RU2634829C2 - Method of protection, including renewable one, marking of direct application from external exposure and unauthorized reading - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to methods for applying direct application markings (DAM) directly onto a markable object. The method for protecting the surface-based direct application marking (DAM) from external exposure during operation involves applying a protective coating on the DAM in the form of, at least, one protective film on a polymer base, while a protective composition comprising a mixture of organic solvents in an amount of 50-55% of the total weight of the protective composition, a mixture of acrylic polymers in an amount of 40-45% of the total weight of the protective composition, coalescent in an amount of up to 2.5% of the total weight of the composition in the form of butyl glycol acetate, less than 0.3% of the total weight of the composition of each of the cellulose thickener, defoamer, biocide, not more than 20% of the total weight of the protective composition of the additive having protective properties, in the form of a dye, fluorescent pigment or filler dispersing light in the form of fine fractions of chalk, titanium oxide or barium sulphate, are used as a material of the protective film. The said mixture of organic solvents consists of 72% of a high boiling solvent in the form of methyl- or ethyl-cellosolve, 17% of a solvent with an average boiling point in the form of toluene or butyl acetate and 11% of a light boiling solvent in the form of acetone or diethyl ether.

EFFECT: protection of direct application markings from external exposures and unauthorized reading and recovery, including - repeatedly, decoding of the protected direct application marking, reading of which ceased or became difficult.

9 cl, 4 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 applying markings directly to 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 acoustical application, laser application (several types), electrospark application and application 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). In addition, 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 structure (ie, on / off - design). There are many varieties of 2D codes (e.g. PDF 417, 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 polarization and frequency parameters of which are protective signs to identify the authenticity of the object.

The use of fluorescence, its spectral and polarization parameters as identification and protective features are 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 the 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. [ʺAIM DPM Verification of Dot Peen Data Matrix Symbols on small curved surfacesʺ, by Ron Page] proposes to fill the acupuncture marking holes with black or white ink to improve image quality.

Filling IE MPN with a polymer 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 slightly increases the 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 recesses formed by 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 ranges. 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.

The manufacturing methods of fluorescence MPN set forth in this patent are applicable to the implementation of the claimed invention. However, the solution under consideration does not imply the restoration of the possibility of stable decoding of MPN after mechanical damage, chemical and / or radiation, and / or thermal effects, due to insolation or UV irradiation, as a result of technological operations - for example, coating or painting, as well as intentional introducing certain interference. Accordingly, both methods of protecting markings from unauthorized access to the information contained in protected MPN and methods for ensuring authorized access to it are not offered.

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

Further expansion of the scope of practical application of MPN requires the improvement of protection methods, including renewable,

markings of direct drawing from external influences and unauthorized reading.

The solution to this problem is provided by the claimed method.

SUMMARY OF THE INVENTION

The essence of the invention lies in the fact that a method is proposed for protecting direct application markings (MPN) from external influences during operation, including applying protective layers and / or coatings to MPN (or its information elements). In this case, the task of choosing the composition of protective coatings, methods of their application and methods of their processing is to ensure the possibility of recovery, including multiple, decoding MPN. The reading of MPN, the decoding of which is to be restored, is terminated during the operation of the marked product or is deliberately blocked to limit access to the information encoded in the marking. The external influences from which MPNs are protected include, in particular, an attempt to unauthorized access to information encoded in the marking.

To implement the essence of the invention, a method for the protection of MPN is proposed — applying one- or multi-layer coatings to it, cured by drying and / or photo and / or thermopolymerization, with layers of the same or different composition.

