CH666054A5 - METHOD FOR COATING A TOOL, ESPECIALLY A CHIPING TOOL. - Google Patents

Description

DESCRIPTION Technical field

The invention relates to a method according to the preamble of claim 1 and relates to the field of metalworking.

State of the art

According to the current state of development in the metalworking industry, the strength, wear resistance and economy of the materials used for tool manufacture are particularly high.

Perfection in the composition of such materials alone is not enough to achieve a significant improvement in the physical and mechanical parameters. Only when the processes for applying high-melting, wear-resistant coatings are perfected does a substantial improvement become possible.

From the published work “Plasma Coating” by V.l. Kostikov and J.A. Shesternjev, page 94, published in 1978 by the publishing house "Metallurgia", Moscow, discloses a method for applying a coating to a large body made of a carbon-containing material. A carbide-forming substance is evaporated in a vacuum and condensed on the heated working surface of the base body to form the coating. The evaporation of the carbide-forming substance and the heating of the work surface take place in a thermal manner.

The reaction in the carbide formation of the vaporized substance by the carbon content of the base body takes place in this known method at temperatures between 1000 and 1600 ° C, which complicates the technological process of coating formation.

In addition, in this known method the evaporated metal does not react completely with the carbon of the base body, so that the quality of the coating is unsatisfactory.

Furthermore, from the magazine "Physika i chimija obrabotki materialow" No. 2/1979, page 169, publisher "Nauba" Moscow, under the title "Coatings made of molybdenum carbide, which result from the precipitation of plasma currents in a vacuum", by A.A. Andrejev et al. a method for applying a coating to a carbon-containing base body of a particularly cutting tool by evaporating at least one carbide-forming substance by means of arc discharge in a vacuum is known. For this purpose, an electrical voltage is applied to the tool and its working surface is cleaned and heated by bombardment with ions of the evaporating carbide-forming substance. The ions are then condensed on the work surface to form the coating. In this known method, prior to condensation, a gas mixture is passed into the vacuum, which reacts with the evaporating carbide-forming substance until the coating is formed on the work surface.

The supply of the gas mixture is an additional expense in this known method and delays the formation of the coating.

In addition, the evaporation of the carbide-forming substance is unstable, so that the composition of the coating is subject to constant changes and the reproduction of the specified composition is difficult. This makes this known method even more complicated.

Since the gases intended for use are explosive, there is also a risk of explosion in the known method.

Presentation of the invention

The invention has for its object to develop a method of the type mentioned, in which the cleaning and heating of the work surface of the tool to be coated is simplified and any risk of explosion is avoided.

The object is achieved according to the invention by the features specified in the characterizing part of claim 1.

While in a preferred embodiment according to claim 2 a hard alloy rang serves as the base material, steel can also be used as the base material, the corresponding temperature for the reaction of the carbide formation being between 500 and 540 ° C.

The present invention enables the production of a coating, the composition of which is stable over its entire thickness. Furthermore, the method can be considerably simplified compared to known methods with an additional risk of explosion.

The invention is explained below on the basis of the description of specific exemplary embodiments.

Ways of Carrying Out the Invention

The method for coating a tool having a carbon-containing base body is that a carbide-forming substance is evaporated in a vacuum by means of arc discharge. To do this, an electrical voltage is applied to the tool and the tool to be coated

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Work surface cleaned by (cathode) bombardment with ions of the evaporating, carbide-forming material and heated to a temperature at which the reaction of the carbide formation of the evaporating, carbide-forming material takes place with the carbon of the base material. The ions of the evaporating, carbide-forming substance then condense on the working surface of the tool to form the coating.

A temperature between 620 and 680 ° C. is chosen for the reaction of the carbide formation in order to saturate the resulting coating with carbon as much as possible with a hard alloy as the base material.

If the temperature is lower than 620 ° C, saturation of the coating with carbon is not guaranteed. If the temperature is higher than 680 ° C, the hard alloy partially softens. In both cases, the tool life is reduced.

Titanium is suitable as an evaporating carbide-forming substance. However, if higher wear resistance is required, titanium nitride or a titanium alloy is preferred.

When using two evaporating carbide-forming substances, molybdenum can be used as the second substance.

For better understanding of the present invention, specific exemplary embodiments are given below:

example 1

The coating was applied to twist drills - hereinafter referred to as twist drills - with a diameter of 5 mm.

