CS255357B1 - Method of titanium nitride's rub-proof layer preparation on conductive substrate - Google Patents

Abstract

The essence of the method of preparing abrasion resistant titanium nitride layer TiNx, where x is from the interval 0 to 0.95, per electrically conductive substrate in an electroplated ion-extinguishing device vaporizer where the substrate forms a cathode against a grounded vacuum chamber, is that the substrate is heated to temperature higher than 350 ° C is applied by plasma formed inert gas, most commonly argon, titanium vapor and nitrogen vapor permeated into the plasma space in which it is smooth increases nitrogen concentration and interval pressure 10 Pa 3 Pa to 1 Pa for preparation layers.

Description

(54) A method for preparing an abrasion resistance of a titanium nitride layer on an electrically conductive substrate

The principle of preparing a wear-resistant titanium nitride layer of TiNx, where x is from 0 to 0.95, on an electrically conductive substrate in an ion-plating apparatus with an electron beam evaporator, where the substrate forms a cathode against a grounded vacuum chamber, is 350 DEG C. is treated with plasma, the inert gas, usually argon, titanium vapor and nitrogen vapor to the mating area of the plasma, which is continuously increasing the concentration of nitrogen and a pressure in the range 10 ^'3 Pa and 1 Pa for the preparation of the layer.

I

The invention relates to a method of forming a hard abrasion-resistant titanium nitride layer on a solid electrically conductive substrate in plasma under vacuum conditions.

More methods and technologies are now known for forming hard wear layers. The solid substrate pressures, such as galvanic methods, chemical coating methods (CVD), PVD methods such as magnetron sputtering and ion cladding, which allow titanium nitride layers to be formed.

Disadvantages of galvanic dispersion-reinforced coatings, for example based on Ni or Cr with TiN dispersive particles, are the low mechanical properties of the matrix and the imperfect anchoring of the TIN particles in the coating matrix. A considerable disadvantage of CVD methods is the necessity of heating the substrate to temperatures of 900 to 1100 ° C, which limits their use to high speed, tool or structural steels, which then have to be subsequently heat treated, because they are annealed at such high temperatures. they are not sufficiently adhering for some applications and their surface has increased roughness. With known magnetron sputtering and cladding methods it is currently possible to form titanium nitride layers also on the above-mentioned types of substrate, also on Al and its alloys, but in some cases the adhesion of TiN coatings to the base material is not satisfactory.

The above drawbacks eliminate the method of forming a wear-resistant adhesive layer of titanium nitride on a solid electrically conductive substrate according to the invention, which is essentially based on a solid electrically conductive substrate that has a negative potential! In contrast to a grounded vacuum chamber in an ion-plating device, it is vacuum-treated with a plasma containing inert gas, most commonly Ar and Ti vapors, which enter the plasma space by evaporation of the Ti by an electron evaporation source, creating a thin layer of TiN _x . from an interval of 0 to 0.2, and to which you will not break, the plasma is treated with a nitrogen concentration of increasing concentration, which in turn creates a TiN _x layer, where x is from an interval of 0.6 to 0.95. Furthermore, it is expedient for the process according to the invention to be carried out at a pressure in a vacuum chamber which is in the range of 10 ^-4 to 1 Pa. It is also expedient according to the invention that prior to Ti evaporation, plasma is formed by an inert gas ion on a cathode substrate having a potential of 0-10 KV, causing bombardment of the substrate and dedusting of adsorbed oxide layers and any impurities which they remain on the surface after prior cleaning of the substrate in air, for example by immersion degreasing in a degreaser or improved degreasing in an ultrasonic degreaser and, as a result of the bombardment, heating the substrate to a desired temperature which depends on the substrate material.

Examples of design

The process of forming the TiN _x layer according to the invention can be described, for example, in terms of the coated substrate, taking into account the properties of the base material and adjusting the technological parameters of the layer preparation during the process. By virtue of its properties and application, the TiN _x layer is intended for application to components and tools made of duralumin, sintered carbide, high speed steels and tool steels.

Example 1

The substrate of Al or its alloy, for example CSN 42 4254.60, is inserted into the vacuum chamber of the ion-plating device, into a holder which is connected to a negative potential of 2.1 KV relative to a grounded vacuum chamber. After the vacuum chamber has been pumped to a pressure of the order of 10 ^-3 Pa, the Ar valve is started to be admitted by the needle valve, creating a glowing discharge and the ionized particles Ar bombard the substrate surface. In this way, the surface of the substrate is so-called cleaned of adsorbed gas layers and at the same time heated. The casting time is from 5 to 30 minutes, depending on the substrate area. Take care not to heat the substrate to a temperature higher than 350 ° C. In the next step, Ti is evaporated by electron beam at a pressure of 1. 10 “ ³ Pa and its output 1,8 kW. At the same time, nitrogen is admitted to the vacuum chamber and is reduced in the plasma under reduced pressure 2. ^10-1 Pa, with its concentrate continuously increasing. Such in the first phase of preparation of the TiN _x layer is a layer of TiN _x, where x is in the range 0 and 0.2, and in a second stage the preparation of layer x of the interval of 0.6 to 0.95. Since it is a coated duralumin substrate, it is expedient to not exceed 400 ° C, where structural changes occur therein so that the current density on the substrate is 0.6 inA during the formation of the Ti _x layer. cm ² and a negative voltage on the substrate of 2.1 kV. The useful thickness of the thus formed layer is from 2 to 10 µm. Example 2

In the second example of the formation of TiN _x layer according to the invention, the high-speed steel substrate CSN 19 830 is selected. The process of cleaning the surface of the substrate in the Ar discharge is identical to the conditions given in the first example. glow discharge Ar 350 ° C and ion plating 400 ° C. The substrate may be heated up to a tempering temperature of 19,830, i.e. 560 ° C, for the process. Therefore, the current density on the substrate during the formation of the TiN _x layer is more than 1 mA. cm ^-2 and negative voltage on the substrate 2.5 kV. The power of the electron beam is 2 kW.

When using the sintered carbide to be coated with a TiN _x layer according to the invention, we select the maximum current density and negative voltage on the substrate that the process equipment is capable of providing. This is because the sintered carbide substrates are not sensitive to overheating, which could cause a change in their performance.

Mainly the use of TiN _x layers is for cutting tools made of high-speed steel and sintered carbides and also for light alloys which are subject to wear. The area of application of TiN _x layers is determined by high hardness (from 10 000 to 40 000 N. Mm ^-2 ), low coefficient of friction and high wear resistance as well as corrosion resistance.

Claims (1)

SUBJECT Method for preparing a wear-resistant titanium nitride layer TiN _x , where x is from 0 to 0.95, on an electrically conductive substrate in an ion-plating apparatus with an electron beam evaporator, where the substrate forms a cathode opposite to a grounded vacuum chamber. 350 ° C is treated with an inert gas plasma, usually argon, titanium vapors and nitrogen vapors admitted to the plasma space, in which the nitrogen concentration and pressure are continuously increased from 10 ³ Pa to 1 Pa during the layer preparation.