MD921Z - Installation and process for manufacturing an identification tag on a current-conducting object - Google Patents

Abstract

The invention relates to the field of information technologies and can be used for manufacturing an identification tag by electrochemical machining of current-conducting objects.The installation for applying an individual image on a current-conducting object comprises a vacuum chamber (6), in the lower part of which is placed the working part, made of metal foil (7) with an annular cooling tube (9). In the upper part of the chamber (6) is installed a system of tapered electrodes (10), connected to a high-voltage source (11). Under the vacuum chamber (6) are placed a capacity with electrolyte for positioning therein of a current-conducting object, a displacement device (14) and a random number generator (13). The working part (7) and the current-conducting object are connected to a low-voltage source (8).The process for manufacturing an identification tag on a current-conducting object comprises application on the object of an identification tag, consisting of an identification number, an information coordinate grid and an individual image, obtained electrochemically using the above installation, wherein the vacuum chamber is mounted fixedly. The object is displaced randomly in a two-coordinate plane.

Description

The invention relates to the field of information technologies and can be used to execute identification marking through electrochemical processing of electroconductive objects.

A method of identifying an electroconductive object is known, which includes printing an identification number, mechanically applying an informational coordinate grid to the object, followed by a point-like electrical discharge between the object, one or several vibrating electrodes made of different metals or alloys, which move arbitrarily in the coordinate system of the grid and are installed above it, and a mixture of electroconductive powders optionally introduced into the interstice between the object and the electrode/electrodes [1].

The disadvantage of this method is that it requires the use of high voltage equipment, which is dangerous for the operating personnel. To maintain the spark discharge regime, it is necessary to use the vibration of the electrode (identification object), which is also harmful for the operating personnel.

Also known is a method of identifying an electroconductive object, which includes applying an identification mark to the object, consisting of an identification number, an information grid of coordinates and an individual image, obtained by applying electric current to the object and to an electrode, installed with a gap above it and consisting of sections, connected to a low-voltage electrical power source through a random number generator. At the same time, a liquid electrolyte is discharged into the gap between them. The mark obtained is recorded in the computer memory, and the object is identified by comparing the mark on the identified object with the registered one [2].

The disadvantage of this process is the low productivity.

The closest solution is an electrochemical process for identifying an electroconductive object, which includes applying an identification mark to the object, consisting of an identification number, an information grid of coordinates and an individual image, obtained electrochemically when applying electric current to the object and to an electrode-tool, with the working part in the form of a metal foil, installed above the object with a gap, into which the previously cooled electrolyte is discharged, additionally a random flow of electrons is injected through the metal foil. The obtained mark is recorded in the computer memory, and the object is identified by comparing the mark on the object to be identified with the registered one [3].

The disadvantage of this method is that the influence of the intensification is distributed over the entire surface of the object (the mark on the object). At the same time, the difference between the sections where the electron flow hit and where it did not hit is insignificant, which makes the process of comparing the mark on the object and in the database under the same number a little different.

An installation for applying an individual image to an electroconductive object is known, which includes a vacuum chamber made of dielectric material with the working part made of a metal foil fixed on an internal support made of a coiled pipe, connected to a system for dispensing the cooled electrolyte. A row of sharp electrodes is installed in the vacuum chamber, which together with the metal foil are connected to a high voltage source through a random number generator, while the metal foil is connected to a low voltage source [3].

The disadvantage of this installation is that all the sharp electrodes, which are located in the vacuum chamber, are directed parallel to each other and irradiate the entire surface of the future identification mark, which reduces the level of identification indices.

The problem solved by the invention consists in increasing productivity and creating an identification mark with enhanced identification characteristics.

The installation, according to the invention, eliminates the above-mentioned disadvantage by containing a vacuum chamber, made of a dielectric material, at the bottom of which is located the working part, made of a metal foil, on which is placed an annular cooling tube, connected to an electrolyte delivery system; at the top of the chamber is installed a system of sharp electrodes, connected to a high voltage source and directed so that the electron flow is focused at a point on the surface of the electroconductive object; under the vacuum chamber is placed an electrolyte tank for placing the electroconductive object therein, connected to a device for moving it, operated by a random number generator; the working part and the electroconductive object are connected to a low voltage source.