Titanium was used as the evaporating, carbide-forming material, and steel as the material for the drill body in the following composition:

c

Cr

W

V

Mo Fe

0.80-0.85

3.8-4.4

5.5-6.5

1.7-2.1

5.0-5.5 rest

The drills cleaned of contaminants were placed in special cassettes and placed in a vacuum chamber in which a cathode made of titanium was installed. As soon as the vacuum reached 667 • 10 ~ 5 Pa, an arc was ignited in the chamber and a voltage of 1500 V was applied to the drill. The work surface of the drills was cleaned by cathode bombardment with titanium ions while heating the drills to a temperature of 520 ° C, which was measured with an infrared pyrometer with an accuracy of ± 10 ° C. The voltage was then reduced to 250 V, and in the course of three minutes the condensation of the titanium ions on the working surface of the drill was carried out, combined with the carbide formation of the titanium by the carbon of the steel. As soon as the coating, which represents titanium car bid, had reached a thickness of 2 μm, the tension was removed from the drills and the arc was switched off. The drills in the chamber then cooled to room temperature.

The test for wear resistance was carried out when processing steel with the following composition:

C.

Fe

0.42-0.49

Rest with five control drills from each series in the following operating mode:

Cutting speed V = 32 m / min Feed size S = 0.12 mm / rev

Drilling depth 1 = 3d = 15mm

The test results are shown in Table 1, serial number of the tested drill bits 1 2 3 4 5

Number of holes drilled with a drill 205 206 206 206 207

Example 2

The coating was applied to cutting tips.

As material for the base body of the platelets

Co

TiC

WC

6

15

Rest and as an evaporating substance - titanium.

The coating was applied analogously to Example 1, but with the difference that the working surface of the platelets was cleaned by cathode bombardment with titanium ions at a working surface temperature of 620 ° C.

Testing was carried out on five control plates from each series in the following operating mode:

Cutting speed V = 160 m / min

Feed size S = 0.3 mm / rev

Depth of cut 1 = 1 mm

Table 2 shows the test results according to the number of the tested platelets 1 2 3 4 5

Number with a 26 26 25 26 27

Processed tiles

Workpieces

Example 3

Twist drills 0 5 mm were coated.

Titanium nitride would be used as the evaporating, carbide-forming substance and steel as the material for the base body, the composition of which is given in Example 1.

The working surface of the drill was cleaned by cathode bombardment with titanium nitride ions while heating the drill to 510 ° C. The voltage was then reduced to 300 V and the titanium nitride ions were condensed on the work surface of the drill over three minutes, combined with the carbide formation of the titanium nitride by the carbon of the steel. The coating, which consisted of titanium car bonitride Ti (NC), reached a thickness of 2 ßtn. Then the voltage was removed from the drills and the arc switched off. The drills cooled down to room temperature in the chamber. The drills were tested analogously to example 1. Table 3 shows the test results. '

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Serial number of the tested drill 1 2 3 4 5

Number of holes drilled with one drill 250 249 249 249 249

Example 4

Cutting plates were coated.

Titanium nitride was used as the vaporizing substance, and as the material for the base bodies of the platelets - a hard alloy, the composition of which is given in Example 2.

The coating was applied analogously to Example 3, but with the difference that the working surface of the base of the platelets was cleaned by cathode bombardment with titanium nitride ions while the platelets were heated to 635 ° C.

The platelets were tested analogously to Example 2.

Table 4 shows the results of the test.

Serial number of the tested platelets 1 2 3 4 5

Number with a 37 37 36 37 37

Processed tiles

Workpieces

Example 5

Twist drills 0 5 mm were coated. A titanium alloy of the following composition was used as the evaporating, carbide-forming substance:

AI

Mon

Ti

5.5-7.0

2.0-3.0

Rest and as material for the base body - steel, the composition of which is given in Example 1.

The coating was applied in the same way as in Example 1, but with the difference that the work surface of the drills was cleaned by cathode bombardment with titanium, aluminum and molybdenum ions while the work surface was heated to 525 ° C., the resulting coating a complex alloy mixed crystal based on titanium carbide (Ti, Mo, Al) C.

The drills were tested analogously to example 1. Table 5 shows the results of the test.

Serial number of the tested drill 1 2 3 4 5

Number of holes drilled with one bit 255 255 236 235 236

Example 6

Cutting plates were coated.

