RU2774682C1 - Electrochemical method of deposition of copper protective coatings from halide melts on the surface of steel 12x18h10t - Google Patents

Abstract

FIELD: electrochemical deposition.

SUBSTANCE: invention relates to the electrochemical deposition of copper coatings on the surface of stainless steel 12X18H10T using molten salts and can be used to protect structural materials from corrosion. The method includes electrolysis of a melt of the composition CuCl 6 wt.% - KCl 44 wt.% - NaCl 50 wt.%, while the electrolysis is carried out in an inert atmosphere at a temperature of 500°C and a cathode current density ≤ 0.2 A/cm².

EFFECT: simplification and safety improvement of obtaining a copper layer that protects the surface of steel 12X18H10T from corrosion.

1 cl, 1 ex, 3 dwg

Description

The invention relates to the electrochemical deposition of copper coatings on the surface of stainless steel 12X18H10T using molten salts and can be used to protect structural materials from corrosion.

Along with the advantages of using molten salts, their efficient operation is hindered by corrosion of structural materials caused by extreme temperature conditions and high concentrations of substances. Corrosion protection by traditional methods, such as the formation of a passivating oxide layer on corrosion-resistant alloys, becomes thermodynamically unfavorable in molten salts, so the use of many corrosion-resistant alloys is limited. One of the effective ways to reduce corrosion losses is to create a layer on the metal surface that protects it from the corrosive effects of the environment. The protective layer can be either metallic or inorganic material that is chemically resistant in this aggressive environment.

It seems appropriate to apply metals that are stable in such media, for example, copper, which exhibits high corrosion resistance in a fluoride melt with respect to structural materials, in particular, steel 12X18H10T. High-temperature coatings obtained from molten salts have such a valuable property as non-porosity at large thicknesses. And this is their main competitive advantage over coatings obtained by other methods. Diffusion coatings in general are the standard of adhesion of a coating to a substrate by definition, and thin intermediate diffusion layers between the base and the coating smooth out the difference in the coefficients of linear thermal expansion (CLTE) and therefore are a guarantee of the quality of the coating.

A known method of applying a copper coating on austenitic stainless steel products (12x18n10t, 12x18n9t, 1x18n9, etc.). The coating is applied by chemical-thermal treatment in baths with molten salt composition CuCl 50-70 wt.%; KCl 40-25 wt%; ZnCl ₂ 10-15 wt.% for 5-15 min at a temperature of 400-440°C in air (Kushkhov Kh.B. Functional coatings from molten salts / Kh.B. Kushkhov, N.I. Shurov, M. K. Vindizheva, Nalchik: Kab.- Balk. Univ., 2016. - 100 p.) [1].

The use of molten salts based on CuCl as a corrosive medium for deposition of copper coatings provides the following advantages. This corrosive environment, interacting with stainless steel immersed in it, corrodes its surface layer, forming a loosened surface. At the same time, there is a reaction of contact exchange of steel components with copper ions present in the melt. As a result, a copper coating is formed, while copper monochloride is very hygroscopic, and the presence of water and oxygen-containing impurities in the melt significantly reduces the quality of the resulting coating. In addition, the thickness of the protective coating obtained by this method is insufficient to provide long-term protection of the steel surface from corrosion.

A known method of manufacturing products from sheet stainless steel, according to which a copper coating is applied to a product made of steel 12X18H10T or 08X18HX10E by chemical-thermal treatment in salt melts of metal chlorides for 5-15 minutes (RU2036042, publ. 27.05.1995) [2]. In this case, copper layers are applied from a chloride melt containing monovalent copper chloride, potassium chloride and zinc chloride or sodium fluoride. These components were introduced into the melt for additional etching of oxides from the steel surface at a temperature of 400–600°C. The optimal conditions for applying a copper coating are: melt CuCl-KCl-NaF (20-78-2 wt.%, respectively) at a temperature of 500°C. To improve the adhesive properties of the coating obtained by this method, it is necessary to pre-etch the surface of the steel. The main problem solved by this method is to obtain a soft sublayer for subsequent machining of steel.

It should be noted that the salts used in this method as part of the electrolyte are extremely hygroscopic; therefore, it is extremely difficult to obtain a coating without oxygen anionic impurities, which significantly reduce the quality of the coating. In addition, chloride-fluoride melts are aggressive media, and conducting electrolysis in them leads to a decrease in the service life of materials and equipment. Working with chloride-fluoride melts in an air atmosphere is unsafe, not environmentally friendly, and the inevitable presence of water and oxygen-containing impurities reduces the quality of the resulting coating.

The objective of the present invention is to improve the quality of the copper coating on the surface of steel 12X18H10T while improving the environmental friendliness of the method.

For this, an electrochemical method for applying copper protective coatings from halide melts on the surface of steel 12X18H10T is proposed, including electrolysis of a melt of the composition CuCl 6 wt.% - KCl 44 wt.% - NaCl 50 wt.%, while the electrolysis is carried out in an inert atmosphere at a temperature of 500 ° C and cathode current density ≤ 0.2 A/cm ² .

The concentration in the salt melt of copper monochloride 6 wt.% and conducting electrolysis in an inert controlled atmosphere, in which the electrolyte has a lower content of oxygen impurities, can improve the quality of the resulting copper coatings. Conducting electrolysis at a temperature of 500°C and a cathode current density of ≤ 0.2 A/cm2 increases ^the plasticity of the coatings and reduces their porosity and makes it possible to obtain a copper layer on the surface of the protected steel with a thickness sufficient to protect the steel surface from corrosion.

The presence in the salt melt KCl 44 wt.% - NaCl 50 wt.% allow the process to be carried out at a sufficiently low temperature. The use of volatile zinc chloride is not required. The use of an inert controlled atmosphere increases the safety and improves the environmental friendliness of the method, while pre-etching of the surface to be coated is not required.

The new technical result achieved by the invention is to simplify and improve the safety of obtaining a copper layer that protects the surface of steel 12X18H10T from corrosion.

The invention is illustrated by drawings, where figure 1 shows a micrograph of the surface of the copper coating; figure 2 - micrograph of the cross-section of the substrate of steel 12X18H10T with a copper coating obtained by the claimed method; figure 3 - distribution of elements in the coating on the depth of the section.

A copper protective coating on a 12Kh18N10T steel substrate was obtained as follows. A crucible made of an electrically conductive and chemically inert material, such as graphite or a carbon composite material, was placed in an electrochemical cell with a quartz retort or a closed type electrolyzer. The electrolysis was carried out at a temperature of 500°C, anode and cathode current densities of 0.01-0.02 and ≤ 0.2 A/cm ² respectively. As a result, dense, continuous and well-adhered copper coatings with a smooth surface with a thickness of 20 μm were obtained.

Thus, outside the air atmosphere and in the absence of the use of aggressive volatile products, a high-quality copper coating with a thickness sufficient to protect the surface of 12Kh18N10T steel from corrosion was obtained.

Claims (1)

An electrochemical method for applying copper protective coatings from halide melts on the surface of steel 12X18H10T, including electrolysis of a melt of the composition СuCl 6 wt.% - KCl 44 wt.% - NaCl 50 wt.%, while the electrolysis is carried out in an inert atmosphere at a temperature of 500 ° C and a cathode current density ≤ 0.2 A/cm ² .

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