EA008676B1 - Method for applying two-layer galvanic coating on copper sleeve and crystallizer plate - Google Patents

Abstract

The invention relates to metallurgy, in particular, to continuous steel casting installations, more particular to technology of applying coating when manufacturing crystallizer plates and sleeves.The inventive task comprises working out a protective coating providing higher wear resistance and coating strength, increase crystallizer life time and better billet quality.The technical result is aimed at producing a protective coating having better lubricity of the surface with liquid steel, high adhesion of coating with copper base, difference in coefficients of thermal expansion coatings and base, reduction of thermal deformation, increase of crystallizer plate and sleeve durability.The method for electrochemical applying of two-layer protective coating comprises the following steps: washing an article surface and two-layer electrochemical coating in bath with electrolytes. According to the invention prior to coating the article is pretreated in electrolyte comprising sodium hydroxide, then the surface is washed by detergents, pumice, solvent and a prior operation of washing with solutions of hydrochloric acid and sulfanic acid, wherein the electrochemical coating is applied in two layers: first electrochemical nickelling in sulphamate electrolyte. It needs 33.5-34.5 hours to obtain 845 mkm coating thickness and 2.5-3.0 hours for 35-40 mkm coating thickness. After that the surface is washed with a detergent, pumice, soda ash and a solvent, a second coating layer is applied by electochemical chromium-plating in standard electrolyte comprising chrome anhydrite, sulphuric acid, chromium and other admixtures.

Description

The invention relates to the field of metallurgy, in particular to continuous casting machines (CCM), and more specifically to the technology of applying a protective coating in the manufacture of plates and sleeves of crystallizers.

The essence of the invention is the application of the electrochemical method of a two-layer coating on the working surface of the plates and sleeves, using a single layer (nickel) as a softening substrate under the wear-resistant working layer (chrome).

There are various options and methods for applying protective coatings: single-layer and multilayer, applied by electrochemical method, sputtering, knurling. Certain requirements should be made to the applied coatings: high wear resistance and hardness, low lubricity with liquid steel, high adhesion of coatings with a copper base, the ability to provide adequate heat dissipation and the smallest possible difference in the coefficients of thermal expansion of the coatings and the substrate.

The known method [1] applying a protective coating having two and three layers. The intermediate layer Νί- (ί, ’ο) and the working layer (or two layers) No. (Co) P (3-20%) - Cr or Νί-Co-B (2-15%). The disadvantage of applying these coatings is the high cost of the coating process, including the high cost of the necessary reagents, increased control of the electrolyte state, additional costs for the preparation of the coating.

The lack of coatings No. (Co) P- (Cr), No. (Co) B- (Cr) in that they have low thermal conductivity, coefficient of thermal expansion and a narrow range of operating temperatures.

As a prototype adopted the method [2] of applying a protective coating. The coating is performed with a single-layer No. (Co) and a two-layer No. (Co) -B (0.05-1.5%). The durability and wear resistance of the coating obtained using this invention is not very high. Therefore, in order to increase the wear resistance twice (up to 300 heats at a speed of 1.9 m / min), the method of cone-shaped and stepped coating of various configurations was applied. The thickness of this coating is in the upper part of the crystallizer from 50 to 200 microns and in the lower part from 200 to 1000 microns.

The technological process of applying a protective coating on the copper surface of the mold includes the following operations:

washing with water, 50% hydrochloric acid solution, 3% sulfamic acid solution; electrochemical coating in the bath number (Co) -In the electrolyte of the following composition:

Nickel sulfate 250 g / dm ³

Nickel chloride 20 g / dm ³

Boric acid 30 g / dm ³

Dimethylaminboran 0.1 g / dm ³ at a temperature of 40-45 ° С, pH 4.0 and current density 1-3 A / dm ² .

The coating time depends on the thickness of the coating that is to be obtained.

The process goes with a gradual decrease in the level of electrolyte in the electroplating bath to form a taper coating.

The method of cone-shaped and step coating of various configurations is applied.

The disadvantage of the prototype is that the manufacturing process of molds is complicated, which leads to additional costs.

Moreover, the thickness of the applied coating affects the heat sink, which can lead to thermal deformation of the mold, reduced durability and the formation of surface defects when casting blanks. Therefore, it is required for the manufacture of crystallizers to use copper alloys containing silver to increase the recrystallization temperature. The cost of the coating process increases.

The problem solved by the invention is to develop a protective coating that provides high wear resistance and hardness of the coating, increasing the service life of the molds and improving the quality of cast billets.

The technical result achieved with the use of the invention is to obtain a protective coating that provides improved surface lubricity with liquid steel, high adhesion of the coating to the copper base, the difference in the thermal expansion coefficients of the coatings and the base during the operation of the molds, reduction of the thermal deformation of the molds during the operation, increase resistance plates and sleeves molds.

The solution of the problem is ensured by the fact that the method of electrochemical deposition of a two-layer protective coating includes the following operations: washing the surface of the product and a two-layer electrochemical coating in a bath with electrolytes. According to the invention, before coating, the products are pretreated in an electrolyte containing sodium hydroxide with a concentration of 170-230 g / dm ³ , at a temperature of 18-20 ° C and a current density of 3 to 10 A / dm ² , then the surface of the product is washed with detergents, pumice, solvent and preparatory washing operation with 10% hydrochloric acid solution and 4% sulfamic acid solution, and the electrochemical coating is applied in two layers: first, electrochemical nickel plating is performed in the sulfamate electrolyte of the following co Ava:

- 1 008676

370-470 g / dm ³

2-4 g / dm ³

20-30 g / dm ³ Not more than 0.1 g / dm ³

Nickel sulfamate

Nickel Bromide

Boric acid

Impurities of iron at pH 2.8-3.2, temperature 50-60 ° С and current density 0.5-2.5 A / dm ² .

