RU2699486C1 - Method for application of electroerosion-resistant coatings based on copper and silver oxide on copper electric contacts - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to coating copper electric contacts. Method includes electric explosion of composite electrically exploding conductor consisting of two-layer flat silver shell with weight of 60–360 mg and core in form of copper oxide powder with mass equal to 0.5–2.0 of shell weight, formation from explosion products of a pulsed multiphase plasma jet, its melting surface of copper electric contact at absorbed power density of 4.5–6.5 GW/m², deposition on surface of explosion products and formation on it of composite coating of CuO-Ag system and subsequent pulse-periodic electron-beam treatment of coating surface at absorbed energy density of 40–60 J/cm², pulse duration 150–200 mcs and pulse number 10–30.

EFFECT: invention is aimed at formation on copper electric contacts coatings based on copper oxide and silver, having high electrical conductivity, erosion resistance and adhesion with substrate at the level of cohesion.

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Description

The invention relates to a technology for coating metal surfaces using concentrated energy flows, in particular, to a technology for producing coatings based on copper and silver oxide on copper electrical contacts, which can be used in electrical engineering as electroerosion-resistant coatings with high electrical conductivity and adhesion with a substrate on cohesion level.

A known method (Patent RU No. 2451111, IPC С23С 14/32, published on 05/20/2012) applying electroerosion-resistant molybdenum-copper composite coatings with a filled structure to the contact surfaces, comprising using a concentrated energy flow to evaporate the starting materials of molybdenum and copper and condensing them onto contact surface, characterized in that, as starting materials, first, a copper foil weighing 4 ... 5 mg with a weighed portion of molybdenum powder weighing 0.8 ... 0.9 g is used alternately, then one copper foil weighing 175 ... 185 mg, vapor s is performed by passing the foil by electric current causing its electrical explosion, and condensation products of the explosion to the contact surface is carried out at a value of the absorbed power density on the surface of the hardenable 4.5 ... 5.0 and 7.6 ... 8.1 GW / m ^2, respectively .

The disadvantage of this method is the low stability of the structure during operation of electrical contacts with such coatings. During the operation of electrical contacts with such coatings, their surface is melted, under the influence of sparking and the appearance of an electric arc, local melting and spraying of metal occurs, as a result of which the metal product breaks its integrity, changes its size and shape. Since tungsten and copper are immiscible components in the entire temperature and concentration range, various types of defects occur during the interaction of a spark or arc when switching contacts on the coating surface. During testing, fusible copper evaporates and tungsten becomes the main coating element, which forms a matrix with copper inclusions with sizes of the order of several micrometers (Electroexplosive spraying of wear- and electroerosion-resistant coatings / D.A. Romanov, E.A. Budovskikh, V.E. Gromov , Yu. F. Ivanov. -Novokuznetsk: Publishing house of LLC Polygraphist, 2014. - 203 p.) [1]. This may cause premature failure of the electrical contacts.

Closest to the claimed one is the method (Patent RU No. 2546939, IPC С23С 4/12 publ. 04/10/2015) [2] applying electroerosion-resistant coatings based on tungsten and copper to copper electrical contacts, including an electric explosion of a composite electrically exploded conductor, consisting of a two-layer a flat copper shell weighing 60-360 mg and a core in the form of a tungsten powder with a mass equal to 0.5-2.0 mass of the shell, the formation of the products of the explosion of a pulsed multiphase plasma jet, its fusion of the surface of the copper electrically on contact with the absorbed power density of 4.5-6.5 GW / m ^2, the deposition on the surface of the explosion products, forming a composite coating thereon W-Cu system and subsequent periodic pulsed electron-beam treatment of the surface coverage of absorbed energy density at 40- 60 J / cm ² , pulse duration 150-200 μs and the number of pulses 10-30 imp.

The disadvantage of this method is the low stability of the structure during operation of electrical contacts with such coatings, as well as their low electrical conductivity. During the operation of electrical contacts with such coatings, their surface is melted, under the influence of sparking and the appearance of an electric arc, local melting and spraying of metal occurs, as a result of which the metal product breaks its integrity, changes its size and shape. Since tungsten and copper are immiscible components in the entire temperature and concentration range, various types of defects occur during the interaction of a spark or arc when switching contacts on the coating surface. During testing, fusible copper evaporates and tungsten becomes the main coating element, which forms a matrix with copper inclusions with sizes of the order of several micrometers [1]. This may cause premature failure of the electrical contacts. The low electrical conductivity of the coatings causes overheating of the electrical contacts during operation, resulting in a reduced service life.

