RU2698736C1 - Method of producing amorphous metal fibers - Google Patents

Abstract

FIELD: manufacturing technology; methods of protecting documents.

SUBSTANCE: invention relates to protection of valuable counterfeit documents. Disclosed is a method of producing amorphous metal fibers, which uses a Ulitovsky-Taylor apparatus, which includes the following steps: 1) formation of amorphous metal fibers by induction casting on said plant, 2) gluing the obtained fiber into bundles by means of a water-soluble adhesive, and 3) cutting the bundles into pieces of a given length, characterized in that the apparatus in addition is provided with a capacitive sensor included in the negative feedback system, and is configured to vary the winding speed of the cast fiber depending on the measured conductivity of the cast fiber.

EFFECT: ensuring stability of electrotechnical properties of cast fiber.

9 cl, 1 ex

Description

FIELD OF TECHNOLOGY

The invention relates to the field of protection of valuable documents from counterfeiting and describes a method for the manufacture of amorphous metal fibers intended for instrumental determination of the authenticity of protected media, such as forms and documents with copy protection, banknotes, securities, labels, excise and postage stamps, payment, identification and travel documents, as well as plastic cards and access keys.

BACKGROUND

It is known from the prior art that magnetic elements based on fibers from amorphous-metal alloys, which have the property of magnetically reversing magnetically under the influence of an applied magnetic field (“Barkhausen effect”), are used as security tags for authenticating documents. The abrupt remagnetization of amorphous metal fiber is accompanied by the emission of an electromagnetic pulse, which allows reliable non-contact, remote control of the authenticity of the protected medium. By changing the morphology (geometric dimensions) of the magnetic elements, their number in the label, as well as the properties of their material, it is possible to achieve a given combination of the ratio of intensities and phases of electromagnetic pulses that are emitted by the label under the influence of an external magnetic field. In turn, this allows encoding and / or identification of protected objects - information carriers.

Thus, by varying the chemical composition of the alloy and the size of the microwires, it is possible to construct protective labels with desired properties, characterized by the ratio of intensities and phases of the emitted electromagnetic pulses following exposure to an external alternating magnetic field. Moreover, the set of phases and ratios of the intensities of the pulses can be considered as a “key” or “code” used to identify the medium containing the label.

A security (identification) label is understood to mean a device, at least one of whose elements is a magnetic element made of a ferromagnetic alloy, having a certain geometric shape and predetermined magnetic properties, and serving as a hallmark or identifier.

The traditional method of manufacturing fibers (wires) from amorphous metal alloys described in the sources consists in ultrafast cooling (up to 1 million ° C per second) of a wire, when it is pulled out of the melt through a die at the stage of material formation.

A complete technological process for the manufacture of a wire suitable for use as a mark in determining the authenticity of an information carrier consists in heating the alloy located in a glass tube to the melting temperature, overheating the obtained melt, and then drawing it into the capillary tube and rapidly cooling it. Next, the wire is cut into pieces, which are used as label elements, and, if necessary, glued into briquettes with water-soluble glue - for ease of transportation and use.

A number of technical solutions are known that use amorphous metal fibers as tags in electronic systems for monitoring objects, in keys of access systems, and also as elements for determining authenticity.

From international publication WO 02082475, labels are known which are a piece of a microwire made of an amorphous metal alloy based on cobalt; the microwire contains a core of a ferromagnetic alloy consisting of cobalt, iron, manganese, boron and silicon selected in different percentages, exhibits magneto-stable properties during magnetization reversal and is characterized by an almost rectangular hysteresis loop. The microwire core is covered with a glass shell, the diameter of which is in the range from 5 to 35 microns. The microwire is fabricated by heating the alloy located in the glass tube to a melting point at which the tube material softens, the alloy overheats, and then the softened tube is pulled into the capillary tube and then the capillary tube is cooled with the alloy. Next, the microwire is cut into segments that are used as magnetic elements of the labels. In the manufacturing process, depending on the applicable time and temperature conditions, an alloy having an amorphous, amorphous-crystalline, microcrystalline or fine crystalline microstructure can be obtained.

A disadvantage of the known labels is that the coding units made of these fibers do not have the required stability of their electrophysical (magnetic) properties, and, as a result, the sufficient reliability of registration due to the absence of any control of conductivity during fiber casting.

