RU2637041C2 - Method for manufacturing marking of direct application (mda) - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: specified marking consists of information elements (IE) on the surface of the marked part. After the initial needle-impact action, materials or various materials with the necessary properties are additionally placed between the needle of the needle-impact unit and the surface of the marked part. At subsequent needle-impact actions, they are sequentially moved to the depressions forming the information elements of the MDA. The material, which is placed between the needle-impact installation and the surface of the marked part, may be metal foil or alloy, in particular aluminium, copper, gold, lead, tin, antimony, brass, bronze, duralumin.

EFFECT: providing the high information capacity.

13 cl, 3 dwg

Description

The present invention relates to protective devices and devices for monitoring equipment, to compositions for coating, characterized by the effect of the resulting coating, in particular, luminous paints. The invention also relates to the field of development of optical and optoelectronic marking, analog-to-digital encoding and decoding of various objects and products. More specifically, it relates to methods and systems for marking directly on a marked object - direct marking (MPN - "Direct Part Marking" - DPM).

The technical level of the invention

The requirements for the modern level of technology are determined by the fact that companies and enterprises whose activities are associated with high and / or costly risks are required to provide legal evidence of a causal relationship of losses (and often human casualties) and failure of the product (part, unit), which allows you to transfer responsibility for the consequences of a product failure to its manufacturer (dealer, supplier). Direct marking is used for this.

Unlike markings applied by paint or glued to a controlled object, direct application marking (MPN) consists of information elements (IE) formed by changing the surface of the marked part in one way or another. MPN can only be removed together with the material of the surface of the marked part, thus being a reliable way to control the entire life cycle of an object up to its disposal.

Currently, there are several methods of applying MPN, the equipment for which is offered on the market - it is needle-percussion deposition (IU-MPN), laser deposition (several types), electrospark deposition and deposition by chemical and electrochemical etching.

When applying MPN, as a rule, two-dimensional (2D) encoding is used, which has high information capacity and noise immunity (2D MPN). In terms of the amount of stored information, the capacity of a 2D code can be hundreds of times greater than the capacity of a one-dimensional one (for example, it is capable of storing several pages of text). More importantly, almost all modern technologies of 2D codes, unlike one-dimensional ones, contain error correction tools and, therefore, guarantee greater reliability of data safety.

2D codes have a predominantly matrix form and do not use traditional strokes / spaces to encode information. Instead of the standard technology for determining the stroke width, matrix codes are used to encode information of a “yes - no” or “unit – zero” design (ie, “on / off” - design). There are many varieties of 2D codes (e.g. PDF417, MaxiCode, DataMatrix).

Readers of 2D codes, unlike barcode scanners, first capture the image, then analyze the resulting image, and only then extract it from it and decode the information. In this regard, the reading and decoding of 2D MPN is associated with technological difficulties in terms of hardware solutions and the development of the necessary software. When reading a 2D MPN, the main problem is to obtain a label image with a quality sufficient for reliable decoding of the information contained in it, regardless of the ambient lighting and the state of the surface on which the label is applied. In terms of software, the problem is to increase the decoding ability in the analysis of heterogeneous (“blurry”) images. At the same time, the decoding process is strongly affected by the strong dependence of the obtained electronic image on the state of the surface and external illumination.

The development of ways to increase the stability of decoding and protection against external influences of MPN has been the subject of a number of publications, including patents.

So, in particular, the technical solution proposed in US 2003/9106994 is known, where a protective marking is proposed to identify an object, including a fluorescent or phosphorescent material with an orientationally ordered molecular structure. When the marking is irradiated with UV radiation, it re-emits polarized fluorescent or phosphorescent light, the polarizing and frequency parameters of which are protective signs to identify the authenticity of the object.

The use of the spectral parameters of reflected light or fluorescence as identification features is also characteristic of the claimed invention, however, the marking proposed in the source is not MPN and is easily removed from the surface of the part. In addition, the proposed technical solution does not solve the problem of increasing the contrast and dependence of the marking image on the optical properties of the surface, especially in the case of optical inhomogeneities close in size to the IE markings.

In a presentation by General Electric Inc. ["AIM DPM Verification of Dot Peen Data Matrix Symbols on small curved surfaces", by Ron Page] proposes to fill the needle-stroke marking holes with black or white paint to improve image quality.