To do this, before MPN, polymer compositions containing:

- a mixture of organic solvents in an amount of 50-55% of the total mass of the protective composition, consisting of 72% of a high boiling solvent in the form of methyl or ethyl cellosolve, 17% of a solvent with an average boiling point in the form of toluene or butyl acetate and 11% of a low boiling solvent in the form of acetone or diethyl ether;

- a mixture of acrylic polymers in an amount of 40-45% of the total mass of the protective composition;

- coalescent in an amount up to 2.5% of the total weight of the composition in the form of butyl glycol acetate;

- less than 0.3% of the total weight of the composition of the cellulose thickener, antifoam, biocide;

- not more than 20% of the total weight of the protective composition of the additive having protective properties in the form of a dye, fluorescent pigment or filler scattering light in the form of finely divided fractions of chalk, titanium oxide or barium sulfate.

Protective polymer compositions are applied to the MPN before starting its operation in at least one layer using a roller, tampon, brush, squeegee or spraying pneumatically or aerosolly.

The layers of the protective polymer composition that are opaque or have lost transparency due to contamination or mechanical damage are peeled or peeled off before decoding the MPN, after which, if the need for protection of the MPN remains, they are applied again. This will also remove coatings, paint, other contaminants, as well as traces of mechanical stress on the marked part. It is only required that such influences do not violate the integrity of the protective coating.

Transparent or translucent protective layers by themselves do not interfere with the decoding of MPN. They can also be updated if necessary.

The choice of a specific composition and method of applying the layers of the protective coating allows you to adjust their properties, in particular - viscosity, hydrophilicity, mechanical resistance, resistance to solvents, adhesive properties, transparency in a particular spectral region. The properties of the applied layers can also be modified during their curing in one way or another, for example, by drying, thermo- or photopolymerization, and the final consistency of the layers can be jelly-like, resinous or solid. To increase the resistance of MPN to pollution, aggressive agents and mechanical damage, the protective coating can be applied layer by layer, up to creating a solid and flat surface on the MPN.

Application of a protective layer (s) to the MPN can be used to prevent unauthorized reading of all or part of the information contained in it. To prevent unauthorized reading of MPN, protective layers and / or coatings containing the above additives with protective properties can be applied to it.

In the absence of decoding MPN due to insufficient transparency of the protective coating, to restore decoding MPN coating can be mechanically cleaned or removed by dissolution or decomposition. One of the options for mechanical action on the protective layers can be the alternation of the sticker on the MPN and the separation of the polymer film with adhesive.

If the mechanical cleaning of the protective coating was not enough to restore its transparency, the transparency of the coating can be restored by applying a new coating layer of the above composition or a transparent lubricant such as castor oil, petroleum jelly on a hydrocarbon or silicone base, transparent polymer varnish.

Note that the geometric configuration of the protective layer can serve as an identification sign of the authenticity of the corresponding MPN. In this case, protective coatings of various geometries can be applied locally to some part of the MPN or to some information elements of the MPN. This can provide ranking of access to marking information, in particular, for this, various groups of protected elements of MPN can have protective coatings of various compositions.

The objective of the invention is to enable recovery of decoding MPN, the reading of which ceased during operation or was deliberately stopped. For this, it is proposed to use single or multilayer protective coatings, the composition of which and the processing methods are given in the claims and are an important part of it.

The technical result of the invention is the restoration of decoding MPN, the reading of which ceased during operation or was deliberately stopped.

The technical result consists in the fact that as a result of the preliminary application of the protective polymer composition on the MPN, it becomes possible to restore the decoding of the MPN, the reading of which ceased during operation or was deliberately stopped.

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

To achieve a technical result, MPNs are coated with single or multilayer coatings, cured by drying and / or photo and / or thermopolymerization, with layers of the same or different composition.

To do this, before MPN, polymer compositions containing:

- a mixture of organic solvents in an amount of 50-55% of the total mass of the protective composition, consisting of 72% of a high boiling solvent in the form of methyl or ethyl cellosolve, 17% of a solvent with an average boiling point in the form of toluene or butyl acetate and 11% of a low boiling solvent in the form of acetone or diethyl ether;

- a mixture of acrylic polymers in an amount of 40-45% of the total mass of the protective composition;

- coalescent in an amount up to 2.5% of the total weight of the composition in the form of butyl glycol acetate;

- less than 0.3% of the total weight of the composition of the cellulose thickener, antifoam, biocide;

- not more than 20% of the total weight of the protective composition of the additive having protective properties in the form of a dye, fluorescent pigment or filler scattering light in the form of finely divided fractions of chalk, titanium oxide or barium sulfate.