A known method of manufacturing an amorphous magnetic alloy wire, comprising placing a metal billet in a glass tube, melting the metal billet together with the tube, drawing the metal melt in the form of a metal wire coated with a glass layer, cooling to produce an amorphous alloy wire coated with a glass layer, removing the surface of the wire layer of glass (RF patent for the invention No. 2430433). The removal of the glass layer is carried out by pulling the wire along the curved surface of the solid body across the generatrix of the curved surface with a radius of curvature, providing a tensile stress in the glass layer equal to or greater than its tensile strength and tensile stress in the wire during bending while stretching across the generatrix of the curved solid surface in the range of the tensile strength of the glass and the elastic limit of the amorphous alloy of the wire.

The stability of the electrophysical (magnetic) properties of known fibers is insufficient for reliable recording, due to the absence of any control of conductivity during fiber casting.

For the same reason, the labels described in the published application of the Russian Federation for the invention No. 2003101292 and 2007111536, as well as in the patent of the Russian Federation for the invention No. 22219299, do not have sufficient stability.

A known method of manufacturing an amorphous alloy wire, comprising placing a metal billet in a glass tube, melting a metal billet, drawing a metal melt in the form of a metal wire coated with a glass layer, cooling the wire alloy while maintaining the amorphous state of the wire alloy coated with a glass layer, removing the glass layer from the surface amorphous alloy wire. Removing a glass layer from the surface of an amorphous alloy wire is performed by pulling an amorphous alloy wire coated with a glass layer along a curved surface of a solid body across a generatrix of a curved surface (published RF application for invention No. 2009138455).

In addition to the drawback already noted above, due to the lack of conductivity control, this solution does not describe the process and method of forming a security label, including more than one coding element based on microwires with different magnetic properties.

The closest analogue is the magnetic element of the identification mark made in the form of at least one piece of microwire with almost zero magnetostriction, having a ferromagnetic alloy core coated with a glass sheath (US patent No. 6441737). This microwire is made of cobalt-based alloy with different percentages of Co, Fe, Mn, B, and Si, which leads to its various microstructure. The magnetic element is made by casting a microwire from a melt having a ferromagnetic alloy core coated with a glass shell, and cutting the microwire into pieces. Labels are formed from the obtained segments of the microwire, using one segment or several segments connected in different ways.

The disadvantage of the aforementioned analogue, as well as the general disadvantage of all the aforementioned labels, is that coding units made of amorphous metal fibers do not possess the required stability of their electrophysical (magnetic) properties due to the absence of conductivity control in the proposed methods for manufacturing fibers, which is expressed in practice at insufficiently high signal levels and different response times of the magnetic element to the influence of an external magnetic field, which limits the detection zone of the label, nyaet its registration and increases the likelihood of errors.

As a result, the methods for producing amorphous metal fibers proposed in the known solutions do not allow the creation of a stably working security label with a code formed by elements based on data with given amplitudes and signal repetition phases when exposed to an alternating magnetic field.

SUMMARY OF THE INVENTION

A feature of the proposed technical solution, which allows expanding the number of varieties of unique security labels for various groups of documents and goods, is the use of a set of elements with different, but strictly specified magnetic properties as part of a single security label, forming a given identification code inherent in only one group of products. In this case, the security label, in essence, forms a coding unit, and the composition and content of the code is established during the manufacture of the security label and cannot be changed or destroyed.

The purpose and objective of the present invention is to develop an improved method for producing fibers, which provides a material with increased stability of specified electrophysical properties, which allows you to provide a given sequence of pulses when forming coding elements from fibers, allows you to create identification tags with increased registration reliability.

The problem is solved due to the fact that the proposed method for producing amorphous metal fibers, which use the Ulitovsky-Taylor installation, which includes the following steps:

1) the formation of amorphous metal fibers by induction casting on the said installation,

2) bonding the obtained fiber into bundles by means of a water-soluble glue, and

3) cutting the bundles into segments of a given length, characterized in that it

said installation is additionally equipped with a capacitive sensor included in the negative feedback system, and is configured to change the winding speed of the cast fiber depending on the measured conductivity of the cast fiber, thereby ensuring the stability of the electrical properties of the latter.

As will be understood from the above, the problem is solved mainly by introducing a deep negative feedback element into the composition of the known induction casting unit, which regulates the speed of winding of the cast fiber depending on the signal value of the capacitive conductivity sensor.

As for bonding with water-soluble glue, this stage is intended to simplify the cutting of fibers (or bundles / flat structures made by gluing fibers with water-insoluble glue) into segments of a given length, after which the water-soluble glue can be removed.

In one embodiment of the above method, before the aforementioned step 2, a predetermined number of the aforementioned fibers with predetermined electrical properties are glued longitudinally into bundles or flat structures with a water-insoluble adhesive composition, thereby forming coding elements.

The aforementioned fibers, in one embodiment of the above method, can be made on the basis of an iron-cobalt alloy containing chromium, boron and silicon, or on the basis of an iron-nickel alloy containing phosphorus, boron and sulfur.

