MD1121Z - Installation for application of the individual image on the current-conducting object and method for identification thereof - Google Patents

Abstract

The invention relates to the field of information technology and can be used to generate identification marks by electrochemical processing of metals and creating databases of solid material resources, in particular from an electrically conductive material. The installation for applying an individual picture to an electrically conductive object (3) includes an electrode (2), consisting from sections (7), and a low voltage source (6), to which an electrode (2) and an object (3) are connected. The installation also includes a dielectric limiter (13), installed with the possibility of forming with the object (3) a channel for the flow of electrolyte (4). Sections (7) are movable, with the possibility of changing their position in space under the action of an electrolyte stream (4), by attaching them to current leads (5) made of flexible, of different lengths. Each section (7) is made in the form of a ball, on the outer surface of which a dielectric coating is applied with exposed sections and dielectric protrusions. A method of identifying an electrically conductive object includes applying an identification mark to the object, consisting of an identification number, a coordinate information grid and an individual picture obtained by passing an electric current through an electrolyte flowing between an object and an electrode consisting of movable sections, and registering the resulting mark in memory s computer, and object identification is performed by comparing the tags with the identified object with the previously registered.

Description

The invention relates to the field of information technologies and can be used for forming identification marks through electrochemical processing of metals and creating databases of solid material resources, especially from electroconductive material.

A process for identifying material resources is known, which is carried out by printing an identification number, on which an information grid is applied, followed by blowing the grid surface with a strong jet of gas mixed with metallic or non-metallic particles, which move on the processed surface following an arbitrary trajectory, then the obtained image of the information grid is scanned and stored in the memory of a computer, and product identification is achieved by comparing the number and image of the product grid with the number and image of the previously recorded grid [1].

The disadvantage of this method is the difficulty of processing metal surfaces and high-strength alloys. The difficulties arise because during subsonic acceleration of particles their kinetic energy is not sufficient to penetrate high-strength metals and, respectively, to form an individual image. Gas-dynamic identification is applicable only for the formation of an individual image on surfaces made of plastic, relatively soft metals and alloys, for example, lead, aluminum, copper, bronze, etc.

There is also a known method of identifying an electroconductive object by printing an identification number on the object, on which an information grid of coordinates is applied, followed by performing a point-like electrical discharge between the object and a vibrating electrode installed with a gap above it. The electrode moves arbitrarily in the grid coordinate system, and the obtained image is scanned and stored in the computer memory, while the object is identified by comparing the number and the image with the previously recorded one [2].

The disadvantage of this method is that its implementation requires high-voltage equipment, which is dangerous for the operating personnel. To maintain the electrical discharge regime, vibration of the electrode or object is necessary, which is not harmless for the operating personnel. At the same time, the formation of an individual image on the mark by the method of electrical discharge is accompanied by a minimal mass transfer from the high-voltage electrode to the object and is not accompanied by a complete change in the state of the mark, which changes only in the place where the pulsed electrical discharge occurred, the size of which is, as a rule, proportional to the size of a match head. The adjacent area, where the electrical discharge failed, remains unchanged.

Also known is an installation for applying an individual image to an electroconductive object, which includes an electrode, formed of sections and installed above the object with a gap. Each section is connected to a device for moving it and to a low-voltage electrical power source through a random number generator. The installation also includes a system for pumping liquid electrolyte into the gap between the electrode and the object [3].

The disadvantage of this installation is that to obtain the unreproducible image on the marking, the electrode sections are connected to the power source through the random number generator, which is not always reliable.

There is also known 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, 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 [3].

The disadvantage of this process is that, since the electrodes are fixed, to obtain stochasticity it is necessary to use a random number generator, whose reliability is not always sufficient.

The problem solved by the invention consists in creating an installation and a process that allows the formation of conditions for the stochastic manifestation of the electrochemical process.

The installation for applying an individual image to an electroconductive object, according to the invention, eliminates the above-mentioned disadvantages by including an electrode, formed of sections, and a low-voltage source for connecting the electrode and the object to it. The installation also includes a dielectric limiting wall, installed with the possibility of forming with the object a channel for the flow of an electrolyte. The electrode sections are made mobile, with the possibility of changing their position in space under the action of the electrolyte flow, being fixed on conductors, made flexible, of different lengths. Each section of the electrode is made in the form of a sphere, on the outer surface of which a dielectric coating is applied, with the formation of bare portions of different shapes and sizes and dielectric protrusions. Electrolyte turbulators, made in the form of spiral petals, installed at different distances from each other, are fixed on the conductors. Turbulators are fixed on the limiting wall, preferably at the end corresponding to the channel entrance.

The method of identifying an electroconductive object, according to the invention, eliminates the disadvantages mentioned above by including the application on the object of an identification mark, consisting of an identification number, a coordination information grid and an individual image, applied with the help of the installation, defined above, being obtained when the electric current passes through an electrolyte, discharged in the interstice between the object and an electrode, consisting of mobile sections, fixed with the possibility of changing their position in space under the action of the electrolyte flow, as well as the recording of the mark obtained in the memory of a computer, and the identification of the object is achieved by comparing the mark on the object subject to identification with the previously recorded one.