The method, according to the invention, eliminates the above-mentioned disadvantages by including the application on the object of an identification mark, consisting of an identification number, an information grid of coordinates and an individual image, obtained electrochemically using the installation for applying the individual image on an electroconductive object, defined in claim 1, in which the vacuum chamber is placed immobile; at the same time, electric current is applied to the object and to the sharp electrode system with the passage of the electron flow through the metal foil and with the flow focusing at a point on the identification mark, and the object is randomly moved in a two-coordinate plane.

The invention is explained by the drawings in Fig. 1-4, which represent:

- Fig. 1, installation diagram;

- Fig. 2, the marking surface;

- Fig. 3, installation diagram;

- Fig. 4, annular cooling tube.

Fig. 1 schematically shows the installation, which operates according to the proposed process. The process involves marking an electroconductive object 1 with the identification mark 2, the information grid 3 and the individual matrix 4 and injecting the focused electron flux 5 onto the surface of the mark (Fig. 1, 2).

When focusing the electron flow due to the increased electron density, the speed of electrochemical reactions suddenly increases, which makes the identification mark with indices much more distinctive.

In Fig. 3 the installation is shown. It contains a vacuum chamber 6 made of dielectric material with a working section in the form of a metal foil 7, connected to the low voltage source 8 and an annular cooling tube of the foil 9, connected to the electrolyte supply, with a system of sharp electrodes 10, installed in the vacuum chamber, connected to the high voltage source 11 and a counter electrode 12 facing the sharp electrodes 10. All sharp electrodes 10 in the vacuum chamber 6 are directed to one point on the surface of the identification mark 2, and the cooling tube 9 is made in the form of a ring in the center of which is the partially focused electron beam (Fig. 4). The cooling system is made in the form of an annular contour, through which the cooling dielectric liquid is discharged. Since the foil is not in the focus, the density of electron radiation in it is much lower. The marker is equipped with a movement device 14 using the random number generator 13.

The installation works as follows. When the electrode is brought into the gap between the identification mark and the tool electrode, the electrolyte, passing through the cooling ring, leads to additional cooling of the metal foil. When the foil 7 and the object 1 with the future mark 2 are connected to the low-voltage source 8, the electrochemical reaction is initiated on the surface of the reference. To amplify the chemical reactions, high voltage is applied to the sharp electrodes 10 and the counter electrode 12 from the source 11. A flow of electrons is released from the tips of the electrodes 10. Since the chamber 6 is evacuated, the electron flux freely reaches the foil 7. Penetrating the foil 7, the electron flux heats it, which is why the cooling system 9 is provided. Passing through the transparent electrolyte, the electron flux hits the surface of the identification mark 2, sharply increasing the speed of electrochemical reactions in the place where it hit. Since all the sharp electrodes 10 are directed at one point on the surface of the identification mark 2, and the object 1 itself is equipped with a device 14 for moving the mark in a two-coordinate system using the random number generator 13, and the focus of the permanent electron flux is strictly in the required place, an individual image is created with well-relieved identification indices.

The proposed process can be used not only for making identification marks, but also in electrochemical processing of metals, in particular for making annular channels in gun barrels. However, for this it is necessary to invent a system for introducing electron flux or laser radiation into a long barrel.

1. MD 3389 F2 2007.08.31

2. MD 3992 B2 2009.12.31

3. MD 404 Y 2012.02.29

Claims (2)

1. Installation for applying an individual image to an electroconductive object, which contains a vacuum chamber (6), made of a dielectric material, at the bottom of which is placed the working part, made of a metal foil (7), on which is placed an annular cooling tube (9), connected to an electrolyte delivery system; at the top of the chamber (6) is installed a system of sharp electrodes (10), connected to a high voltage source (11) and directed so that the electron flow (5) is focused at a point on the surface of the electroconductive object (1); under the vacuum chamber (6) is placed a reservoir with electrolyte for placing the electroconductive object (1) therein, connected to a device for moving it (14), driven by a random number generator (13); the working part (7) and the electroconductive object (1) are connected to a low voltage source (8). 2. Method for performing an identification mark on an electroconductive object, which includes applying to the object an identification mark consisting of an identification number, an information grid of coordinates and an individual image, obtained electrochemically using the installation for applying an individual image to an electroconductive object, defined in claim 1, in which the vacuum chamber is placed stationary; at the same time, electric current is applied to the object and to the sharp electrode system with the passage of the electron flow through the metal foil and with the flow focusing at a point on the identification mark, and the object is randomly moved in a two-coordinate plane.