The technical problem solved by the invention is to obtain composite coatings based on copper and silver oxide with a filled microcrystalline structure, having high structural stability, cohesion between the phases of copper oxide and silver, a high degree of homogenization of the structure of their surface layer, surface gloss and high electrical conductivity, due to the use of silver, and electrical discharge resistance.

The existing technical problem is solved in that the method includes an electric explosion of a composite electrically exploded conductor, consisting of a two-layer flat silver sheath weighing 60-360 mg and a core in the form of a copper oxide powder with a mass equal to 0.5-2.0 shell mass, the formation of products the explosion of a pulsed multiphase plasma jet, fusing it with the surface of a copper electrical contact at an absorbed power density of 4.5-6.5 GW / m ² , depositing explosion products on the surface and forming a composition on it cation of the CuO-Ag system and subsequent pulse-periodic electron-beam treatment of the coating surface at an absorbed energy density of 40-60 J / cm ² , pulse duration 150-200 μs and the number of 10-30 pulses.

The technical result obtained by using the invention is that the destruction products of the composite electrically exploded conductor form a plasma jet, which serves as a tool for forming a composite coating with a filled structure on the surface of a copper electrical contact (Matthews M., Rawlings R. Composite materials. Mechanics and technology. - M .: Technosphere, 2004. - 408 p.) [3], formed by the alloy of copper monoxide and silver. The use of silver instead of copper provides high electrical conductivity of the formed coatings. The subsequent pulse-periodic electron-beam processing (EPO) of the coating is accompanied by remelting of its surface layer with a thickness of 20-30 microns. Defects in the form of micropores and microcracks detected after electroexplosive spraying (ESP) [1] are not observed in it. Pulse-periodic EPO leads to the formation of a finely dispersed and uniform structure in the coating. The sizes of CuO inclusions in the silver matrix decrease by 2-12 times in comparison with their sizes immediately after the EHV. The surface of the coating acquires a mirror shine. The advantage of the proposed method compared to the prototype is the formation of a surface layer with low roughness, increased adhesion and electrical conductivity compared to the electric explosive coatings obtained in the method [2] and the homogenized structure, which increases their service life and expands the field of practical application of contacts in electrical equipment .

The method is illustrated in FIG. 1 by the cross-sectional structure of the surface layer of the electric explosive composite coating of the CuO-Ag system without exposure to EPO, FIG. 2 - the structure of the cross section of the surface layer of the electric explosive composite coating of the CuO-Ag system after exposure to EPO.

Scanning electron microscopy studies have shown that, when an EMI is applied on the surface of a copper electrical contact by an electric explosion of a composite electrically exploded conductor with an absorbed power density of 4.5-6.5 GW / m ² , a coating with a composite filled structure is formed when, in a silver matrix, CuO inclusions with sizes from 0.5 to 2.0 μm are located (Fig. 1). Defects in the form of micropores and microcracks are observed in the coating. The specified mode, in which the absorbed power density is 4.5-6.5 GW / m ² , is established empirically and is optimal, since at an intensity of exposure below 4.5 GW / m ² there is no relief formation between the coating and the copper electrical contact, as a result, peeling of the coating is possible, and above 6.5 GW / m ² , a developed relief of the surface of the sprayed coating is formed. When the mass value of the silver foil is less than 60 mg, it becomes impossible to make a composite electrically exploded conductor from it. With a silver foil mass value of more than 360 mg, a coating with a composite filled structure on copper electrical contacts has a large number of defects. When the core mass value of the composite electrically exploded material is less than 0.5 or more than 2.0 mass of the foil, the coating with the composite filled structure on copper electrical contacts also has a defective structure. The boundary of the electroexplosive coating with the copper substrate is not even, which allows to increase the adhesion of the coating to the substrate.

Pulse-periodic EPO of the surface of an electric explosive coating with a surface density of absorbed energy of 40-60 J / cm ² , a pulse duration of 150-200 μs, and a number of pulses of 10-30 leads to smoothing of the surface relief until a mirror shine is formed. The thickness of the modified layers after EPO varies from 20 to 40 microns and slightly increases with increasing electron beam energy density. EPO, accompanied by remelting of the coating layer, leads to the formation of a composite filled [3] structure (Fig. 2). Defects in the form of micropores and microcracks are not observed in it. The sizes of inclusions of CuO in silver range from 0.1 to 0.2 microns. Pulse-periodic EPO of the surface layer leads to the formation of a more dispersed and uniform structure in it. The specified mode is optimal, because when the surface energy density is less than 40 J / cm ² , the pulse duration is shorter than 150 μs, the number of pulses is less than 10 pulses. there is no formation of a homogeneous structure based on CuO and silver and dispersion of CuO in the coating. When the surface energy density is more than 60 J / cm ² , the pulse duration is longer than 200 μs, the number of pulses is more than 30 pulses. surface relief is formed.

