RU61289U1 - MULTI-LAYER-CUTTING TOOL - Google Patents

Abstract

The utility model relates to the field of coating, in particular to coating by evaporation and condensation in a vacuum, and is intended to obtain wear-resistant coatings on a cutting tool in tool production. The technical result is an increase in the resistance of the cutting tool. A multilayer coated cutting tool is proposed, comprising a tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that a compound of titanium, niobium, aluminum and iron is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, iron and aluminum. Instead of iron, you can use chromium, molybdenum, zirconium, silicon.

Description

The utility model relates to the field of coating, in particular to coating by evaporation and condensation in a vacuum, and can be used in tool production to obtain wear-resistant coatings on a cutting tool (RI).

Known cutting tool with a three-layer wear-resistant ion-plasma coating deposited by GT VNIITS and consisting of an upper layer of titanium nitride TiN, an intermediate layer of titanium carbonitride TiCN and a lower layer of titanium carbide TiC (see Vereshchak A.S. M.: Engineering, 1993.S. 252).

The reasons that impede the achievement of the technical result indicated below when using the known coated cutting tool include the fact that in the known coated cutting tool, the applied coating has a relatively low hardness and level of compressive stresses and insufficient adhesion to the tool base. As a result of this, the coating undergoes more wear and tear, cracks quickly nucleate and propagate in it, leading to the destruction of the coating, which reduces the resistance of RI with the coating.

The closest cutting tool with a coating of the same purpose to the claimed utility model in terms of features is a cutting tool with a multilayer coating consisting of a lower layer of a compound of titanium, metal and aluminum, an intermediate layer of titanium nitride or carbonitride and metal, and an upper layer of titanium nitride or carbonitride, metal and

aluminum. The metal used is iron, chromium, molybdenum, zirconium or silicon (Utility Model Patent No. 46006 IPC 7 C 23 C 4/32. Cutting tool with a multilayer coating).

The reasons that impede the achievement of the technical result indicated below when using the known coated cutting tool adopted as a prototype include the fact that in the well-known RI coated, the multilayer coating contains layers with high thermal conductivity, which leads to more heating of the tool base, as a result of which creep processes are activated, leading to loss of form stability of the cutting wedge, its deformation and destruction of the wear-resistant coating due to the appearance and rapid development tiya cracks.

The technical result is an increase in the resistance of the cutting tool.

The specified technical result in the implementation of the utility model is achieved by the fact that in the known cutting cutting tool, the compound of titanium, niobium, aluminum and iron, the intermediate layer is niobium nitride and the outer layer is titanium, iron and aluminum nitride or carbonitride are used as the lower coating layer.

The specified technical result in the implementation of the utility model is also achieved by the fact that instead of iron, chromium, molybdenum, zirconium, silicon are used.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model, allowed to establish that the applicant did not find a source characterized by features identical to all the essential features of the claimed utility model,

defined from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, it was possible to establish a set of significant distinctive features in relation to the applicant's perceived technical result in the claimed cutting tool with a wear-resistant coating set forth in the claims.

Therefore, the claimed utility model meets the condition of "novelty."

Information confirming the possibility of implementing a utility model with obtaining the above technical result.

The essence of the utility model is as follows. In the proposed cutting tool 1, a multilayer coating is applied to its surface, consisting of a lower layer 2 containing a compound of titanium, niobium, aluminum and iron; an intermediate layer 3 containing niobium nitride; top layer 4 containing titanium nitride or carbonitride, iron and aluminum. Instead of iron, the proposed cutting tool also uses chromium, molybdenum, zirconium, and silicon.

The use of niobium nitride having a low thermal conductivity as an intermediate layer can improve the thermal state of the cutting tool by lowering the temperature in the cutting wedge.

The coatings were applied by the CIB method (condensation from the plasma phase in vacuum with ion bombardment). Non-grind plates preliminarily cleaned of contaminants made of MK8 hard alloy were placed in the chamber of the Bulat-6T installation with electric arc evaporators installed in it, the cathode materials of which include coating elements. After applying the lower coating layer was carried out

the reaction gas is nitrogen; and the intermediate layer is precipitated. Then, when a reaction gas of nitrogen (or a mixture of nitrogen and acetylene) was supplied, an upper coating layer was applied. Then, the evaporators, the supply of reaction gas, the voltage and rotation of the device were turned off. After 15-20 minutes, the chamber was opened and the coated tool was removed.

The value of the lowering of the cutting edge at the apex was measured when studying the profilograms of the contact pads on the front surface of the plates in the main secant plane on the K-202 model profilograph-profilometer.

The average temperature on the front surface of the plates under the coating was calculated according to the method of A. N. Reznikov (Reznikov A. N. Thermophysics of the processes of mechanical processing of materials / A. N. Reznikov. - M .: Mashinostroenie, 1981. - 279 p.), With experimental determination of the necessary contact characteristics on the front surface of non-turning coated plates (cutting forces, contact length of the chip with the front surface, chip shortening factor).

