperature 550C and carbonitride of titanium and silicon is applied as an upper layer at pressure of acetylene in the chamber of the installation 4.310-3 Pa and temperature 500C. ^ EFFECT: increased functionality of cutting tool and quality of processing. ^ 1 tbl, 1 ex

Description

The invention relates to methods for applying wear-resistant coatings to a cutting tool and can be used in metalworking.

A known method for producing a wear-resistant coating for a cutting tool (RI), in which a titanium nitride (TiN) or titanium carbonitride (TiCN) coating is applied on its surface by a vacuum-arc method (Tabakov V.P. Performance of a cutting tool with wear-resistant coatings based on complex titanium nitrides and carbonitrides. Ulyanovsk: UlSTU, 1998.122 s). The reasons that impede the achievement of the technical result indicated below when using the known method include the fact that in the known method, coatings having good adhesion to the tool material have relatively low hardness and level of compressive stresses, or have high microhardness, but insufficient adhesion to the tool basis. As a result of this, the coating easily undergoes abrasive wear, cracks quickly nucleate and propagate in it, leading to the destruction of the coating, which reduces the resistance of the RI with the coating.

The closest method of the same purpose to the claimed invention in terms of features is a method comprising vacuum-plasma deposition of a multilayer coating consisting of a lower layer of titanium nitride and zirconium TiZrN and an upper layer of titanium nitride, zirconium and chromium TiZrCrN (patent for the invention RU 2297473 C1, C23C 14/24, C23C 14/06. - 04/20/2007. - Bull. No. 11.), adopted as a prototype.

For reasons that impede the achievement of the technical result indicated below when using the known method adopted as a prototype, the multilayer coating in the known method contains layers having low residual stresses and high thermal conductivity. As a result, the coating poorly resists cracking processes and practically does not prevent the penetration of heat into the instrument.

Recently, the increase in the cost of metal-cutting tools and the tightening of requirements for precision machined parts made the problem of increasing the resistance of radiation sources even more urgent. The main cause of RI wear is the occurrence of cracks in its cutting part, which are the cause of chips and chipping associated with fatigue failure and the creep phenomenon of the RI cutting wedge. Creep, in turn, is caused by the penetration of heat generated during cutting and friction of the chips on the surface of the tool into the instrument. One of the ways to increase the durability and performance of coated RIs is by applying multilayer coatings. The presence in the coating of layers with certain thermophysical and mechanical properties can inhibit the processes of formation and propagation of cracks without reducing microhardness, improve the thermally stressed state of RS with a coating and increase the resistance of RS.

The technical result is an increase in the health of the Republic of Ingushetia and the quality of processing.

The specified technical result in the implementation of the invention is achieved by the fact that in the known method on the working surfaces of the RI vacuum-arc method is applied to a three-layer coating. A feature of the proposed method lies in the fact that titanium carbonitride is applied as the lower layer at an acetylene pressure in the chamber of the apparatus 7.5 · 10 ^-4 Pa and a temperature of 600 ° C and as an intermediate layer at the pressure of acetylene in the chamber of the apparatus 7.5 · 10 ^-4 Pa and a temperature of 550 ° C, the same silicon-doped carbonitride is deposited, and titanium and silicon carbonitride are deposited as an upper layer at a pressure of acetylene in the apparatus chamber of 4.3 · 10 ^-3 Pa and a temperature of 500 ° C. The deposition of the lower coating layer under reduced gas pressure and elevated temperature makes it possible to obtain a higher adhesion strength of the coating to the tool base, and lowering the temperature and increasing the gas pressure during the deposition of subsequent layers can increase its microhardness and residual compressive stresses. The layout of the coating installation includes two composite cathodes with a VT1-0 titanium alloy housing and 12X18H10T silicon and stainless steel inserts and one titanium cathode. In the deposition of the lower layer, titanium and titanium-iron cathodes are used to obtain a TiFeCN layer, in the deposition of the intermediate layer, all three cathodes are used, and in the deposition of the upper layer, the cathode containing iron is turned off. The use of complex carbonitride layers with high residual compressive stresses as materials helps to increase the crack resistance of the coating; in addition, such materials have lower thermal conductivity compared to coatings of the type TiN, TiCN, TiAlN. Moreover, depending on the area of use of the tool with a coating, its total thickness can range from 5 to 8 microns, and the proportion of the lower layer can be 40-50% of the total coating thickness.

The invention consists in the following. In the process of cutting, RI works in conditions of crack formation, as well as exposure to high temperatures. To reduce the intensity of the processes of wear and destruction of the coating and the tool itself, coatings of complex composition are most effective, and in conditions of crack formation, multilayer coatings with layers of complex composition show even greater efficiency. Moreover, an increase in the number of alloying elements in the composition of the coating leads to an increase in its hardness and wear resistance, as well as crack resistance. However, this often reduces the adhesion strength of the coating to the tool base. At the same time, it is possible to increase the adhesion strength of the coating to the base by reducing the pressure of the reaction gas during its condensation and increasing the condensation temperature, however, at the same time, its other operational properties (wear resistance, etc.) are reduced. Therefore, it is advisable to use a three-layer coating, in which the upper layer should have the highest wear and crack resistance, and the lower one should first provide high adhesion to the tool base. Depending on the cutting conditions, the coating thickness varies from 5 to 8 μm (lower values with interrupted cutting). In this case, with a decrease in the coating thickness, the fraction of the lower layer increases to 50% in order to ensure the possibility of obtaining a continuous layer capable of fully performing its functions (layers with a thickness of less than 1 μm are non-functional). Coated plates obtained with deviations from the layer thicknesses indicated in the claims showed lower results.