Another object of the present invention, which solves the problem, is an identification tag containing segments of amorphous metal fibers made as described above.

The above label, in one particular embodiment, can be made in the form of coding units formed by a given number of amorphous metal fibers with desired properties, which are connected in the form of a bundle, or a flat structure by longitudinal gluing with an insoluble adhesive in water.

The aforementioned identification mark, in one particular embodiment, is made visually indistinguishable when observing a reflection under normal lighting.

Another object of the present invention that solves the problem is a storage medium, characterized in that it contains at least one identification tag according to any one of paragraphs. 4-5.

The aforementioned identification marks, in one particular embodiment, are arranged uniformly randomly in the entire volume of the medium, or uniformly in the form of a strip with a width of 1 to 100 mm without inclusion in the volume of the medium in its remaining sections.

The aforementioned medium, in one particular embodiment, is a copy-protected document selected from the group consisting of a banknote, excise stamp, postage stamp, passport, travel document, driver's license, identification card, security paper, plastic card, label and payment document.

The proposed invention is illustrated by examples.

DETAILED DESCRIPTION OF THE INVENTION

Example 1

A method of obtaining a stranded beam for use in the identification tag

The fibers were formed by induction casting at the Ulitovsky-Taylor installation.

To ensure the stability of the electrical properties of the fiber, the installation has a built-in negative feedback system, including a microprocessor controller, a capacitive sensor, and a pulse-width (PWM) converter, which provides adjustment of the speed of winding of the cast fiber to the receiving reel depending on the measured conductivity of the cast fiber.

One of the fibers has a core diameter of 10 μm, and the second is 20 μm, both veins are made on the basis of iron-cobalt alloy with the content of components, wt. %:

With 49.5; Fe 50.0; Cg 0.2; AT 0.1; Si 0.2.

In both fibers, the metal core has a shell of fusible glass with the following components, wt. %:

Bi ₂ O ₃ 42.0; Pbo 38.0; Zno 12.0; SiO ₂ 2.0; B ₂ O ₃ 6.0.

For use in the further technological process, these multicore bundles of two fibers are glued into bundles of 5 mm length with BF-2 water-soluble adhesive based on polyvinyl styrene.

Based on multicore beams, identification marks are made that are uniformly and randomly placed over the entire surface of the paper medium and are not visible to the naked eye when observing reflection in diffuse lighting.

A valuable document in the form of a banknote is made on said medium.

The introduction of feedback allows you to get fibers with stably reproducible properties, reduces the percentage of marriage.

Claims (13)

1. A method of producing amorphous metal fibers, which use the installation of Ulitovsky-Taylor, which includes the following steps: 1) the formation of amorphous metal fibers by induction casting on the said installation, 2) bonding the obtained fiber into bundles by means of a water-soluble glue and 3) cutting the bundles into segments of a given length, characterized in that it said installation is additionally equipped with a capacitive sensor included in the negative feedback system, and is configured to change the winding speed of the cast fiber depending on the measured conductivity of the cast fiber, thereby ensuring the stability of the electrical properties of the latter. 2. The method according to p. 1, characterized in that in it before the aforementioned step 2, a predetermined number of the aforementioned fibers with desired electrical properties are glued longitudinally into bundles or flat structures with a water-insoluble adhesive composition, thereby forming coding elements. 3. The method according to any one of paragraphs. 1 or 2, characterized in that in it the aforementioned fibers are based on an iron-cobalt alloy containing chromium, boron and silicon, or on the basis of an iron-nickel alloy containing phosphorus, boron and sulfur. 4. Identification mark, characterized in that it contains segments of amorphous metal fibers made according to any one of paragraphs. 1-3. 5. The label according to claim 4, characterized in that it is made in the form of coding blocks formed by a predetermined number of amorphous metal fibers with predetermined properties, which are connected in the form of a bundle or a flat structure by longitudinal gluing with an insoluble adhesive in water. 6. The label according to claim 4, characterized in that it is made visually indistinguishable when observing the reflection under normal lighting. 7. A storage medium, characterized in that it contains at least one identification tag according to any one of paragraphs. 4-6. 8. The medium according to claim 7, characterized in that the aforementioned identification marks are arranged uniformly randomly throughout the volume of the medium or uniformly in the form of a strip with a width of 1 to 100 mm without inclusion in the volume of the medium in its remaining sections. 9. The media according to any one of paragraphs. 7 or 8, characterized in that it is a copy-protected document selected from the group consisting of a banknote, excise stamp, postage stamp, passport, travel document, driver's license, identification card, security paper, plastic card, label and payment document.