RU2595187C1 - Apparatus for applying coatings on surfaces of parts - Google Patents

Abstract

FIELD: metal processing.

SUBSTANCE: invention relates to an apparatus for applying coatings on surfaces of parts. Inside the housing of the vacuum chamber there is at least one source of sprayed material, made in the form of N magnetrons, where N is an integer number and N > 1, and an ion source. Inside the housing chamber there is a protective capsule, and in the center of the chamber there is a high-voltage source of bias voltage and low-voltage source of bias voltage. Carousel and part holder are located inside the upper part of the protective capsule. Parts are located inside the protective capsule bottom. Magnetrons and ion source are installed along the perimeter of the protective capsule. Upper part of the protective capsule is made with upper blind end and fixed on hollow shaft, which is installed in the upper part of the housing chamber and is rigidly connected to the carousel shaft in electrically insulated assembly of top part of protective capsule. Lower part of protective capsule has bottom blind end and fixed on shaft, which is installed in the lower part of the housing of the vacuum chamber and is connected with drive of reciprocal motion by coupling. Axis of rotation of the upper and lower parts of the protective capsule, shaft of top part of the protective capsule, shaft of lower part of the protective capsule, rod, electrically insulated assembly, electrically insulated fitting assembly coincide with the axis of rotation of the carousel. Outer side of the vacuum chamber housing, containing a system of gas supply, has a multi-position electric switch, configured to switch the high-voltage and low-voltage sources of bias voltage from the carousel shaft onto the shaft of the upper part of the protective capsule and shaft of the lower part of the protective capsule.

EFFECT: higher quality of coatings due to protection surface of parts from defects.

1 cl, 1 dwg

Description

The invention relates to mechanical engineering, in particular to vacuum technology, in particular to vacuum installations for applying wear-resistant, heat-resistant, antifriction coatings to expensive parts such as turbine blades, rods, shafts and metalworking tools.

A device for applying multilayer conductive coatings on products made of dielectric materials and an ion source for it (RF patent for the invention No. 2261289, IPC С23С 14/35, publ. 09/27/2005), containing a working chamber with a magnetron sputtering system (MPC), including sources of atomized material and ion sources, MPC power system, vacuum system, working gas inlet system, cassette for processed products and its movement mechanism, in which the sources of atomized material and ion sources are supplied with GOVERNMENTAL protective shields to protect them from deposition of undesirable films on the surface of other sources of sputtered material that, when enabled products can give the surface of workpieces contamination.

The disadvantage of this device is the low quality of coatings due to the fact that the protective screens are too close to the sources of the sprayed material, interfere with their operation in the closed state and cannot be used to prevent surface contamination of the products at the initial moment of switching on the sources of sprayed material due to adsorbed gases and oxide films at the cathodes and in the crucibles of these sources.

Another gateway device for loading and unloading products from vacuum is known (USSR author's certificate No. 1688609, IPC С23С 14/56, publ. 07/01/1991), containing a camera with a shutter, a product cassette placed on a table with a displacement drive, a soft-leakage leakage gas into the chamber and the discharge pipe in the form of a bypass line with a valve for smooth pumping of the camera, as well as a screen in the form of a glass placed on a table without a gap and covering the outer surface of the cartridge, designed to improve the quality of coatings by maintaining a clean You are the surface of the product when pumping the chamber and the inlet of gas into it. The screen can be made of perforated sheets, and the holes in the sheets are optically opaque, or the screen can be made of sintered granules, and the screen and the table are made with through pores.

The disadvantage of this device is the low quality of coatings due to the fact that the screen is located in a separate lock chamber, and not in the spraying zone and can only serve to protect the surface of the products when pumping the chamber to a working vacuum and gas inlet. The device does not protect the surface of the products from the introduced defectiveness associated with the release of adsorbed gases during heating at the beginning of operation of the sources of the sprayed material, as well as the defectiveness associated with impurities that fall on the sprayed parts at the initial time during spraying or evaporation of the contaminated surface layer of the source of sprayed material, as it is in the lock chamber.

Closest to the technical nature of the claimed invention is an installation for applying nanocomposite coatings on flat surfaces of a part (RF patent for utility model No. 100519, IPC С23С 14/56, publ. 12/20/2010), containing at least one source of sprayable material, an ion source, a carousel on which at least one part holder is located.

The disadvantage of this installation is the reduced quality of the coatings due to the deposition of dust suspensions resulting from the evacuation of the vacuum chamber on the sprayed surfaces of the parts, from the defects introduced into the coating composition associated with the release of adsorbed gases during heating at the beginning of the work of the source of the sprayed material, as well as the defects associated with with impurities falling at the initial time on the sprayed surfaces of the parts when cleaning the surface of the targets of the sources of the sprayed material.

The technical result consists in improving the quality of coatings by protecting the surface of parts from introduced defects in the form of dust torn from the surfaces of equipment and snap-in of the vacuum chamber at the time of evacuation of the vacuum chamber, as well as from the deposition of unwanted films during the process of setting the operating modes of the sources of the sprayed material, ion cleaning their targets and reactive spraying.

The specified technical result is achieved by the fact that the installation for coating on the surface of parts containing a vacuum chamber, inside the case of which containing a gas inlet system, is installed at least one source of atomized material made in the form of N magnetrons, where N is an integer and N≥1, an ion source, a carousel mounted rotatably on a shaft on which at least one part holder is arranged, capable of rotating the part around its own axis of the holder, parallel axis of rotation of the carousel, passing in the center of the vacuum chamber, the high-voltage bias voltage source, the low-voltage bias voltage source, is equipped with a protective capsule located inside the vacuum chamber housing made of metal in the form of overlapping upper and lower parts with the formation of technological clearance with side walls in the form of surfaces rotation, with a bar fixed on the carousel, with a multi-position electric switch located on the outside of the vacuum chamber housing, at the same time The upper part of the protective capsule is made with an upper blind end, with an electrically insulated node located on it, and a shaft made hollow, the lower part of the protective capsule is made with a lower blind end, with an electrically insulated docking unit located on it for engagement with the rod, and the shaft, while the carousel and the holder are located inside the upper part of the protective capsule, the details are located inside the lower part of the protective capsule, magnetrons and an ion source are installed around the perimeter of the protective capsule, while the shaft the upper part of the protective capsule is installed in the upper part of the vacuum chamber body and is rigidly connected to the carousel shaft in an electrically isolated unit, and the shaft of the lower part of the protective capsule is installed in the lower part of the vacuum chamber body and connected to the reciprocating drive, while the axis of rotation of the upper and the lower parts of the protective capsule, the shafts of the upper and lower parts of the protective capsule, rod, electrically isolated node, electrically isolated docking node coincide with the axis of rotation of the carousel, in at the same time, the multi-position electric switch is configured to switch the high-voltage and low-voltage bias voltage sources from the carousel shaft to the shaft of the upper part of the protective capsule and the shaft of the lower part of the protective capsule.

The invention is illustrated by the drawing, which shows a diagram of the installation for coating on the surface of the parts.

Installation for coating on the surface of parts 1 contains a vacuum chamber 2, inside the housing of which is installed at least one source of atomized material 3, made in the form of N magnetrons, where N is an integer and N≥1, ion source 4, carousel 5 mounted on the shaft 6 rotatably, on which at least one holder 7 of the part 1 is placed, arranged to rotate the part 1 around the own axis of the holder 7, parallel to the axis of rotation O of the carousel 5, passing in the center of the vacuum chamber 2, high a bias voltage source 8, a low-voltage bias voltage source 9. Inside the housing of the vacuum chamber 2 there is a protective capsule 10 made of metal in the form of an overlap with the formation of a technological gap of the upper 11 and lower 12 parts with side walls, for example, in the form of a cylinder or a truncated cone . In this case, the carousel 5 and the holder 7 are located inside the upper part 11 of the protective capsule 10, the parts 1 are located inside the lower part 12 of the protective capsule 10, the magnetrons 3 and the ion source 4 are installed around the perimeter of the protective capsule 10. The upper part 11 of the protective capsule 10 is made with the upper blind end face and mounted on a hollow shaft 13, which is installed in the upper part of the housing of the vacuum chamber 2 by electrically isolated vacuum inlets 14 and is rigidly connected to the shaft 6 of the carousel 5 in the electrically isolated node 15 of the upper part 11 of the protection capsule 10. The lower part 12 of the protective capsule 10 is made with a lower blind end and is mounted on the shaft 16, which is installed in the lower part of the housing of the vacuum chamber 2 with electrically isolated vacuum inlets 14 and connected by a coupling 17 with a reciprocating drive 18. On the carousel 5 fixed rod 19, located inside the protective capsule 10, which is engaged, for example, by a spline connection or a cam clutch with the lower part 12 of the protective capsule 10 in an electrically insulated docking unit 20. The axis of rotation of the upper 11 and The lower 12 parts of the protective capsule 10, the shaft 13 of the upper part 11 of the protective capsule 10, the shaft 16 of the lower part 12 of the protective capsule 10, the rod 19, the electrically insulated assembly 15, the electrically insulated docking assembly 20 coincide with the axis of rotation O of the carousel 5. From the outside of the housing a vacuum chamber 2 containing a gas inlet system 21, is a multi-position electric switch 22, configured to switch high-voltage 8 and low-voltage 9 sources of bias voltage from the shaft 6 of the carousel 5 to the shaft 13 of the upper part 11 the protective capsule 10 and the shaft 16 of the lower part 12 of the protective capsule 10.