Filling IE MPN with a composition with special properties to increase contrast, facilitate reading and improve the protective properties of MPN is also characteristic of the claimed invention, however, the proposed improvement does not reduce the effect of external illumination and does not significantly increase contrast. In addition, methods for filling cavities and methods for implementing protection against unauthorized reading of MPN are not offered here.

The closest solution is proposed in the patent of the Russian Federation with a priority of October 23, 2009 No. 2490709, where an effective way to solve the problem of reading 2D MPN is proposed. To this end, it is proposed to form a direct application mark from information elements that are conical depressions formed during needle impact marking, or surface areas with microcracks and roughnesses formed by laser engraving that are filled with fluorescent paint that absorbs radiation at near UV, visible and near wavelengths IR bands (FMPN). It is specifically proposed to use in the manufacture of markings fluorescent paints that absorb radiation at the wavelengths of the near UV, visible and near infrared ranges and emit in the passband of the receiving channel of the reader, mainly 600-700 nm.

This leads to a significant improvement in the image quality of the marking during its reading, in particular its contrast, and reduces the dependence of the decoding reliability of the marking on the nature of the surface on which the 2D MPN is applied. This solution allows marking to be read both with a conventional reader (reader) and with a special one that registers a fluorescence image.

The use of this solution significantly facilitates the reading of the PSFM, reduces the price of the reader, allows for reading at a greater distance and reduces the requirements for the quality and depth of the recesses, and therefore for the marking device.

At the same time, a method for manufacturing a label is proposed, which consists in filling it with paint and characterized in that it provides localization of the filling area with only information elements. It is proposed to form information elements, in particular, by gluing a film on the part to be marked, in which holes are formed during acoustical marking or laser engraving, through which information elements are filled with fluorescent paint using a roller, swab, brush, squeegee or spray. In development of the method, it is proposed to remove the paint remaining between the information elements by either washing off or erasing, or by gluing to a polymer film with an adhesive layer having good adhesion to the fluorescent paint material. It is proposed to protect the resulting marking by “applying a protective varnish on top, transparent in the visible and absorbing in the UV short-wavelength range”. Moreover, it is not clear from the patent formula at what stage the marking is made, and moreover, the procedure for applying varnish is referred only to markings obtained by laser engraving.

Some of the manufacturing methods of the FMPS set forth in this patent are used in the manufacture of markings in accordance with the claimed invention. However, the solution under consideration does not imply repeated needle-impact, sequential formation of the structure of the MPN information element, or the use of plastic-deformed metals, alloys, or other materials with corresponding properties. These features, as well as the increased resistance of the resulting MPN to mechanical damage, chemical and / or radiation, and / or thermal effects, insolation or UV radiation, determine the differences between the claimed invention and the known ones.

Thus, the totality of the known solutions does not exhaust the totality of the features of the claimed invention.

SUMMARY OF THE INVENTION

The essence of the invention lies in the proposed method for the manufacture of direct application marking, characterized in that after the primary needle-impact action between the needle of the needle-drum set and the surface of the marked part, additionally placed materials (in particular multilayer) containing particles, compositions or substances having the necessary properties . During subsequent needle-impact actions, they sequentially move into the recesses forming the information elements of the MPN. Note that the material that is additionally placed between the needle of the needle-drum set and the surface of the marked part in the manufacture of the MPN must be fixed on the surface of the marked part - for example, by gluing, rolling, mechanical pressing. Moreover, during each cycle of the needle-impact, the impact force of the needle of the needle-drum set can be different.

The material that is placed between the needle of the needle-drum set and the surface of the marked part can be a plastic deformable metal or alloy foil. It is proposed to use aluminum, copper, gold, lead, tin, antimony, brass, bronze, duralumin as a plastic deformable metal or alloy.

Plastic-deformed foil can be used as a carrier of particles that give IE properties that differ from the properties of the material of the marked part. Other carriers of such particles may be fabrics or non-woven materials made from natural or synthetic fibers. Polymeric films can also be used as a carrier of particles that impart IE properties that differ from the properties of the material of the marked part. Such films are obtained by curing a polymer composition based on acrylic, epoxy, urethane, organosilicon, alkyd, polyester and / or any other film-forming polymers.