Protective polymer compositions are applied to the MPN before starting its operation in at least one layer using a roller, tampon, brush, squeegee or spraying pneumatically or aerosolly.

The technical result is achieved in that in order to protect MPN on MPN before its operation one-or multi-layer coatings are applied, cured by drying and / or photo and / or thermopolymerization, with layers of the same or different composition.

Single-layer coatings can be both opaque and transparent or translucent in the visible wavelength range. The opaque layers are removed by decoding the MPN, after which, if the need for protection of the MPN remains, they are applied again. Transparent or translucent layers of protective coating are removed if they become dirty or damaged. If it is necessary to maintain MPN protection, they can be updated.

When using a multilayer transparent polymer protective coating, the reading of MPN can be repeatedly restored by sequentially removing the layers. This will also remove coatings, paint, other contaminants, as well as traces of mechanical stress on the marked part. It is only required that such influences do not violate the integrity of the protective coating.

In order to achieve a technical result, in each particular case, the composition and method of applying the protective coating layers are selected. This allows you to adjust their properties, in particular - viscosity, hydrophilicity, mechanical resistance, resistance to solvents, adhesive properties, transparency in a particular region of the spectrum. The properties of the applied layers can also be modified during their curing in one way or another, for example, by drying, thermo- or photopolymerization, and the final consistency of the layers can be jelly-like, resinous or solid. To increase the resistance of MPN to pollution, aggressive agents and mechanical damage, the protective coating can be applied layer by layer, up to creating a solid and flat surface on the MPN.

In the absence of decoding MPN due to insufficient transparency of the protective coating, to restore the decoding MPN coating layers can be mechanically cleaned or removed by dissolution or decomposition. One of the options for mechanical action on the layers of the protective coating can be the alternation of the sticker on the MPN and the separation of the polymer film with adhesive.

If the mechanical cleaning of the protective coating was not enough to restore its transparency, the transparency of the coating can be restored by applying a new coating layer of the above composition or a transparent lubricant such as castor oil, petroleum jelly on a hydrocarbon or silicone base, as well as a transparent polymer varnish.

Note that the geometric configuration of one or more layers of the protective coating can serve as an identification sign of the authenticity of the corresponding MPN. At the same time, layers of protective coatings of various geometries can be applied locally to some part of MPN or to some information elements of MPN. This may provide ranking of access to labeling information.

The invention is illustrated by drawings.

In FIG. 1-4 the following notation is used:

1 - fluorescent polymer composition;

2 - additional composition;

3 - marked part;

4 - a protective coating.

In FIG. 1 shows a 3-MPN device consisting of ordered recesses and / or microcracks, and / or surface roughness of a 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.

A protective coating (4) is applied to the Z-MPN, which is a polymer composition (in particular, a multilayer one). If the reading of the Z-MPN was blocked intentionally or became difficult for other reasons, the protective coating with the specified properties will enable the restoration of decoding of the Z-MPN, including multiple decoding.

In FIG. 2 shows a 3-MPN device consisting of ordered depressions and / or microcracks and / or surface roughnesses of a 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.

A protective coating (4) is locally applied to the information elements of the Z-MPN, which is a polymer composition with desired properties. If the reading of the Z-MPN was blocked intentionally or became difficult for other reasons, the protective coating will provide the ability to restore decoding of the Z-MPN, including multiple.

In FIG. Figure 3 shows a 3-FMPN device consisting of information elements formed by filling cavities and / or microcracks and / or surface roughnesses of a marked part (3) with a fluorescent composition (1) that absorbs light radiation at wavelengths of UV, visible and / or near IR -bands and radiating in the wavelength range of the passband of the input filter of the reader. 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.

