PL241203B1 - The method of producing an interference coating - Google Patents

Abstract

The subject of the application is a method of producing an interference coating on the surface of an aluminum alloy or alloy product, including anodizing and electrochemical dyeing with the use of alternating current, which consists in the fact that the electrolyte used during electrochemical dyeing contains copper (II) sulphate in an amount from 1 to 100 g / l, boric acid in an amount from 1 to 40 g / l and tartaric acid in an amount of 0.1 g to 20 g / l.

Description

Description of the invention

The present invention relates to a method of producing an interference coating on the surface of an aluminum alloy or alloy product comprising anodizing and electrochemical dyeing with the use of an alternating current.

Due to the favorable strength to specific weight ratio and the ease of shaping, aluminum alloys have gained popularity in many manufacturing industries. Currently, aluminum alloys are widely used in the automotive, construction and food packaging industries. The conditions in which the products operate make it necessary to additionally protect the metal surface against adverse external factors. For some industries, the visual effect is a key factor in the customer's decision to purchase a given product. The growing awareness of the need for sustainable development poses new challenges for engineers working on the development of new coatings. Currently, the market requires meeting all three of the above-mentioned aspects, the coating must meet certain technical requirements, be environmentally friendly and offer unprecedented visual effects.

The protection of the aluminum surface can be achieved by the anodizing process. The process itself is well known and described in the available literature.

US 1869058 of 1931 describes an anodizing process using a low voltage of current in sulfuric acid. Over the years, there has been a lot of work presenting different approaches to the development and improvement of the technique in order to meet the latest environmental and consumer requirements.

A dyeing process without a preceding anodizing step is described in US4115212. The document discloses a process for electrochemical dyeing of items made of aluminum alloys using an alternating current in an aqueous solution containing sulfuric acid and boric acid or only sulfamic acid and metal salts. The process ends with additional protection of the surface by applying a colorless varnish. The layer, however, has no interference effect.

The document US4066816 describes an anodizing process combined with electrochemical dyeing which results in an interference coating. The document describes a two-step anodizing in sulfuric acid and in phosphoric acid, which necessitates the rinsing of the elements in order to avoid transfer of the bath between the stages. The second anodizing is to enlarge the pores in the oxide layer.

In the scientific publication Synthesis and properties of iridescent Zn-containing anodic aluminum oxide films (Thin Solid Films 586 (2015) 8-12), electrochemical deposition of zinc atoms from 80 g / L ZnSO4 7H2O and 20 g / L H3BO3 solutions was preceded by acid anodization phosphorus for at least 10 minutes. In the work Interference Coloring of Dual-Anodized Films on Aluminum Containing Electrolytically Deposited Thin Metal Layers (Plating and Surface Finishing; 84, 5; 116-119; 1997), the interference effect was obtained by depositing tin and nickel atoms in the pores of aluminum oxide.

Document WO2019011778 describes a method of producing an iridescent coating on rolled products. Anodized thin, porous aluminum oxide layer with a thickness of 15 to 25 nm is dyed with azo, anthraquinone or indigo dyes. This process is completed with a coating obtained with the sol-gel method. The layer obtained in this way is characterized by a slight iridescent effect.

The method of producing an interference coating on the surface of an article from an aluminum alloy or alloys, including anodizing and electrochemical dyeing with the use of alternating current according to the invention, is characterized in that the electrolyte used during electrochemical dyeing contains copper (II) sulphate in an amount from 1 to 100 g / l, boric acid in an amount from 1 to 40 g / l and tartaric acid in an amount of 0.1 g to 20 g / l.

The dyeing is carried out under conditions of continuous stirring of the electrolyte.

The dyeing time is over 10 s.

The dyeing is carried out at a temperature of 5-40 ° C.

Coloring is carried out with the use of alternating current with a voltage in the range of 0.5-50 V.

Anodizing takes place in a solution of sulfuric acid (VI) with a concentration of 50-500 g / l with the addition of aluminum ions in the amount of 0-100 g / l.

Anodizing is carried out at a current density of 0.1-5 A / dm ² .

The anodizing time is 10-3600 seconds.

After dyeing, the product seals itself.

PL 241 203 B1

Sealing is carried out by hot or cold hydrothermal or vapor deposition methods.