As a result of the sequential introduction of various particles, IEs are created that differ from the material of the marked part in the fluorescence spectrum, or / and the fluorescence excitation spectrum, and / or the reflection coefficient, and / or the absorption coefficient of electromagnetic radiation in one or more ranges of their spectrum, for example, X-ray , microwave, UV, IR, visible. In addition, the created IE can differ from the material of the marked part in electrical conductivity; magnetic, electrical insulating, triboelectric, adhesive, hydrophilic-hydrophobic properties; the ability to induce catalytic, autocatalytic, radical chain processes, sorption processes, polycondensation.

To facilitate the application of MPN, in particular, to prevent tearing of the carrier material during the needle-impact process, to facilitate its removal after the end of the application of MPN, the carrier can be pre-hardened, for example, reinforced with a polymer or metal mesh.

The surface of the marked product can be prepared for marking by preliminary applying an additional composition to it. In this case, the viscosity of the composition, its adhesion to the marked surface and the method of its application are selected in such a way that the additional composition levels the surface irregularities and inhomogeneities of the marked part.

To improve the operational properties of the manufactured markings, they can be further protected. MPN can be protected by applying a protective coating (varnish) and / or gluing a single or multilayer protective film, which can be transparent in the visible wavelength range and allow MPN to be read without removing it. When using a multilayer protective film, the reading of MPN can be repeatedly restored by sequentially removing the layers of the protective film. This will remove coatings, paint, other contaminants and traces of impacts on the marked part of technological operations and other adverse factors. It is only required that such influences do not violate the integrity of the protective coating.

The properties of the applied layers (including additional and / or protective) can be modified in one way or another, for example, by drying, thermo- or photo-polymerization.

The aim of the invention is to obtain a wide range of direct application markings with desired properties by sequentially introducing materials, particles, compositions, substances into their information elements using multiple needle-impacts. In addition, the purpose of the invention is to increase resistance to external influences, expanding the possibilities of introducing particles with the necessary properties into information elements, and improving the operational properties of direct application markings due to the use of plastic deforming metals or alloys in their manufacture.

Technical result:

- Obtaining a wide range of direct application markings with desired properties by sequentially introducing materials, particles, compositions, substances, using repeated needle-impact impacts;

- increasing the resistance to external influences, expanding the possibilities of introducing particles with the necessary properties into information elements, and improving the properties of direct application markings due to the use of plastic deforming metals or alloys in their manufacture;

- improving the manufacturing technology of MPN through the use of technological methods based on repeated needle-shock effects, and the needle-shock effects are proposed to be used not only for the formation of recesses in the material of the marked part, but also for introducing particles, compositions or substances having these necessary properties.

The technical result can be implemented in a number of ways, some of which are defined in the text of the proposed patent claims.

The technical result is achieved, in particular, by the fact that in the manufacture of IU-MPN, after the primary needle-impact action, additional material is placed, in particular, multilayer, between the needle of the needle-drum set and the surface of the marked part.

As layers of such a material, carrier layers can be used that provide sufficient mechanical strength of the material — in particular, metal and / or alloy foils, polymer films, porous materials, and fabrics. If necessary, such layers can be further hardened, for example, reinforced with a polymer or metal mesh, which prevents tearing of the material after a needle-impact and facilitates its removal after use in the application of IU-MPN.

In addition, as layers of additionally placed material, compositions can be used, in particular polymeric ones containing substances having certain properties. The substances introduced into the material can, in particular, ensure decodability of the IU-MPN, prevent unauthorized access to the information contained in the IU-MPN, and contribute to the consolidation of the compositions forming the IU-MPN in the recesses in the material of the marked part.

The material placed between the needle of the needle-drum set and the surface of the marked part is fixed on the surface of the part, for example by gluing and / or by mechanical pressing and / or rolling. This is necessary to ensure sufficient accuracy of localization of effects on the marked part during subsequent operations.

Then, the following needle-impact action is carried out, and with multiple needle-impact actions, various materials can be sequentially placed in such a way, fragments of which are successively moved to the recesses forming the information elements of the MPN.