The erosion resistance of coatings obtained by the claimed method, under conditions of arc erosion, was measured on the contacts of electromagnetic starters ПМА 4100. Tests for switching wear resistance in AC-4 mode according to GOST (GOST 2933-83. Testing for mechanical and switching wear resistance. Low-voltage electrical test methods . - M .: Publishing house of standards, 1983. - 26 p.) [4] was carried out at the testing complex of the Federal State Budget Educational Institution of Higher Education Siberian State Industrial University (Novokuznetsk) at a switching current of 378 A, which is 6 times higher than the nominal, and cosϕ = 0.35. The number of on-off cycles until complete destruction was ~ 10000-11000. This complies with the requirements of GOST [4] for such contacts.

Testing of coatings for electrical discharge resistance under conditions of spark erosion was carried out with point contact. The current was 3 A and the voltage was 220 V. After 10,000 on-off switches, the mass loss of the sample was measured. The coatings formed during EHV have a higher erosion resistance in the conditions of spark discharge in comparison with the initial for grade M00 copper and coatings obtained by the method [2]. The relative change in electrical discharge erosion resistance under conditions of spark erosion of coatings with a composite filled structure m _e / m is 10.90, where m _e is the mass loss of M00 grade copper, taken as the standard for 10,000 on-off cycles.

The conductivity of the coatings was measured using a conductivity meter Constant K6. The value of the electrical conductivity of the coatings of the CuO-Ag system exceeds by 21% the electrical conductivity of the coatings of the W-Ni-Cu system obtained by the patent [2].

Examples of specific implementation of the method:

Example 1

The contact surface of the copper electrical contact of the KKT 61 controller with an area of 1.5 cm ² was subjected to processing. A composite electrically exploded conductor was used, consisting of a shell and a core in the form of CuO powder, while the shell consisted of two layers of 60 mg electrically exploded flat silver foil, and the core weight was 30 mg. The formed plasma jet melted the surface of the copper electrical contact at an absorbed power density of 4.5 GW / m ² and formed a composite electroexplosive coating of the CuO-Ag system on it. After self-hardening of the coating during heat removal into the bulk of the copper contact base, a pulse-periodic EPO of the surface of the electric explosive coating was performed at a surface energy density of 40 J / cm ² , the pulse duration was 150 μs, and the number of pulses was 10 pulses.

An electroerosion-resistant coating was obtained with high adhesion of the coating to the substrate at the cohesion level. At JSC "WEST-2002" copper contacts, hardened by the claimed method, showed an increased switching wear resource of 1.7 ... 2.2 times compared to serial contacts.

Example 2

The processing was subjected to a copper electrical contact surface of the contacts of starters PVI-320A brands with an area of 0.8 cm ² . A composite electrically exploded conductor was used, consisting of a shell and a core in the form of CuO powder, while the shell consisted of two layers of 360 mg electrically exploded flat silver foil, and the core weight was 720 mg. The formed plasma jet was used to melt the copper electrical contact surface of the contacts of starters of the PVI-320A grades at an absorbed power density of 6.5 GW / m ² and formed a composite electroexplosive coating of the CuO-Ag system on it. After self-hardening of the coating during heat removal into the bulk of the copper contact substrate, a pulse-periodic EPO of an electric explosive coating was carried out at a surface energy density of 60 J / cm ² , pulse duration 200 μs, and 30 pulse counts. An electroerosion-resistant coating with a high adhesion of the coating with a base at the level of cohesion was obtained.

At JSC Remkomplekt, Novokuznetsk, copper contacts hardened by the claimed method showed a switching wear resource at a level 2.2 times higher than the contacts of starters of the PVI-320A grades.

Claims (1)

A method for applying electroerosion-resistant coatings based on copper and silver oxide to copper electrical contacts, including an electric explosion of a composite electrically exploded conductor, consisting of a two-layer flat silver sheath weighing 60-360 mg and a core in the form of a powder of copper oxide weighing 0.5-2, 0 shell mass, formation of the explosion products polyphase pulse plasma jet, its melting copper surface in electrical contact with the absorbed power density 4.5-6.5 GW / m ^2, the deposition of n surface explosion products and the formation of a composite coating thereon CuO-Ag system, and the subsequent periodic pulsed electron beam treatment coating surface when the absorbed energy density of 40-60 J / cm ^2, a pulse duration of 150-200 microseconds and 10-30.

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