Durable tests of the cutting tool were carried out with the longitudinal turning of blanks made of 30KhGSA steel on a 16K20 lathe. Cutting modes: cutting speed V = 180 m / min, feed S = 0.15 mm / rev, cutting depth t = 0.5 mm, processing was performed without the use of coolant. For the wear criterion, the value of the chamfer of wear on the rear surface was taken: h ₃ = 0.4 mm.

Table 1 shows the test results of RI with the obtained coatings. As can be seen from the table. 1 data, the resistance of the cutting tool with the developed multilayer coatings is increased 1.4-1.6 times compared with the tool with the coating prototype.

Thus, the above information indicates

when using the claimed cutting tool with a wear-resistant coating, the following combination of conditions:

Table 1
Coated RI Test Results No pp Coating material The thickness of the coating layers, microns The average temperature under the coating on the front surface of the plate, ° C The value of the lowering of the cutting edge at the top of the insert, microns, after operating time Resistance, min Note bottom layer Intermediate layer Upper layer 10 min 30 minutes one 2 3 four 5 6 7 8 9 10 one TiC-TiCN-TiN 2 2 2 930 4.4 7.4 131 Analogue 2 TiSiAl-TiSiN-TiSiAlN 2 2 2 937 4.0 6.8 322 Prototype 3 TiSiAl-TiSiCN-TiSiAlCN 2 2 2 968 4.2 7.0 349 four TiSiNbAl-NbN-TiSiAlN one four 2 884 3.6 6.3 513 5 TiSiNbAl-NbN-TiSiAlCN one four 2 909 3.8 6.4 517 6 TiFeAl-TiFeN-TiFeAlN 2 2 2 966 4.4 7.2 282 Prototype 7 TiFeAl-TiFeCN-TiFeAlCN 2 2 2 993 4.4 7.3 307 8 TiFeNbAl-NbN-TiFeAlN one four 2 905 3.9 6.6 416 9 TiFeNbAl-NbN-TiFeAlCN one four 2 929 4.0 6.8 457

Continuation of table 1 one 2 3 four 5 6 7 8 9 10 10 TiCrAl-TiCrN-TiCrAlN 2 2 2 962 4.3 7.2 288 Prototype 111 TiCrAl-TiCrCN-TiCrAlCN 2 2 2 989 4.4 7.3 318 12 TiCrNbAl-NbN-TiCrAlN one four 2 904 3.8 6.6 403 13 TiCrNbAl-NbN-TiCrAlCN one four 2 922 3.9 6.7 449 fourteen TiMoAl-TiMoN-TiMoAlN 2 2 2 958 4.3 7.1 286 Prototype fifteen TiMoAl-TiMoCN-TiMoAlCN 2 2 2 983 4.3 7.2 312 16 TiMoNbAl-NbN-TiMoAlN one four 2 902 3,7 6.4 412 17 TiMoNbAl-NbN-TiMoAlCN one four 2 919 3.8 6.5 477 eighteen TiZrAl-TiZrN-TiZrAlN 2 2 2 944 4.1 6.9 297 Prototype 19 TiZrAl-TiZrCrs-TiZrAlCN 2 2 2 978 4.2 7.1 326 twenty TiZrNbAl-NbN-TiZrAlN one four 2 987 3.6 6.3 446 21 TiZrNbAl-NbN-TiZrAlCN one four 2 913 3.8 6.4 515

the tool embodying the claimed cutting tool with a wear-resistant coating in its implementation, is intended for use in industry, namely in the field of coating, in particular in the field of coating by evaporation and condensation in a vacuum, and can be used in tool production to obtain wear-resistant coatings on cutting tool;

- for the declared cutting tool with a wear-resistant coating in the form described in the independent clause of the stated utility model formula, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed;

- a tool that embodies the claimed utility model in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

Therefore, the claimed utility model meets the condition of "industrial applicability".

Claims (5)

1. A cutting tool with a multilayer coating containing the tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that the compound of titanium, niobium, aluminum and iron is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, iron and aluminum. 2. A cutting tool with a multilayer coating containing a tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that a compound of titanium, niobium, aluminum and chromium is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, chromium and aluminum. 3. A cutting tool with a multilayer coating, containing the tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that the compound of titanium, niobium, aluminum and molybdenum is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, molybdenum and aluminum. 4. A cutting tool with a multilayer coating, containing the tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that the compound of titanium, niobium, aluminum and zirconium is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, zirconium and aluminum. 5. A cutting tool with a multilayer coating, containing the tool base and a three-layer wear-resistant ion-plasma coating deposited on it, characterized in that the compound of titanium, niobium, aluminum and silicon is used as the lower layer; as an intermediate - niobium nitride; as the outer layer, nitride or carbonitride of titanium, silicon and aluminum.