The technical result is achieved, in addition, by the fact that in order to contrast the IE MPN before its authorized reading and the difficulty of unauthorized reading, structures are formed in the IE that differ in certain properties. In particular, in the manufacturing process of markings, IEs can be created from the marked surface:

- in the reflection coefficients and / or absorption and / or in the fluorescence spectra and / or in the fluorescence excitation spectra in a certain wavelength range of one of the regions of the electromagnetic radiation spectrum, for example, X-ray, microwave, UV, IR, visible;

- in physical properties, in particular - magnetic, electrical conductivity, triboelectric or electrical insulating properties;

- in the physicochemical and / or chemical properties, in particular adhesive, hydrophilic-hydrophobic, the ability to induce catalytic or autocatalytic and / or radical chain processes, and / or sorption, polycondensation processes.

In the process of implementing the technical result, in order to enable marking on the surface, rough, mechanically insufficiently strong, deteriorating with time or during the operation of the marked part, an additional composition is applied to the marked surface. This composition is applied before the formation of the information elements of the IU-MPN. The properties of the additional composition can be modified by introducing reactive substances into it, for example, in order to increase the adhesion of the composition to the surface of the marked part or to form an insoluble spatially crosslinked structure on its basis.

Appropriate processes can be carried out with the participation of external influences - heating and / or irradiation with UV and / or IR radiation, and / or microwave and / or laser radiation, corona discharge, exposure to oxidizing agents, reducing agents. With the help of appropriate additives, other properties of the additional composition may be modified. In particular, the optical properties of the composition can be changed in order to increase the optical contrast of the IE IU-MPN with respect to the surface of the marked part.

In the process of implementing the technical result, a protective composition may be applied to improve the operational properties of the manufactured markings. The protective composition is applied at the end of the manufacturing process of the MPN if it is necessary to protect the information elements of the manufactured marking from external influences during operation and / or from unauthorized reading. In order to prevent unauthorized reading of MPN, additives containing the necessary properties can be added to the composition of the protective composition.

For the same purpose, instead of applying protective compositions to MPI, polymer films (including multilayer films) can be glued.

The invention is illustrated by drawings.

The following notation is used in the figures:

1 - structures filling information elements formed by the repeated successive introduction of materials, particles, compositions, substances, using needle-impact effects;

2 - additional composition;

3 - marked part;

4 - a material containing particles, compositions or substances having the necessary properties;

5 - a protective coating.

In FIG. 1 shows the IU-MPN device, consisting of ordered recesses on the surface of the marked part (3). Before the formation of the marking information elements, an additional composition (2) is applied to the marked surface, leveling the surface roughness of the marked part (3) and / or increasing the optical contrast of the subsequently formed information marking elements.

The structures filling the information elements (1) are formed by the repeated successive introduction of materials, particles, compositions, substances, using needle-impact effects.

The IU-MPN is coated with a protective coating (5), which is a polymer composition and / or a polymer film (in particular, multilayer). If the reading of the IU-MPN was intentionally blocked or became difficult for other reasons, the removal of the protective coating may provide the ability to restore the decoding of the IU-MPN.

FIG. 2 illustrates the implementation of one of the needle-impacts, which sequentially form the information elements of the marking. The manufacturing process of IE consists in the formation of structures having the necessary properties (1), by repeatedly introducing fragments of materials, particles, compositions, substances, using needle-impact effects.

For this, a material (4) containing particles, compositions or substances having the necessary properties is placed between the needle of the needle-drum set and the surface of the marked part.

As such a material, it is convenient to use a two-component structure consisting of a carrier that provides the necessary mechanical qualities of the material and ease of use, and a polymer layer or impregnation containing particles, compositions, substances with the necessary properties. The carrier may be metal or alloy foils, polymer films, fabrics or non-woven materials made from natural or synthetic fibers.

The material placed between the needle of the needle-drum set and the surface of the marked part must be fixed on the surface of the marked part in a way that ensures the necessary accuracy of localizing the effects on the marked part, for example, by gluing, rolling, mechanical pressing.

Before the formation of the marking information elements, an additional composition (2) is applied to the marked surface, leveling the surface roughness of the marked part (3) and / or increasing the optical contrast of the subsequently formed information marking elements.

In FIG. 3 presents the IU-MPN with a protective coating (5), which is a polymer composition and / or a polymer film (in particular a multilayer).

FIG. 3 illustrates the irradiation of a protective coating (5) with UV or IR radiation. Such irradiation can be applied to achieve the following goals.