The peculiarity of the proposed installation is that each section of the electrode is connected directly to the low voltage source, without the use of a random number generator, which is not always reliable.

Obtaining a large number of individual image varieties is conditioned by the implementation of movable electrode sections, with the possibility of changing their position in space under the action of the electrolyte flow.

The advantage of the invention consists in obtaining identification marks with a higher degree of non-reproducibility.

The invention is explained by the drawings in Fig. 1 and 2, which represent:

- Fig. 1, view of the installation for applying the individual image on the electroconductive object;

- Fig. 2, view of a section of the electrode with exposed portions of different shapes and sizes.

The installation for applying an individual image to an electroconductive object (Fig. 1) includes the gap 1, the electrode 2 and the object 3. The electrode 2 consists of sections 7, connected directly to the low voltage source 6, without the use of a random number generator. The sections 7 are fixed on the conductors 5, made flexible and of different lengths. Each section 7 is made in the form of a sphere (Fig. 2), on the outer surface of which the dielectric coating 8 is applied with the formation of bare portions 9 of different shapes and sizes and dielectric protrusions 10. The turbulators 11 of the electrolyte 4 are fixed on the conductors 5, made in the form of spiral petals, installed at different distances from each other. The dielectric limiting wall 12 is installed with the possibility of forming with the object 3 the electrolyte flow channel 4 (Fig. 1). Turbulators 13 are fixed on the limiting wall 12, preferably at the end corresponding to the channel entrance.

The installation works as follows.

In the electrolyte flow channel 4, formed by the dielectric limiter 12 and the object 3, the electrolyte 4 is fed by means of a supply system. Since the sections 7 are fixed on the conductors 5, and these are equipped with the turbulators 11, during the flow of the electrolyte flow 4 the sections 7 continuously change their position relative to the object 3, forming an individual, unreproducible image on the identification mark.

The turbulators 13 form the primary non-repeatability of the electrolyte flow 4. The protrusions 10 form a gap and do not allow the short circuit regime to occur.

Example of the process

The electrode 2 was used, consisting of sections 7, made in the shape of a sphere, with a diameter of 7…15 mm, made of stainless steel X18H9T. On each sphere, a coating 8 of fluoroplastic was applied, forming the bare portions 9 as working windows of various shapes and sizes. Turbulators 11 made of dielectric material, namely fluoroplastic, were fixed on the conductors 5. The sections 7 in the shape of a sphere were fixed on the conductors 5 of various lengths. An aqueous solution of NaCl with a content of 170 g/l was used as electrolyte 4. The object 3 was connected to the positive pole of the source 6, and the sections 7 - to the negative pole. The current density was recorded on the sections 7 in the range of 1…30 A/cm². The source 6 with a voltage of up to 30 V and a current of up to 150 A was used. The electrolyte 4 was fed into the flow channel using a centrifugal pump, which allowed for a non-uniform flow of electrolyte 4. Visualization of the process of the flow of electrolyte 4 in the flow channel confirmed the active movement of the sections 7. When executing the turbulators 11 in the form of spiral petals, the process of rotation of the sections 7 was fixed, which, in turn, being executed in the form of a sphere and equipped with working windows of various shapes and sizes, guarantee the obtaining of an individual, unreproducible image.

After obtaining the individual image on the object, the identification number and the coordinate information grid are applied to it with an engraving machine, then the obtained marking is scanned and the identification number with the individual image is recorded in the database on a computer. The identification of the object is carried out by comparing the marking on the object subject to identification with the one previously recorded in the database. If the marking with an identification number on the object subject to identification, such as a vehicle engine, has an individual image that does not coincide with the image of the marking previously recorded in the database, having the same identification number, the engine is recognized as counterfeit production.

1. MD 3390 F2 2007.08.31

2. MD 3389 F2 2007.08.31

3. MD 3992 B2 2009.12.31

Claims (2)

1. Installation for applying an individual image to an electroconductive object, which includes an electrode, formed of sections, and a low voltage source for connecting the electrode and the object to it, characterized in that it also includes a dielectric limiting wall, installed with the possibility of forming with the object a channel for the flow of an electrolyte; the electrode sections are made mobile, with the possibility of changing their position in space under the action of the electrolyte flow, being fixed on conductors, made flexible, of different lengths; each section of the electrode is made in the shape of a sphere, on the outer surface of which a dielectric coating is applied, with the formation of bare portions of different shapes and sizes and dielectric protrusions; electrolyte turbulators, made in the form of spiral petals, installed at different distances from each other, are fixed on the conductors; Turbulators are fixed on the limiting wall, preferably at the end corresponding to the channel entrance. 2. Method for identifying an electroconductive object, which includes applying to the object an identification mark, consisting of an identification number, a coordination information grid and an individual image, applied with the help of the installation, defined in claim 1, being obtained when passing electric current through an electrolyte, charged in the interstice between the object and an electrode, consisting of mobile sections, fixed with the possibility of changing their position in space under the action of the electrolyte flow, as well as recording the mark obtained in the memory of a computer, and the identification of the object is achieved by comparing the mark on the object subject to identification with the previously recorded one.