MD796Z - Method for producing the identification tag on a metal carrier - Google Patents

Abstract

The invention relates to the field of information technologies and is intended for identification of material objects, particularly for producing the identification tag on a metal carrier.The method for producing the identification tag on a metal carrier consists in that it is carried out a single electrospark discharge between a high-voltage electrode and a carrier, consisting of a metal sheet with a transparent dielectric film coating on both surfaces. On one of the surfaces, between the metal sheet and the film coating, are placed strips in the form of grid. The carrier is placed in a grounded closed electrode. Thereafter, the carrier is cut into individual cells, on each of which being applied a digital code and a virtual information grid.

Description

The invention relates to the field of information technologies and is intended for identifying material resources, in particular for obtaining an identification mark on a metal carrier.

An identification process is known, which includes printing an identification number on the electroconductive object, mechanically applying an informational coordinate grid to the object, followed by a point-like electrical discharge between the object and the vibrating electrode that moves arbitrarily in the coordinate system of the grid. The obtained image of the grid is scanned and stored in the computer memory, and the identification of the object is achieved by comparing the identification number and the grid image with those previously recorded [1].

The disadvantage of this process is that it is not very reliable and has a low yield due to the long process of obtaining the identification mark.

The closest solution is a method of identifying an electroconductive object, in which the method of obtaining the identification mark consists in the fact that an identification number is printed on the object, on which an information grid of coordinates is applied, on which an unreproducible image is applied by point electrical discharges between the object and an electrode, made of nanocomposites of ultradisperse metal powders, installed with a gap above the information grid. After this, the grid with the obtained unreproducible image is registered in an electronic database, at the same time, according to the law of random numbers, at least one sign is selected on the unreproducible image, the coordinates of which on the information grid and its spectral characteristic are registered in an independent electronic database. Object identification is carried out in two stages [2].

The disadvantages of this process are that it requires expensive spectral devices, low efficiency, the need to perform several electrical discharges, and the impossibility of increasing the productivity of the process. The individual image, without spectral characteristics, has a low information saturation.

The problem that the invention solves is increasing productivity and obtaining an individual image with maximum information saturation.

The method according to the invention eliminates the above-mentioned disadvantages by performing a single electric discharge by sparks between a high-voltage electrode and a carrier, formed by a metal sheet with a transparent dielectric film coating on both surfaces. On one of the surfaces, between the metal sheet and the film coating, some strips are placed in a grid shape, made of a material with an electrical resistance lower than that of the film coating. The carrier is placed with its edges in a closed electrode connected to the ground and with the grid surface facing the high-voltage electrode. After this, the carrier is sectioned into individual cells, on each of which a numerical code and a virtual information grid are applied.

The technical result consists in increasing the productivity of making the identification mark and obtaining an individual image with information saturation formed by several point-like and striated-discontinuous structures of the irreproducible mark.

The invention is explained by the drawing in Fig. 1-3, which represents:

- Fig. 1, diagram of the installation for carrying out the process of obtaining the identification mark on a metal carrier;

- Fig. 2, view of the experimental metal carrier;

- Fig. 3, view of an individual cell.

Fig. 1 schematically shows the installation that allows to carry out the process: 1 - metal support, 2 - glass, 3, 5 - transparent film dielectric coatings, 4 - metal sheet, 6 - closed electrode, 7 - high-voltage capacitor, 8 - high-voltage electrode, 9 - high-voltage source.

Fig. 2 shows the carrier, which consists of: 2 - glass, 4 - metal sheet, 3, 5 - dielectric coatings, 10 - grid-shaped strips, 15 - the place of the single electric discharge by sparks.

In Fig. 3 one of these twelve individual cells is shown: 10 - a part of the grid, 11 - the individual numerical code of the cell, 12 - the virtual information grid, 13 - point evaporations on the metal sheet 4, 14 - striated-discontinuous evaporations of the metal sheet 4.

The process of obtaining the identification mark on a metal carrier consists in performing a single electric discharge by sparks between a high-voltage electrode 8 and a carrier, formed by a metal sheet 4 with a transparent dielectric film coating 3, 5 on both surfaces, at the same time on one of them, between the metal sheet 4 and the film coating 5, some strips 10 are placed in a grid shape, made of a material with a lower electrical resistance than the film coating 3, 5. The carrier is placed with the edges in a closed electrode 6 connected to the ground and with the grid surface 10 facing the high-voltage electrode 8. After this, the carrier is sectioned into individual cells, on each of which a numerical code 11 and a virtual information grid 12 are applied.

The procedure is carried out in the following order: the carrier is installed between the high-voltage electrode 8 and the grounded metal support 1 of the installation. For safety, a glass 2 is installed between the metal support 1 and the carrier. The presence of the dielectric coating 3, 5 leads to the fact that the electric discharge pierces the dielectric coating 5 and ensures the passage of the electric current pulse into the gap between the dielectric coatings 3 and 5. The passage of the electric current from the place of the main electric discharge to the strips 10 with a better electrical conductivity of the information grid is accompanied by the electric discharge of various sectors of the dielectric coating 3, 5 and the subsequent formation of evaporation traces from microdischarges with the appearance on the metal sheet 4 of a multitude of both point-like and linear stretched strips. The electric current discharge occurs through the widest electroconductive strip and is accompanied by complete evaporation of the metal sheet 4, including the periphery. The electric discharge on the strips 10 is carried out at a distance of up to the closed electrode 6 and a limited distance perpendicularly, but not greater than the grid pitch 10 with a length of 8...10 mm. Thus, identification marks are obtained simultaneously on all 12 cells.

The carrier, after processing with a single electric discharge, is sectioned into individual cells (in Fig. 2 twelve such cells are shown, which is not a limit) with subsequent application to each of the twelve cells of a virtual information grid 12 and an individual numerical code 11, applied to each cell with the help of a computer program. The marking is ready and in this form it is entered into the database.

The technical result is a highly productive process of creating, using a single electric discharge, a set of informationally saturated cells with non-repeatable marking, consisting of both point evaporations 13 on the metal sheet 4 and striated-discontinuous sectors 14 on the metal sheet 4.

1. MD 3389 G2 2007.08.31

2. MD 3950 C2 2009.07.31

Claims (1)

Method for obtaining an identification mark on a metal carrier, which consists in performing a single electric discharge by sparks between a high-voltage electrode and a carrier, formed by a metal sheet with a transparent dielectric film coating on both surfaces, at the same time on one of them, between the metal sheet and the film coating, some strips are placed in a grid shape, made of a material with a lower electrical resistance than the film coating; the carrier is placed with the edges in a closed electrode connected to the ground and with the grid surface facing the high-voltage electrode; after this, the carrier is sectioned into individual cells, on each of which a numerical code and a virtual information grid are applied.