Sealing is performed by the vapor deposition method using the atomic layer deposition technique.

In order to ensure good and reproducible quality of the coatings, the surface of the aluminum product should be degreased and etched prior to the commencement of anodizing. This process can take place in baths based on organic solvents, acidic and alkaline water baths. After washing and etching the workpiece, rinse it with deionized water. After excess water has drained off, the aluminum product can be subjected to the process of producing an interference coating. The above-described method of preparing the surface of the product can be replaced by another known method. Other alternative methods are available in the art that can ensure an adequate surface quality.

After anodizing, the product should be rinsed, preferably in deionized water, and then transferred to the dyeing bath.

The unquestionable advantages of the method of obtaining the interference coating according to the invention are the appropriate selection of the electrolyte components. The use of copper (II) sulphate (VI) is much safer in relation to the previously used electrolytes, e.g. cobalt sulphate (VI) or nickel sulphate (VI), which are suspected or show carcinogenic properties. The composition of the electrolyte allows to obtain a wide range of color variants in one bath, thus facilitating the technological process, also shortening the time of creating the coating, which is an important economic aspect and is beneficial for the natural environment as it reduces energy consumption.

The method according to the invention may in particular be useful for obtaining a new graphic effect on the surface of beverage cans or their lids.

The subject of the invention is presented in the embodiment in the drawings, where Fig. 1 shows a block diagram of the interference coatings production process, and Fig. 2 - a cross-section of an aluminum product showing the structure of the coating with light interference.

P r z k ł a d 1

After degreasing and etching the surface, the aluminum product is anodized in an aqueous solution of sulfuric acid (VI) at a concentration of 150 g / l with the addition of aluminum ions at the level of 1.1 g / l at a temperature of 18 ° C, under constant current conditions with a current density of 1.1 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 200 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is performed using an alternating current of 8 V in an electrolyte containing 15 g / l of copper (II) sulphate (VI), 20 g / l of boric acid and 1 g / l of tartaric acid. Throughout the process, the electrolyte temperature is 18 ° C. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 120 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried.

The block diagram of the interference coatings manufacturing process is shown in Fig. 1, where the numbers represent:

- the process of washing and etching the aluminum element;

, 4, 6, 9 - rinsing process with deionized water;

- anodizing of the aluminum element;

- staining with alternating current (AC);

, 10 - drying the finished element;

- sealing the oxide coating on an aluminum element.

The dashed line indicates the optional sealing path for the coating of the aluminum product.

P r z k ł a d 2

Formation of an interference coating according to the guidelines described in example 1, followed by a hydrothermal heat seal. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z k ł a d 3

Preparation of the interference coating according to the guidelines described in example 1, followed by cold sealing. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

PL 241 203 B1

P r z k ł a d 4

Formation of an interference coating according to the guidelines described in Example 1, followed by sealing by means of a vapor deposition technique, e.g. by atomic layer deposition. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z o l a d 5

After degreasing and etching of the surface, the aluminum product is anodized in an aqueous solution of sulfuric acid (VI) with a concentration of 145 g / l with the addition of aluminum ions at a temperature of 11 ° C, under constant current conditions with a current density of 1.2 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 250 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is carried out using 12 V alternating current in an electrolyte containing 13 g / l of copper (II) sulphate (VI), 22 g / l of boric acid and 1.6 g / l of tartaric acid. The electrolyte temperature is 22 ° C throughout the process. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 160 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z l a d 6

After degreasing and etching the surface, the aluminum product is anodized in an aqueous solution of sulfuric acid (VI) at a concentration of 150 g / l with the addition of aluminum ions at the level of 1.1 g / l at a temperature of 18 ° C, under constant current conditions with a current density of 1.1 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 200 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is performed using an alternating current of 8 V in an electrolyte containing 15 g / l of copper (II) sulphate (VI), 20 g / l of boric acid and 1 g / l of tartaric acid. Throughout the process, the electrolyte temperature is 18 ° C. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 120 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z k ł a d 7

