RU2632006C2 - Method for production of multilayer valuable product with luminescent protective element and multilayer valuable product - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: product is immersed in a bath using rod holders for galvanic metal coating application, provided with anodes of pure metal, such as nickel, copper or brass, or silver. The bath is filled with electrolyte from the group consisting of pyrophosphate, sulfate, ferricyanide, polyphosphate, thiocyanate, iodide, sulfamic, trilonate, dicyanoargentate, cyanide, and marking phosphor is added, which is coated with a protective sheath in the form of a protective capsule inert to the electrolyte, optically and/or physically transparent, with the ability to pass the waves in the optically visible and/or invisible range. The galvanic coating of the said metals is deposited at continuous electrolytic stirring at 650 rpm and electrolyte temperature of 20-70°C, and during metal coating deposition, phosphor refilling is performed. Electric phosphor, and/or Stokes phosphor, and/or anti-Stokes phosphor are used as marking phosphor. The protective sheath - alumina or titania, is applied in vacuum using atomic layer deposition, and silicon oxide is applied in vacuum using chemical vapour deposition. Calcium silicate treated by zinc sulfate can be also used as the protective sheath.

EFFECT: resulting multi-layer valuable metal product with a protective luminescent element has a high degree of protection against forgery.

7 cl, 4 ex

Description

The invention relates to multilayer products containing metal and protective layers for protection against counterfeiting, in particular to the production of multilayer metal products made of different materials, protected from counterfeiting, such as, for example, changeable or collectible precast coins, metal tokens, medals, and also to the original and high-precision method of their manufacture.

A multilayer coin-like product is known from the prior art, in particular, a token containing coding elements in the form of a layer of a luminescent substance RU 2121285 C1. Coding elements in this product provide an increase in the degree of protection against counterfeiting.

Also known is a multilayer product containing at least one metal and / or polymer base layer and an additional layer with coding elements, characterized in that the additional layer is made in the form of a layer of a coloring substance that forms a two-dimensional QR code and is placed on the surface of the multilayer products (RU 134483, B32B 15/04 2013).

There is also a method of producing a two-layer protective coating, in which the nickel coating is 5-7 μm thick, then copper, 20-25 μm thick, and then heat treatment is carried out in three stages (RU 2066715, B32B 15/00, 1994), which is the closest analogue of the claimed method.

Closest to the claimed product is a multilayer metal product containing a metal selected from the range of aluminum, titanium, tantalum, niobium, with the upper surface layer subjected to electrochemical processing (RU 99379, B32B 15/00, 2010).

The disadvantage is the low degree of security, which is eliminated in the claimed invention due to the use of a phosphor enclosed in a transparent shell, which is deposited during galvanization of the product.

The technical result is an increase in the degree of protection, achieved by the fact that the method of manufacturing a multilayer valuable product with a protective element of a luminescent type includes immersing the product using rod holders in a bath for applying a galvanic metal coating, equipped with anodes made of metal, necessary for the deposition process, into which poured either pyrophosphate, or sulfate, or iron-hydrogen, or polyphosphate, or thiocyanate, or iodide, or sulfamine, or trilonate, or dicyanoar a gentate or cyanide electrolyte with a marking phosphor coated with a protective shell in the form of a protective capsule that is inert with respect to the electrolyte, and subsequent overgrowth of the marking phosphor in the shell during the deposition of the metal coating, while the protective shell is made optically and / or physically transparent, with the ability to transmit waves in the optically visible and / or invisible spectrum.

The process is carried out with continuous stirring of the electrolyte at a speed of up to 650 rpm, and the deposition is carried out at an electrolyte temperature of 20-70 ° C and current density required for the process.

As a protective shell, aluminum oxide or titanium oxide is applied, deposited in vacuum using the ALD process - atomic layer deposition.

Silicon oxide is applied as a protective sheath, deposited in vacuum using the CVD process - chemical vapor deposition.

As a protective shell, calcium silicate treated with zinc sulfate is used.

As the marking phosphor, an electroluminophore and / or Stokes phosphor and / or anti-Stokes phosphor are used.

Nickel, or copper, or brass, or silver, of which anodes are made, are used as a metal coating, respectively.

A multilayer valuable product, such as a token, medal, coin, badge, is obtained by the method as described above.

The invention is illustrated by examples.

Example 1

In the bath, for example, a Watts type sulfate electrolyte consisting of divalent nickel sulfate, divalent nickel chloride and boric acid is poured. A token from, for example, an iron alloy is immersed using rod holders in a bath for applying a galvanic metal coating of nickel, equipped with anodes of chemically pure nickel, into which a sulfate electrolyte with a marking phosphor is poured (inorganic chemical compound, for example Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu electroluminophore), coated in the form of a protective capsule inert with respect to the electrolyte, and the surface is “overgrown” with continuous stirring of the electrolyte at a speed of 650 rpm, and deposition lead at Temperature of electrolyte 70 ° C and current density required for the process.