For experimental verification of the claimed method, a prototype coating was applied with a layer ratio corresponding to the optimal value specified in the known method, as well as a three-layer coating according to the proposed method. The coatings were applied to carbide plates in the vacuum chamber of the Bulat-6 installation, equipped with three vacuum arc evaporators located horizontally in the same plane. Two cathodes made of titanium alloy VT1-0 and titanium-iron were used as cathodes of the evaporated metal when applying the lower layer (TiFeCN). When applying an intermediate layer (TiFeSiCN), these two cathodes are used plus a cathode containing a VT1-0 titanium alloy housing with a silicon insert and located between the first cathodes. When applying the upper layer, a titanium cathode and a composite cathode with a silicon insert were used. The coatings were applied after preliminary ion cleaning.

The following is a specific example of the proposed method (coating TiFeCN-TiFeSiCN-TiSiCN with a thickness of 6 μm).

MK8 carbide inserts (4.7 × 12 × 12 mm in size) are washed in an ultrasonic bath, wiped with acetone, alcohol and mounted on a rotary device in the vacuum chamber of the Bulat-6 installation equipped with three evaporators located horizontally in the same plane. The chamber is pumped out to a pressure of 6.65 · 10 ^-3 Pa, the rotary device is turned on, a negative voltage of 1.1 kV is applied to it, one evaporator is turned on, and at an arc current of 100 A, the plates are cleaned and heated to a temperature of 560-580 ° C. The focusing coil current is 0.4 A. Then the negative voltage is reduced to 150 V, the coil current to 0.35 A, two opposite evaporators (cathodes) are made of titanium and titanium-iron, reaction gas is acetylene is introduced into the chamber and the coating is deposited with a thickness 2.0 μm (TiFeCN layer) for 18 min at a gas pressure of 7.5 · 10 ^-4 Pa. The condensation temperature is 600 ° C. Then, at voltages up to 120 V, current focusing coils up to 0.25 A, the third cathode (containing silicon) is turned on. The reaction gas (pressure 7.5 · 10 ^-4 Pa) - acetylene is fed into the chamber and the second coating layer (TiFeSiCN) is deposited with a thickness of 2.0 μm for 18 minutes. The condensation temperature is 550 ° C. Then, with a voltage of up to 120 V, a current of focusing coils up to 0.25 A, the titanium-iron cathode is turned off. The reaction gas (pressure 4.3 · 10 ^-4 Pa) - acetylene is fed into the chamber and the third coating layer (TiSiCN) 2.0 μm thick is deposited for 18 minutes. The condensation temperature is 500 ° C. Then shut off the evaporators, the supply of reaction gas, voltage and rotation of the device. After 15-20 minutes, the chamber is opened and the coated tool is removed.

Durability tests were carried out on a screw-cutting machine 16K20 when machining structural steel 5XHM. Tested carbide inserts grade MK8, processed according to the known and proposed methods. The wear criterion was a chamfer of wear along the back surface with a width of 0.4 mm.

Coated RI Test Results No pp Coating material The thickness of the coating layers (lower-upper), microns H _µ , GPa K ₀ Resistance, min Note one 2 3 four 5 6 7 The processed material - 5XNM, V = 157 m / min, S = 0.25 mm / rev, t = 1 mm one TiN 6 21,2 0.70 38 Analogue 2 TiZrN - TiZrCrN 2-4 36.1 0.33 117 Prototype 3 TiFeCN - TiFeSiCN - TiSiCN 2-2-2 40.1 0.29 135 According to the formula four TiFeCN - TiFeSiCN - TiSiCN 1-4-1 37.0 0.37 120 Received with thickness deviations 5 TiFeCN - TiFeSiCN - TiSiCN 2-2-2 38.1 0.35 122 At the same pressure 6 TiFeCN - TiFeSiCN - TiSiCN 2-2-2 37.3 0.40 111 At the same temperature 1. H _µ - microhardness, GPa (according to Vickers). 2. To ₀ - the coefficient of exfoliation, a decrease in the value of which indicates an increase in the adhesion to the tool base.

As can be seen from the data in the table, the resistance of the plates processed by the proposed method is higher than the resistance of the plates processed by the prototype method by 7-12%. In this case, Example 4 illustrates that if the requirements for the appointment of layer thicknesses are violated, the resistance of the plates decreases. Example 5 shows that when coatings with layers deposited at the same gas pressure are used, the resistance is also reduced. Example 6 shows that in the case of coatings with layers deposited at the same condensation temperature, the resistance is also reduced.

Claims (1)

A method for producing a multilayer coating for a cutting tool, comprising applying a three-layer coating by a vacuum-arc method, characterized in that titanium and iron carbonitride is applied as a lower layer at an installation pressure of 7.5 · 10 ^-4 Pa and a temperature of 600 ° C, as an intermediate layer at a pressure of acetylene in the chamber of the apparatus 7.5 · 10 ^-4 Pa and a temperature of 550 ° C, the same silicon doped carbonitride is deposited, and as the upper layer at a pressure of acetylene in the chamber of the apparatus 4.3 · 10 ^-3 Pa and a temperature of 500 ° C on osyat titanium and silicon carbonitride.