A protective coating with predetermined properties (4) is applied to the Z-FMPN, which is a polymer film (in particular, a multilayer film) and / or a polymer composition.

In FIG. 4 shows a 3-FMPN device consisting of information elements formed by filling indentations and / or microcracks and / or surface roughnesses of a marked part (3) with a fluorescent composition (1). 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. A protective coating (4) is applied to the Z-FMPN, which is a polymer composition and / or a polymer film (in particular, a multilayer film).

The protective coating is exposed to UV or IR radiation. Such exposure can be used to achieve one of two goals.

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

Secondly, radiation can be used to restore the decoding of 3-FMFN 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 3-FMFN (in this case, the change in the properties of the substances can be reversible).

Claims (9)

1. A method of protecting a direct application marking (MPN) formed on a surface of a product from external influences during operation, comprising applying a protective coating to the MPN containing at least one layer, characterized in that said protective coating is applied in the form of at least one protective film on a polymer basis, while a protective composition containing a mixture of organic solvents in an amount of 50-55% of the total weight of the protective composition, a mixture of acrylic polymer is used as a protective film material s in an amount of 40-45% of the total weight of the protective composition, coalescent in an amount of up to 2.5% of the total weight of the composition in the form of butyl glycol acetate, less than 0.3% of the total weight of the composition of each of the cellulose thickener, antifoam, biocide, not more than 20% of the total weight the protective composition of the additive having protective properties in the form of a dye, fluorescent pigment or filler scattering light in the form of finely divided fractions of chalk, titanium oxide or barium sulfate, while the above mixture of organic solvents consists of 72% high boiling point about a solvent in the form of methyl or ethyl cellosolve, 17% of a solvent with an average boiling point in the form of toluene or butyl acetate and 11% of a low-boiling solvent in the form of acetone or diethyl ether, while the above-mentioned protective coating provides the ability to restore decoding of protected MPN. 2. The method according to p. 1, characterized in that the said at least one film regulates the adhesive properties and viscosity during curing of the applied film by drying, thermo- or photopolymerization, while the final consistency of the film is jelly-like, resinous or solid to ensure the properties of the release agent hydrophilicity or hydrophobicity. 3. The method according to p. 1, characterized in that the said film is applied to obtain a single solid and flat surface that provides MPN with increased resistance to contamination, aggressive agents and mechanical damage, and the adhesion properties and hardness of the coating are controlled by drying the cured film, thermal or photopolymerization. 4. The method according to p. 1, characterized in that when exposed to a marked product technological operations leading to the termination of decoding MPN due to contamination or loss of transparency of the protective coating and not violating the integrity of this coating, to restore the decoding MPN carry out cleaning / polishing the surface of the protective coverings. 5. The method according to p. 1, characterized in that the restoration of the decoding of the MPN is carried out by applying the aforementioned protective coating on the MPN, the reading of which has ceased or has become difficult due to mechanical stresses, including due to scratches or as a result of cleaning / grinding of the surface protective coating. 6. The method according to p. 1, characterized in that said protective film is a film that is transparent in the visible wavelength range and does not interfere with the reading of the decoded MPN, while in the case of exposure to the marked product technological operations leading to the termination of decoding MPN due to contamination or loss of transparency of the protective coating and not violating the integrity of this coating, the reading of the decoded MPN is restored by sequentially removing the layers of the protective film. 7. The method according to p. 1, characterized in that the restoration of the decoding of MPN is carried out by removing contaminants or coatings with a single or multiple sticker on the labeling of a polymer film with adhesive and then removing the film together with coatings and contaminants, with a preliminary exposure to a solvent, plasticizer, oxidizing agent reductant. 8. The method according to p. 1, characterized in that at least one protective coating is applied to a certain geometric configuration, which is an identification sign of the authenticity of the corresponding MPN. 9. The method according to p. 1, characterized in that the protective coating is applied to the information elements of the MPN locally, while for ranking access to marking information, part or parts of the information elements of the MPN are protected.

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