RU2657261C2 - Method of creating an identification mark and a tool for electrochemical processing of an identification mark - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to the identification of material resources made of electrically conductive materials. Method includes applying to the electrically conductive object a coordinate grid with an identification number and an individual unique matrix obtained by electrochemical interference between the object and an electrode connected to a low-voltage current source with the introduction of laser radiation through a glass substrate and a semitranslucent metal film into the interelectrode gap. Laser radiation is introduced into the interelectrode gap through a corner reflector freely fixed above the metal film and located in the electrolyte stream above the metal film, the electrolyte stream in front of the corner reflector is further turbulized. Tool for electrochemical processing is also provided that creates an identification mark on an electrically conductive object using laser radiation stochastically irradiating the surface of the object in a wide range without the use of a random number generator.

EFFECT: method for creating an identification mark and a tool for electrochemical processing of the identification mark are proposed.

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Description

The invention relates to the field of information technology, more specifically to methods of information protection, and can be used to create systems for identifying material resources made of electrically conductive materials, such as weapons, machine parts, aircraft and other objects, the production of which uses electrochemical processing of metals.

As an analogue when considering the method, it is possible to choose a method for identifying an electrically conductive object [1] by applying to the object (marks on the object and entering into the computer memory a coordinate information grid with an identification number and an individual matrix (picture) obtained by the electrical action between the object and the electrode and the subsequent identification by comparing the identification number and individual matrix with previously registered.

However, this identification method has several disadvantages. To implement this method, it is necessary to use high voltage and vibration, which is unsafe for maintenance personnel.

As an analogue, you can use the method of identification of an electrically conductive object [2] by applying to the object (marks on the object) and entering into the computer memory a coordinate grid with an identification number and an individual matrix obtained by electrochemical action between the object and the sectional electrode connected to a low-voltage current source through random number generator. The information saturation of an individual matrix increases with an increase in the number of electrode sections, but it is impossible to increase the number of sections to infinity. A more deeply encrypted matrix can be reached with a laser.

As a prototype, the electrochemical beam method [3] is selected using laser radiation controlled by a random number generator.

However, this idea can also be realized without an expensive random number generator and complex automation moving a laser in space.

A method for creating an identification mark on an electrically conductive object is proposed, including applying a coordinate grid with an identification number and an individual unique matrix to the object obtained by electrochemical action between the object and the electrode connected to a low-voltage current source with the introduction of laser radiation through a glass substrate and a translucent metal film into the interelectrode gap in which laser radiation is introduced into the interelectrode gap through an angular reflector, with rim mounted on a metal film disposed in the flow of electrolyte over the metal film, wherein the electrolyte stream before corner reflector further turbulence.

Also proposed is a tool for electrochemical processing of an identification mark on an electrically conductive object, comprising a laser and an electrode made in the form of a translucent metal film mounted on a glass substrate and capable of transmitting laser radiation, the electrode being configured to be mounted above the object and connected to a low voltage source, characterized in that the laser is mounted parallel to the translucent metal film and a channel is formed above the translucent metal film for supplying an electrolyte, in which an angular reflector is mounted with the possibility of deflecting laser radiation under the action of an electrolyte flow.

The proposed method for identifying an electrically conductive object is carried out by applying to the object (marks on the object) and entering into the computer memory a coordinate mark with an identification number and an individual matrix obtained by electrochemical action between the object and the electrode connected to a low-voltage current source and with the introduction of laser radiation through a translucent metal film in the interelectrode gap.

A feature of the proposed method lies in the fact that laser radiation is introduced into the interelectrode gap through an angular reflector freely fixed above the metal film located in the electrolyte stream above the metal film, and the electrolyte stream in front of the reflector is additionally turbulized.