First, the purpose of irradiation can be to give the protective coating the necessary hardness or consistency by drying it and / or inducing its polymerization.

Secondly, irradiation can be used to restore the decoding of MPN by photo-induced decomposition of the protective coating itself or by changing the properties of the substances contained in it that block the decoding of MPN (in this case, the change in the properties of substances can be reversible).

Claims (13)

1. A method of manufacturing a direct application marking (MPN), consisting of information elements (IE) on the surface of the marked part, including the formation of recesses by needle-impact on the surface of the marked part, characterized in that after the primary needle-impact before subsequent needles shock between the needle of the needle-drum set and the surface of the marked part additionally place a material different from the material of the surface of the marked part, and spend the next needle-ud molar impact, with mentioned operation is repeated sequentially moving the material in the recesses or different materials to form information elements PHM. 2. The method according to p. 1, characterized in that each subsequent cycle of the needle-impact impact is carried out with the impact force of the needle of the needle-drum assembly, different from the impact force of the needle during the primary cycle of the needle-impact impact. 3. The method according to p. 1, characterized in that the material, which in the manufacture of MPN is additionally placed between the needle of the needle-drum set and the surface of the marked part, is fixed on the surface of the marked part by gluing and / or by mechanical pressing and / or rolling. 4. The method according to p. 1, characterized in that as a material different from the surface material of the marked part, which is additionally placed between the needle of the needle-drum set and the surface of the marked part in the manufacture of MPN, a foil of plastic deforming metal or alloy is used, selected from aluminum, copper, gold, lead, tin, antimony, brass, bronze or duralumin, and the foil contains at least one additive that gives IE properties that differ from the corresponding properties of the material marked hoists. 5. The method according to p. 1, characterized in that as a material other than the material of the surface of the marked part, which in the manufacture of MPN is additionally placed between the needle of the needle-drum set and the surface of the marked part, use a fabric or non-woven material from natural or synthetic fibers containing at least one additive that gives IE properties that differ from the corresponding properties of the material of the marked part. 6. The method according to p. 1, characterized in that as a material other than the material of the surface of the marked part, which in the manufacture of MPN is additionally placed between the needle of the needle-drum set and the surface of the marked part, use a polymer film obtained by curing a polymer composition based on acrylic, epoxy, urethane, organosilicon, alkyd, or polyester polymers containing at least one additive that gives IE properties that differ from the corresponding properties of the mark material Rui details. 7. The method according to p. 1, characterized in that the material, which during the production of MPN is successively moved to the recesses with the formation of information elements MPN, differs from the material of the marked part in the fluorescence spectrum, and / or the fluorescence excitation spectrum, and / or reflection coefficient , and / or the absorption coefficient of electromagnetic radiation in at least one range of their spectrum, such as x-ray, microwave, UV, IR, or visible. 8. The method according to p. 1, characterized in that the material, which during the manufacturing of MPN is successively moved to the recesses with the formation of information elements of MPN, differs from the material of the marked part in electrical conductivity, magnetic, electrical insulation, triboelectric, adhesive, or hydrophilic-hydrophobic properties , or differs in its ability to induce catalytic, autocatalytic, radical chain processes, sorption, or polycondensation processes. 9. The method according to p. 1, characterized in that the material, which is additionally placed between the needle of the needle-drum set and the surface of the marked part, in the form of a polymer film, non-woven material, fabric or metal or alloy foil, is pre-hardened by gluing on a durable film or reinforcing with a polymer or metal mesh, to ensure that it does not break during the needle-impact process and facilitate its removal after the application of MPN. 10. The method according to p. 1, characterized in that they use a multilayer material, which in the manufacturing process MPN is additionally placed between the needle of the needle-drum set and the surface of the marked part. 11. The method according to p. 1, characterized in that before the formation of the information elements of the MPN, an additional composition is applied to the marked surface, the viscosity of the composition, its adhesion to the marked surface and the application method selected in such a way that the additional composition eliminates surface irregularities and inhomogeneities of the marked part . 12. The method according to p. 1, characterized in that at the end of the manufacture of MPN to protect its IE from external influences during operation, MPN is coated with a protective coating and / or a protective multilayer film is glued. 13. The method according to p. 1, characterized in that after each application to the marked part of the material, it is dried or cured using blowing, heating, or irradiation with UV and / or IR radiation.

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