After degreasing and etching the surface, the aluminum product is anodized in an aqueous solution of phosphoric acid at a concentration of 120 g / l at 18 ° C with the addition of aluminum ions at the level of 1 g / l, under constant current conditions with a current density of 1.1 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 200 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is performed using an alternating current of 8 V in an electrolyte containing 15 g / l of copper (II) sulphate (VI), 20 g / l of boric acid and 1 g / l of tartaric acid. Throughout the process, the electrolyte temperature is 18 ° C. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 120 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z k ł a d 8

After degreasing and etching the surface, the aluminum product is anodized in an aqueous solution of sulfuric acid (VI) at a concentration of 150 g / l with the addition of aluminum ions at a level of 1.0 g / l at a temperature of 20 ° C, under constant current conditions with a current density of 1.1 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 200 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is performed using an alternating current of 8 V in an electrolyte containing 15 g / l of copper (II) sulphate (VI), 20 g / l of boric acid and 1 g / l of tartaric acid. Throughout the process

The electrolyte temperature is 22 ° C. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 120 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z k ł a d 9

After degreasing and etching the surface, the aluminum product is anodized in an aqueous solution of sulfuric acid (VI) at a concentration of 120 g / l with the addition of aluminum ions at the level of 1.0 g / l at a temperature of 21 ° C, under constant current conditions with a current density of 1.1 A / dm ² . An aluminum sheet with a surface equal to or greater than that of the aluminum product may be used as the cathode. The anodizing time was 250 seconds. After completing the anodizing process, the element should be rinsed in deionized water, and after draining off the excess, the next stage can be started. Electrochemical dyeing is performed using an alternating current of 8 V in an electrolyte containing 15 g / l of copper (II) sulphate (VI), 20 g / l of boric acid and 1 g / l of tartaric acid. The electrolyte temperature is 25 ° C throughout the process. A stainless steel counter electrode has a working surface equal to or greater than that of the aluminum product. The electrolyte is constantly stirred and the staining time is 100 seconds. After the end of the process, the aluminum product is rinsed in deionized water and then dried. The block diagram of the interference coatings manufacturing process is shown in Fig. 1.

P r z k ł a d 10

The aluminum product produced by the method according to the invention has an interference coating. Fig. 2 shows a cross-section of such a product showing the structure of a coating in which light interference occurs, where the individual numerals represent:

- area of precipitated copper;

- pores in the structure of the oxide layer on aluminum;

- an oxide layer on aluminum resulting from the anodizing process;

- wall of the aluminum product;

A - ray of light reflected from the oxide layer;

B - a ray of light reflected from the surface of copper precipitation;

C - ray of light reflected from the bottom of the porous structure; d - the thickness of the oxide layer on the aluminum.

Claims (11)

A method of producing an interference coating on the surface of an aluminum alloy or alloy product, including anodizing and electrochemical dyeing with the use of alternating current, characterized in that the electrolyte used during electrochemical dyeing contains copper (II) sulphate in an amount from 1 to 100 g / l, boric acid in an amount from 1 to 40 g / l and tartaric acid in an amount of 0.1 g to 20 g / l. 2. The method according to p. The process of claim 1, wherein the dyeing is carried out under continuous stirring of the electrolyte. 3. The method according to p. The process of claim 1 or 2, characterized in that the dyeing time is greater than 10 s. 4. The method according to p. A process according to claim 1, 2 or 3, characterized in that the dyeing is carried out at a temperature of 5-40 ° C. 5. The method according to any of the preceding claims, characterized in that the dyeing is performed with alternating current with a voltage in the range of 0.5-50 V. 6. The method according to any of the preceding claims, characterized in that the anodizing takes place in a solution of sulfuric acid with a concentration of 50-500 g / l with the addition of aluminum ions in an amount of 0-100 g / l. A method according to any of the preceding claims, characterized in that the anodizing is carried out at a current density of 0.1-5 A / dm ² . 8. The method according to any of the preceding claims, characterized in that the anodizing is performed for 10-3600 seconds. A method according to any of the preceding claims, characterized in that the article is sealed after dyeing. PL 241 203 Β1 10. The method according to p. A process as claimed in claim 9, characterized in that the sealing is performed by a hot or cold hydrothermal method or by a vapor deposition method. 11. The method according to p. 10. The process of claim 10, wherein the sealing is performed by the vapor deposition method using the atomic layer deposition technique.