Installation for coating on the surface of the parts is as follows.

When pumping the vacuum chamber 2, the upper 11 and lower 12 parts of the protective capsule 10 are closed and motionless. The carousel 5, the holder 7 and the parts 1 are located inside the protective capsule 10. Due to the limited conductivity of the technological gap between the upper 11 and lower 12 parts of the protective capsule 10, a pressure differential is created between the volume of the vacuum chamber 2 and the volume created inside the protective capsule 10. This eliminates the ingress of on the surface of parts 1 of particles detached from the surface of all devices located inside the volume of the vacuum chamber 2.

Then, the shaft 6 of the carousel 5 starts rotation, which is transmitted to the shaft 13 of the upper part 11 of the protective capsule 10. The engagement of the rod 19 with the lower part 12 of the protective capsule 10 in the electrically isolated docking unit 20 gives it the moment of rotation of the carousel 5. Thus, the upper 11 and lower 12 parts of the protective capsule 10 rotate together with the carousel 5. The high-voltage bias voltage source 8 by the multi-position electric switch 22 is connected to the shafts 13 and 16 of the upper 11 and lower 12 parts of the protective capsule 10, respectively. An electrically insulated assembly 15 keeps the carousel 5 electrically isolated. Argon working gas is supplied to the vacuum chamber 2 through the gas inlet system 21 to a pressure of 3 · 10 ^-1 Pa, and at a bias voltage of 900 ÷ 1200 V a glow discharge is ignited between the protective capsule 10 and the housing of the vacuum chamber 2. The protective capsule 10 is heated by bombardment by argon ions and transfers radiation thermal energy to the surfaces of parts 1, as a result of which their radiation is heated. If it is necessary to intensify the heating of the surfaces of parts 1, it is also possible to include magnetrons 3 (magnetron sputtering at low discharge currents) as sources of additional plasma.

Next, the lower part 12 of the protective capsule 10 by means of a drive reciprocating movement 18 of the shaft 16 is moved downward, opening parts 1, and remains electrically isolated. The high-voltage source of bias voltage 8 is switched to the rotating shaft 6 of the carousel 5. Then, argon working gas is supplied to the vacuum chamber 2 through the gas injection system 21 to a pressure of 3 · 10 ^-1 Pa, and at a bias voltage of 900 ÷ 1200 V a glow discharge between parts 1 is ignited and the body of the vacuum chamber 2, the ion source 4 is turned on. The parts 1 rotating around its own axis are cleaned by bombardment by argon ions. In this case, the carousel 5 is protected from the effects of the discharge by the floating potential of the upper part 11 of the protective capsule 10. If necessary, intensify the cleaning of the surface of parts 1 as sources of additional plasma, you can also include magnetrons 3.

Then the rotation of the shaft 6 of the carousel 5 and parts 1 stops. The high-voltage source of bias voltage 8 is disconnected from the shaft 6 of the carousel 5. The lower part 12 of the protective capsule 10 moves up and overlaps with the upper part 11 of the protective capsule 10. By applying voltage to the magnetrons 3 and bombarding their surface of targets by argon ions, the surface of magnetron targets 3 is cleaned by its sputtering. This eliminates the ingress of particles on the surface of parts 1 detached from the surface of the magnetron 3 targets.

After 5-10 minutes after cleaning the surface of the magnetron 3 targets and the stabilization of the process of their sputtering occurs, the lower part 12 of the protective capsule 10 moves down, revealing parts 1. The shaft 6 of the carousel 5 starts rotation, a low-voltage bias voltage source 9 is connected to it, and application is made coatings on the surface of parts 1.

If it is necessary to obtain compounds from oxides, nitrides, carbides and carbonitrides, a mixture of argon with the addition of reaction gases (nitrogen, carbon, oxygen, etc.) is used. After 5-10 minutes after cleaning the surface of the magnetron 3 targets using plasma emission control, the reactive spraying mode is set. The shaft 6 of the carousel 5, the overlapped upper 11 and lower 12 parts of the protective capsule 10 remain stationary. The low-voltage bias voltage source 9 is connected to the shafts 13 and 16 of the upper 11 and lower 12 parts of the protective capsule 10, the carousel 5 is electrically isolated. The argon working gas is supplied to the vacuum chamber 2 through the gas inlet system 21 to a pressure of 2 · 10 ^-1 Pa, and at a bias voltage of 50 ÷ 150 V the magnetrons 3 are turned on and put into operation mode 3. The optical signal of the radiation of the base metal of the magnetron 3 targets is normalized, and the necessary level of reduction of this signal is maintained as a result of the inlet of the reaction gas entering through the gas inlet system 21 and reacting with the sprayed material of the magnetron targets 3. After stabilization of the process, it is sprayed I have magnetron targets 3, a low-voltage source of bias voltage 9 is disconnected from the shafts 13 and 16 of the upper 11 and lower 12 parts of the protective capsule 10, the lower part 12 of the protective capsule 10 moves down, revealing parts 1. The shaft 6 of the carousel 5 starts rotation, the low-voltage is connected to it bias voltage source 9, and coating is applied to the surface of parts 1.

Using the invention allows to improve the quality of coatings due to the protection of surfaces of parts from introduced defects at the time of evacuation of the vacuum chamber, as well as from the deposition of unwanted films during the process of setting the operating modes of the sources of sprayed material, ion cleaning of their targets and reactive spraying mode.

Claims (1)

Installation for coating on the surface of parts containing a vacuum chamber, inside the housing of which is installed at least one source of atomized material, made in the form of N magnetrons, where N is an integer and N≥1, an ion source, a carousel mounted on a shaft rotatable, on which at least one part holder is arranged, capable of rotating the part about its own axis of the holder parallel to the axis of rotation of the carousel, passing in the center of the vacuum chamber, a high-voltage source infrared bias voltage, low-voltage bias voltage source and gas inlet system, characterized in that it is equipped with a protective capsule located inside the vacuum chamber body made of metal in the form of overlapping upper and lower parts with a technological gap with side walls in the form of rotation surfaces, a rod mounted on the carousel with a multi-position electric switch located on the outside of the housing of the vacuum chamber, while the upper part of the protective capsule is made with an upper blind end and with an electrically isolated assembly located on it, and a hollow shaft, and the lower part of the protective capsule is made with a lower blind end and with an electrically isolated docking assembly located on it for engagement with the rod and shaft, while the carousel and holder located inside the upper part of the protective capsule, and the lower part of the protective capsule is intended for the location of parts in it, while the magnetrons and the ion source are installed around the perimeter of the protective capsule, and the shaft is upper parts of the protective capsule is installed in the upper part of the vacuum chamber housing and is rigidly connected to the carousel shaft located in the electrically isolated unit, and the shaft of the lower part of the protective capsule is installed in the lower part of the vacuum chamber housing and is connected to the reciprocating drive, while the axis of rotation of the upper and the lower parts of the protective capsule, the shafts of the upper and lower parts of the protective capsule, rod, electrically isolated node, electrically isolated docking node coincide with the axis of rotation of the carousel whether a multi electrical switch configured to switch high and low voltage source with the bias voltage of the carousel shaft on the shaft upper portion of the protective capsule and the lower shaft portion of the protective capsule.

Images