To obtain a coating with a thickness of 845 μm, the process lasts for 33.5-34.5 hours. To obtain a coating with a thickness of 35-40 μm, the process lasts for 2.5-3 hours. Then the surface is washed with detergent, pumice stone, soda ash and the solvent is applied a second layer of electrochemical chrome plating in a standard electrolyte of the following composition:

230-270 g / dm ³

2.3-2.7 g / dm ³

Not more than 7 g / dm ³

Not more than 5 g / dm ³ Not more than 2.7 g / dm ³ Not more than 18 g / dm ³

370-470 g / dm ³

2-4 g / dm ³

20-30 g / dm ³ Not more than 0.1 g / dm ³

Chromic anhydride

Sulphuric acid

Chromium

Chlorides

Sulfates

Iron at a temperature of 50-60 ° C and a current density of 20-50 A / dm ² on the thickness of the coating layer from 60 to 100 microns for 5-6 hours

Due to the high wear resistance of Cr and its good friction properties, the thickness of the applied Cr layer lies in the range that provides the best ratio of wear resistance and thermal conductivity. The negative side of the application of Cr - poor adhesion to Cu - is solved with the help of intermediate layer N1, which has good thermal conductivity and has the function of wear resistance. The main requirement for coating is a uniform thickness of N1 substrate on a copper basis of crystallizers and a protective layer of Cg, which should be on the plates: a layer of nickel (N1) - 845 microns, a layer of chromium (Cr) - 60-100 microns;

on the sleeves: a layer of nickel (N1) - 35-40 microns, a layer of chromium (Cr) - 60-65 microns.

An example of a specific use.

The method was tested at the Republican Unitary Enterprise "Belarusian Metallurgical Plant" in the mechanical repair shop and tested molds with a new protective coating on CCM-1, 2, 3 in the electric steelmaking shops 1 and 2. In the implementation of the process of applying a two-layer protective coating on the copper surface the mold produced the following operations:

pretreatment in the electrolyte: sodium hydroxide 170-230 g / dm ³ at a temperature of 18-20 ° C and a current density of 10 A / dm ² .

Wash the surface with detergent, pumice and solvent. A preparatory washing operation was performed with a 10% solution of hydrochloric acid and 4% sulfamic acid.

Then, electrochemical nickel plating was carried out in the sulphamate electrolyte: Nickel sulfamate Nickel bromide Boric acid Iron impurities at pH 2.8-3.2, temperature 50-60 ° С and current density 0.5-2.5 A / dm ² .

For plates with a protective layer thickness of 845 μm, the coating time is 33.5-34.5 hours, for liners with a thickness of 35-40 μm, the coating time is 2.5-3 hours. Then the surface was washed with detergent, pumice stone, soda ash and solvent and electrochemical chromium plating was performed in a standard electrolyte:

Chromic anhydride

Sulphuric acid

Chromium

Chlorides

Sulfates

Iron at a temperature of 50-60 ° С, current density 20-50 A / dm ² .

For plates, a protective coating on a layer of 60-100 microns was applied for 5-6 hours and for mold sleeves on a layer thickness of 60-65 microns - for 5-6 hours.

The use of the process of electrochemical deposition of a two-layer protective coating allows you to:

1) during the operation of molds, to increase wear resistance, to obtain the necessary thermal conductivity, to reduce the thermal deformation of the plates and mold liners and to reduce the number of surface defects, to improve the macrostructure of the cast billet and to improve its quality,

2) to increase the resistance of the sleeves of the molds on average from 250 to 500 heats (twice) at a speed of

230-270 g / dm ³ 2.3-2.7 g / dm ³

Not more than 7 g / dm ³

Not more than 5 g / dm ³ Not more than 2.7 g / dm ³

Not more than 18 g / dm ³

- 2 008676 rosti casting up to 3.5 m / min, the resistance of the plates of crystallizers is maintained at the level of 700 heats, but at the same time exclude the use of expensive copper with the addition of silver,

3) reduce the need for liners and plates of crystallizers.

Information sources

1. DR No. 40341/1980.

2. EP 0383934 A1, 03.02.90 (prototype).

Claims (2)

CLAIM A method of applying a two-layer electroplating coating on copper products, which are shells or mold plates, comprising the following operations: washing the surface of the product and forming a two-layer electrochemical coating, characterized in that the product is pretreated in an electrolyte containing sodium hydroxide concentration of 170-230 g / dm ³ at a temperature of 18-20 ° C and a current density of from 3 to 10 A / dm ^2, then washing the surface of the product produced detergents, pumice, solvent further performed n dgotovitelnuyu washing step with 10% solution of hydrochloric acid and 4% solution of sulphamic acid and then applied in two layers electrochemical plating: initially carried out in an electrochemical nickel sulfamate electrolyte of the following composition: 370-470 g / dm ³ 2-4 g / dm ³ 20-30 g / dm ³ Not more than 0.1 g / dm ³ Nickel Sulfamate Nickel Bromide Boric acid Impurities of iron at a pH of 2.8-3.2, a temperature of 50-60 ° C and a current density of 0.5-2.5 A / dm ² , moreover, with a coating layer thickness of 845 μm, the process is carried out for 33.5-34 , 5 hours, and with a coating layer thickness of 35-40 microns from 2.5 to 3 hours, and then the surface is washed with a detergent, pumice, soda ash and solvent, and a second coating layer is applied by electrochemical chromium plating in a standard electrolyte of the following composition: