RU2283897C1 - Method of hardening surfaces of parts at simultaneous application of composite coats - Google Patents

Abstract

FIELD: metallurgy; methods of application of coats; hardening surfaces of friction pairs by application of anti-friction coats.

SUBSTANCE: proposed method includes application of copper-containing layer by chemical sedimentation under pressure with the aid of deforming tools. Then layer containing polytetrafluoroethelene is applied and is packed by deforming tools. Copper-and-tin layer is applied as copper-containing layer under pressure of 55-60 Mpa, temperature of 85-90°C and holding time of 40-45 min. Layer containing polytetrafluoroehtylene is applied in form of paste of polytetrafluoroethylene with molybdenum disulfide and is packed at force of 350-400 N. Then heat treatment is performed at temperature of 370-380°C at holding time of 45-50 min and final rolling is performed at force of 400-450 N. Multi-layer composite coat is applied on internal and external surfaces of parts.

EFFECT: facilitated procedure of application of coats, improved quality of coats due to enhanced adhesion of coat with base; reduced thickness of layer.

2 cl, 2 dwg, 4 tbl

Description

The invention relates to metallurgy, and more specifically to methods of coating metal with metal surfaces, and can be used in mechanical engineering for hardening the surfaces of friction pairs with anti-friction coatings.

There is a method of hardening treatment, where a fast-rotating metal brush is used as a tool, and fluorinated graphite is included in the coating (liquid) [Patent No. 2138579, 24 V 39/00, bull. No. 27 dated 09/27/99].

The disadvantage of this method is the use of a metal brush, the latter is advisable to use only for processing internal surfaces, and the presence of fluorinated graphite in the composition complicates the technology for preparing the liquid and requires the processing of fluorinated graphite powder and the additional operation of dispersing the finished composition.

A known method of manufacturing a plain bearing with an antifriction coating. Here, the composition of the coating applied to the substrate includes fluoroplastic with molybdenum disulfide, applied by stretching the caliber and heat treatment [Europatent 1264997 with priority 06.06.02 according to the application WO 02/099297 A2].

The disadvantage of this method is the complexity of the coating technology due to the use of electroplating when forming the substrate, and the use of the caliber does not allow the use of universal equipment and technological equipment, in addition, risks from the caliber are formed on the processing surfaces, and the electroplating softens the surface layer of the base metal.

Closest to the proposed method, the technical solution is a method of hardening surfaces with simultaneous application of composite coatings, consisting of two transitions. A copper-containing coating is preliminarily applied, and then polytetrafluoroethylene (fluoroplastic), while the tool (wire brush) is given additional movement in the longitudinal and perpendicular directions [Patent No. 2235150, IPC С 23 С 26/00, bull. No. 24 dated 08/27/04].

The disadvantage of this method is the difficulty of implementing the processing method, and only internal surfaces.

In addition, reliable adhesion of the fluoroplastic to the base is possible only with special heat treatment, and the substrate must have porosity to create a diffusion layer when the fluoroplastic adheres to the substrate.

This technical solution is selected by the author as a prototype.

The technical result is to simplify the technology of applying a multilayer composite coating, improving the quality of the coating by improving the adhesion of the coating to the base, reducing the thickness of the applied layer.

The technical result is achieved by the fact that in the method of hardening the surfaces of parts with the simultaneous application of composite coatings, including applying a copper-containing layer by chemical deposition under pressure by a deforming tool, applying a layer containing polytetrafluoroethylene, and sealing it with a deforming tool, a copper-tin layer is applied as a copper-containing layer pressure of 55 ... 60 MPa, then a layer of porous bronze is applied and sintered at a temperature of 85-90 ° C and holding for 40 ... 45 min, a layer containing polytetrafluoroethylene, applied in the form of a paste of polytetrafluoroethylene with molybdenum disulfide and compacted at a force of 350 ... 400 N, then heat treatment is carried out at a temperature of 370 ... 380 ° C with a holding time of 40 ... 45 min and a final run-in is carried out with a force of 400. ..450 N. In addition, a composite multilayer coating is applied to the inner and outer surfaces of the parts.

The implementation of the method.

The technological process of the proposed method consists of the following technological steps (transitions).

At the first stage (transition) after preparatory hardening treatment, a thin copper-tin layer is applied by chemical reduction to 2 μm, the application time is 30 ... 35 s, the pressure in the treatment zone is 55 ... 60 MPa. A preliminary diffusion layer is formed on the surface, and then a copper-tin layer, which is well visually observed.

At the second stage (transition), a layer of porous bronze is applied by sintering (for example, BrAZhMts - 8.5-4-5-1.5 according to GOST 18175-72 fractions 100 ... 160 μm) in a reducing atmosphere, such as dissociated ammonia at at a temperature of 85-90 ° C with an exposure of 40 ... 45 min. The process is carried out using the device shown in figure 1 (for processing external surfaces). The metal housing of the bearing 1 with a copper-tin coating 2 is mounted on the mandrel 3 in the housing 4. The space 5 is filled with bronze powder, closed with a washer 5 and fixed with fasteners 6. The device is placed in a furnace for heat treatment (sintering). The thickness of the bronze coating is 25 ... 30 microns.