As a protective sheath, aluminum oxide is applied, optically and / or physically transparent, with the ability to transmit waves in the optically visible and / or invisible spectrum (in another example, titanium oxide), in vacuum using the ALD process (ACO - atomic layer deposition) .

(In various examples, an electroluminophore and / or Stokes phosphor and / or anti-Stokes phosphor, for example ZnS: Cu electroluminophore; Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb.) Were used.)

Example 2

A token from, for example, an iron alloy is immersed with the help of rod holders in a bath for applying a galvanic metal coating of copper, equipped with anodes of chemically pure copper, into which an electrolyte for applying copper is poured either sulfate, or cyanide, or pyrophosphate with a marking phosphor (inorganic chemical compound, for example, Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu-electroluminophore), coated in the form of a protective capsule, inert with respect to the electrolyte, and the surface is “overgrown” with continuous stirring electronic Olita at 650 rev / min and deposition is carried out at an electrolyte temperature of 40 ° C and current density required for the process.

Optically and / or physically transparent, with the ability to transmit waves in the optically visible and / or invisible spectrum, silicon oxide in vacuum is applied as a protective sheath using the CVD process - chemical vapor deposition.

(In various examples, an electroluminophore and / or Stokes phosphor and / or anti-Stokes phosphor was used as an inorganic chemical compound, for example, Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu electroluminophore.)

Example 3

An icon made of, for example, an iron alloy is immersed with the help of rod holders in a bath for applying an electroplated metal coating of brass, equipped with anodes of chemically pure copper and zinc, into which an electrolyte is applied for applying brass, either sulfate or cyanide or pyrophosphate with a marking phosphor (inorganic chemical compound, for example, Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu-phosphor), coated with a protective capsule inert with respect to the electrolyte, and the surface is “overgrown” with continuous mixing electrolyte at a speed of 214 rpm, and the deposition is carried out at an electrolyte temperature of 50 ° C and current density necessary for the process.

Optically and / or physically transparent, with the ability to transmit waves in the optically visible and / or invisible spectrum, calcium silicate treated with zinc sulfate is used as a protective sheath.

(In various examples, an electroluminophore and / or Stokes phosphor and / or anti-Stokes phosphor was used as an inorganic chemical compound, for example, Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu electroluminophore.)

Example 4

As in example 3, the medal is immersed with the help of rod holders in a bath for applying a galvanic metal coating of silver, equipped with anodes of chemically pure silver, into which a sulfate electrolyte for applying silver is added, or sulfate, or cyanide, or pyrophosphate with a marking phosphor (inorganic chemical compound, such as Y ₂ O ₂ S: Yb, Er; Y ₂ O ₂ S: Tb; ZnS: Cu-electroluminophor), coated in a protective capsule which is inert to the electrolyte, and "zaraschivayut" surface with continuous Shuffle AANII electrolyte at a speed of 430 rev / min and deposition is carried out at an electrolyte temperature of 50 ° C and current density required for the process.

Optically and / or physically transparent, with the ability to transmit waves in the optically visible and / or invisible spectrum, calcium silicate treated with zinc sulfate is used as a protective sheath.

In all examples, metal coatings were obtained with embedded encapsulated phosphors located along the thickness of the coating giving a response to the introduced excitation.

Thus, the technical result is clearly achieved by the claimed invention.

Claims (7)

1. A method of manufacturing a multilayer valuable metal product with a protective luminescent element, comprising immersing the product in a bath for applying a galvanic metal coating, equipped with metal anodes, into which an electrolyte with a marking phosphor is poured, characterized in that the product is immersed in the bath using rod holders, the anodes are made of chemically pure metal, a phosphor coated with a protective shell in the form of a protective capsule inert with respect to the electrolyte is used, optically and / or visually transparent with the ability to pass waves in the optically visible and / or invisible range, an electrolyte from a series including pyrophosphate, sulfate, iron-hydrogen, polyphosphate, rhodanic, iodide, sulfamic, trilonate, dicyano-argentate, cyanide-mixed mixing is poured into the bath electrolyte at a speed of up to 650 rpm and an electrolyte temperature of 20-70 ° C, and in the process of deposition of a metal coating, phosphor is fused. 2. The method according to p. 1, characterized in that as a protective sheath, aluminum oxide or titanium oxide is applied in vacuum using the ALD process - atomic layer deposition. 3. The method according to p. 1, characterized in that as a protective sheath, silicon oxide is applied in vacuum using the CVD process - chemical vapor deposition. 4. The method according to p. 1, characterized in that as a protective shell using calcium silicate treated with zinc sulfate. 5. The method according to p. 1, characterized in that the electroluminophore and / or the Stokes phosphor and / or anti-Stokes phosphor are used as the marking phosphor. 6. The method according to p. 1, characterized in that as a metal coating using nickel, or copper, or brass, or silver, of which anodes are made, respectively. 7. A multilayer valuable product, such as a token, medal, coin, badge, obtained by the method according to any one of paragraphs. 1-6.