A titanium alloy, the composition of which is given in Example 5, was used as the evaporating, carbide-forming substance, and one as the material for the base body

Hard alloy, the composition of which can be found in Example 2.

The coating was applied in the same way as in Example 2, but with the difference that the working surface of the drill was cleaned by cathode bombardment with titanium, aluminum and molybdenum ions while heating to 650 ° C. at the same time.

The platelets were tested analogously to Example 2. Table 6 shows the test results according to the number of the tested platelets 1 2 3 4 5

Number of people with a 33 33 33 32 33

Processed tiles

Workpieces

Example 7

Twist drills 0 5 mm were coated.

Titanium and molybdenum were used as the evaporating, carbide-forming substance, and as material for the base body - steel, the composition of which is given in Example 1.

The drills, cleaned of impurities, were placed in special cassettes and placed in a vacuum chamber in which two cathodes made of titanium or molbydane had been installed.

As soon as a vacuum of 667 • 10-5 Pa was reached, a voltage of 1500 V was applied to the drill and an arc was ignited in the chamber. The work surface of the drills was cleaned by cathode bombardment with titanium ions while heating to a temperature of 680 ° C, which was controlled by an infrared pyrometer with an accuracy of ± 10 ° C. The voltage was then reduced to 250 V. Subsequently, the titanium and molybdenum ions were condensed by alternately connecting the titanium cathode and the molybdenum cathode over a period of three minutes. This resulted in a multi-layer coating consisting of alternating titanium carbide layers (TiC) and molybdenum carbide layers (M02C). The voltage was then removed from the drills and the arc switched off. The drills cooled down to room temperature in the chamber.

The testing was carried out analogously to Example 1. Table 7 shows the results of the testing.

Serial number of the tested drill 1 2 3 4 5

Number of holes drilled 260 261 260 260 260

Example 8

Cutting plates were coated.

Titanium and molybdenum were used as the evaporating, carbide-forming substance, and as material for the base body - a hard alloy, the composition of which can be found in Example 2.

The application of a multilayer coating was carried out analogously to Example 7, but with the difference that the surface of the platelets was cleaned by cathode bombardment with titanium and molybdenum ions while heating to 680 ° C. at the same time.

The platelets were tested as in Example 2.

Table 8 shows the results of the test.

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Serial number of the tested platelets 1 2 3 4 5

Number of people with a 40 40 41 40 40

Processed tiles

Workpieces

As the test results shown in Examples 1, 2, 3, 4, 5, 6, 7, 8 show, the simplification of the technological process when applying a coating made it possible to improve the service life characteristics of drills.

The present invention enables the coating to condense at a rate of 0.1 to 0.7 (im / min), thereby reducing the duration of a technological cycle.

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Commercial usability

The present invention can be successfully used in the manufacture of refusible, wear-resistant coatings on cutting and stamping tools made from any carbon-containing material, such as e.g. Steel, hard alloys, ceramic alloys etc.

Claims (6)

666 054 1. A method for coating a tool having a carbon-containing base body, in particular a cutting tool, by evaporating at least one carbide-forming substance by means of arc discharge in a vacuum, for which purpose an electrical voltage is applied to the tool and its working surface is cleaned by cathode bombardment with ions of the evaporating, carbide-forming substance and is heated to a temperature at which this substance interacts with the material of the base body, and then the ions are condensed on the work surface to form the coating, characterized in that the said temperature corresponds to the temperature at which the reaction of the Carbide formation of the evaporating carbide-forming substance takes place through the carbon of the main body, during the condensation of the ions of the carbide-forming substance with simultaneous carbide formation of the ions, which is a chain reaction of the transfer of carbon ff runs over the thickness of the coating. 2. The method according to claim 1, characterized in that a temperature between 620 and 680 ° C is selected for a hard alloy as the base material for the reaction of carbide formation. 2nd PATENT CLAIMS 3. The method according to claim 1, characterized in that titanium is used as the evaporating, carbide-forming substance. 4. The method according to claim 1, characterized in that titanium nitrite is used as the evaporating, carbide-forming substance. 5. The method according to claim 1, characterized in that a titanium alloy is used as the evaporating, carbide-forming substance. 6. The method according to claim 3, characterized in that in two evaporating, carbide-forming substances, molybdenum is used as the second substance.