At the third stage (transition), the process of applying a fluoroplastic coating (filling the pores of bronze) is carried out. The part with a bronze coating 1 is mounted on the mandrel 2, between the washers 3 and 3 'and is fixed by the fastening elements 4. The mandrel is installed and secured in a chuck, for example, a lathe. A deforming tool (roller) 5, which is installed in the cutting tool holder of the machine (not shown), is brought to the surface to be treated. A polytetrafluoroethylene paste with molybdenum disulfide is applied to the surface to be treated. A transverse movement of the machine support creates a static force of 350 ... 400 N. The process of layer-by-layer compaction of the coating occurs, after applying and compaction of the paste (filling the pores of the bronze coating), heat treatment is carried out at a temperature of 370 ... 380 ° С with a holding time of 45 ... 50 min . Heat treatment provides the formation of a diffusion layer, the latter and provides reliable adhesion (introduction) of fluoroplastic with porous bronze. At the last stage (transition) after the formation of the fluorine-containing coating, an additional run-in is carried out by the same roller with a force of 500 ... 600 N for additional sealing of the coating and calibration of the coated surface. The processing scheme is presented in figure 2. The thickness of the final coating layer is 5 ... 8 microns. Technological parameters of the processing process are optimized.

The proposed method allows you to harden the surface layer of the base metal and apply a combined multilayer coating on the inner and outer surfaces of the parts.

A positive technical result is confirmed by the results of laboratory and bench tests (see table 1, 2).

Table 1
The composition of the copper-tin coating Coating composition Prototype The proposed composition, in% Copper chloride Electroplated copper plating and manual tinning 8 ... 10 Tin Dichloride 4 ... 4,5 Stearic acid 0.2 ... 0.25 Acetic acid 10 ... 11 Sodium pyrophosphoric 2.8 ... 3.0 Glycerin (dynamite) rest table 2
The composition of the paste for applying polytetrafluoroethylene (suspension fluoroplast-4DV) Coating Composition (Paste) Prototype,% The proposed composition, in% Polytetrafluoroethylene (4DV fluoroplast), fraction 90 ... 100 microns 2 ... 3 rest Distilled water 10% 10 ... 12% Filler - 3 ... 5% Molybdenum disulfide - 10 ... 15% Ethanol rest 10 ... 12%

Adding molybdenum disulfide to the composition significantly improves the antifriction characteristics of the coating, filler, water, ethyl alcohol and make it possible to prepare the proposed composition in the form of a suspension to facilitate the process of applying a multilayer composite coating.

Table 3
The results of tribological laboratory tests on a friction machine MI-1 Type of composite coating Coefficient of friction Weighted wear of samples, g * 10 ^-4 Weight wear pads, g * 10 ^-4 Prototype 0.0160 ... 0.0081 ... 0.0095 138 ... 140 2.5 ... 3.0 Coverage offered 0.0058 ... 0.0061 128 ... 130 2.0 ... 2.1

The results of laboratory and bench tests showed that the application of the proposed coating method can reduce the complexity of the process compared to the prototype by 10 ... 15%, increase the wear resistance and reliability of heavily loaded contacting friction surfaces in the conditions of boundary lubrication and temporary lack of lubrication, expand the range of types sizes of parts with multilayer composite coatings, to ensure the processing of external and internal surfaces. The main effect is obtained due to the shielding effect of the coating and a significant reduction in the coefficient of friction during the operation of products.

A decrease in the coefficient of friction (improvement of the antifriction characteristics of the working surfaces of the bearing) is established. Laboratory studies were carried out on an MI-1 friction machine. The tests were carried out according to the block-sample scheme, the research results are presented in table 3 at a static load of 2000 N (Ore = 660 MPa). Bench tests were conducted to test plain bearings under the following conditions:

- number of revolutions - 10 * 10 ⁴ / min;

- load - 10 * 10 ⁴ N;

- working time - 100 hours

The results of bench tests of the plain bearing are summarized in table 4.

Table 4
The results of bench tests of bearings at the installation Type of composite coating Deterioration of a working surface of the bearing mm, * 10 ^-3 Working hours Prototype 0.25 ... 0.20 one hundred Coverage offered 0.12 ... 0.009 one hundred

The proposed method allows you to harden the surface layer of the base metal and apply a combined multilayer coating on the inner and outer surfaces of the parts.

Claims (2)

1. A method of hardening the surfaces of parts with the simultaneous application of composite coatings, comprising applying a copper-containing layer by chemical deposition under pressure with a deforming tool, applying a layer containing polytetrafluoroethylene, and sealing it with a deforming tool, characterized in that a copper-tin layer is applied as a copper-containing layer under pressure 55-60 MPa, then a layer of porous bronze is applied and its sintering is carried out at a temperature of 85-90 ° C and holding for 40-45 min, a layer containing polytetrafluoroethylene, nan they are inoculated in the form of a paste of polytetrafluoroethylene with molybdenum disulfide and compacted at a force of 350-400 N, then heat treatment is carried out at a temperature of 370-380 ° C with a holding time of 45-50 minutes and the final run-in is carried out with a force of 400-450 N. 2. The method according to claim 1, characterized in that the composite multilayer coating is applied to the inner and outer surfaces of the parts.

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