In FIG. 1 schematically shows a system that allows to implement such a method. As in many other methods of identifying electrically conductive objects 1 (marks on object 1), a coordinate grid 2 with identification number 3 is applied to the object, followed by the entry of this information into the computer's memory. An individual matrix 4 on the object (label) 1 is created due to the electrochemical process between the metal film and the object and due to laser radiation stochastically moving over the individual matrix 4, which consists of a coordinate grid 2, identification number 3. 5 - a low-voltage current source is conventionally shown 5. The glass substrate has a transparent glass substrate 6 and a translucent metal film 7, which ensures that laser radiation hits a specific location on an individual matrix 4. Thanks Besides that corner reflector 8 is mounted relatively freely, electrolyte flow continuously oscillates deflector 8, causing the stochastic moving the laser across the surface of the matrix 4, creating a unique surface to the object 1.

In FIG. 2 also shows an electrode tool for electrochemical beam processing. It contains an electrode in the form of a translucent metal film 7 connected to a low-voltage current source 5. In order to avoid film vibrations, the latter is mounted on a glass substrate 6. The laser 13 is mounted parallel to the translucent metal film 7. An angled corner is mounted over the translucent metal film in the electrolyte stream formed by an additional channel 9 reflector 8 with the possibility of deviation under the action of an electrolyte stream. The reflector 8 can be mounted on a flexible fastener 11 mounted directly on the glass substrate 6 (Fig. 2), the reflector 8 can be suspended on at least two suspensions 10 to the additional channel 9. (Fig. 3) The additional channel 9 is equipped with turbulators 12 electrolyte flow. For each series of experiments, it is desirable to change the shape and size of the turbulators 12. The philosophical thesis of Heraclitus “it is impossible to enter the same river twice” fully applies to the flow of electrolyte. However, the latest improvement about changing the shape and size of turbulators 12 only strengthens this feature.

An example of the method

An aqueous solution of NaCl transparent to laser radiation was chosen as the electrolyte. When the electrolyte consumption in the additional channel 9 is from 5 to 12 l / min, an oscillation of the corner reflector 8 is detected, leading to a deviation of the laser beam from a neutral position on the surface of the object matrix 1 in the range from -14 to +23 mm at 5 l / min and from - 16 to +32 at a flow rate of 12 l / min. This confirms the possibility of stochastic irradiation of the surface of the matrix 4 of the object 1 in a wide range without using a random number generator.

Thus, a method for identifying an electrode tool and an electrode tool for its implementation, which does not need to move the laser (it is stationary) and does not need an expensive random number generator, is proposed.

Sources of Patent Information

1. Patent RM No. 3389

2. Patent of RM No. 1993

3. Patent RM No. 4045

Claims (5)

1. A method of creating an identification mark on an electrically conductive object, comprising applying to the object a coordinate grid with an identification number and an individual unique matrix obtained by electrochemical action between the object and the electrode connected to a low-voltage current source with the introduction of laser radiation through a glass substrate and a translucent metal film into the interelectrode the gap, characterized in that the laser radiation is introduced into the interelectrode gap through the corner reflector Freely mounted on the metal film located in the flow of electrolyte over the metal film, wherein the electrolyte stream before corner reflector further turbulence. 2 A tool for the electrochemical processing of an identification mark on an electrically conductive object, comprising a laser and an electrode made in the form of a translucent metal film mounted on a glass substrate and capable of transmitting laser radiation, the electrode being configured to be mounted above the object and connected to a low voltage source, characterized in that the laser is mounted parallel to the translucent metal film and a channel is formed over the translucent metal film for supplying electric trolite, in which an angular reflector is installed with the possibility of deflecting laser radiation under the action of an electrolyte flow. 3. The tool according to claim 2, characterized in that the corner reflector is suspended on at least two suspensions in the channel for the electrolyte. 4. The tool according to p. 2, characterized in that the reflector is mounted on a flexible fixture, mounted in turn directly on the glass substrate. 5. The tool according to claim 2, characterized in that the channel for supplying electrolyte is equipped with turbulators.

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