WO2007117178A1 - Étiquette indicatrice - Google Patents

Étiquette indicatrice Download PDF

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Publication number
WO2007117178A1
WO2007117178A1 PCT/RU2006/000574 RU2006000574W WO2007117178A1 WO 2007117178 A1 WO2007117178 A1 WO 2007117178A1 RU 2006000574 W RU2006000574 W RU 2006000574W WO 2007117178 A1 WO2007117178 A1 WO 2007117178A1
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WO
WIPO (PCT)
Prior art keywords
layer
magnetic
indicator
label
resonant circuit
Prior art date
Application number
PCT/RU2006/000574
Other languages
English (en)
Russian (ru)
Inventor
Andrei Vladimirovich Mishin
Anastasiya Mikhailovna Mishina
Anton Andreevich Mishin
Original Assignee
Andrei Vladimirovich Mishin
Anastasiya Mikhailovna Mishina
Anton Andreevich Mishin
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Andrei Vladimirovich Mishin, Anastasiya Mikhailovna Mishina, Anton Andreevich Mishin filed Critical Andrei Vladimirovich Mishin
Priority to PCT/RU2006/000574 priority Critical patent/WO2007117178A1/fr
Publication of WO2007117178A1 publication Critical patent/WO2007117178A1/fr

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Classifications

    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09FDISPLAYING; ADVERTISING; SIGNS; LABELS OR NAME-PLATES; SEALS
    • G09F3/00Labels, tag tickets, or similar identification or indication means; Seals; Postage or like stamps
    • G09F3/02Forms or constructions
    • G09F3/0291Labels or tickets undergoing a change under particular conditions, e.g. heat, radiation, passage of time
    • G09F3/0294Labels or tickets undergoing a change under particular conditions, e.g. heat, radiation, passage of time where the change is not permanent, e.g. labels only readable under a special light, temperature indicating labels and the like

Definitions

  • the Globy indicator label can be used in wholesale and retail trade, in warehousing, transportation of goods, in material and technical supply management systems and product quality control systems.
  • a label - indicator allows you to monitor compliance with product requirements by its shelf life and compliance with the conditions and storage regime of the goods.
  • the indicator label can be used in access control systems with increased security requirements, in wireless transaction systems and various payment applications, acting as an electronic wallet.
  • Label - indicator can also be used to identify the product and to automate accounting. Label - indicator can be placed on the product and packaging, property, documents, CDs, library materials, contactless identification cards of the consumer, etc. PREVIOUS LEVEL.
  • the invention is known "Method of marking, detection and identification of objects", patent RU, JYs 2107324, publ. 1998.03.20, IPC G06K5 / 00, G06K19 / 02, in which there are tags that are irradiated with an external radiation source and then the radiation from the tag is recorded by the detector. Crystals of a substance with magnetic properties are introduced into the label. Moreover, the invention allows to simplify the process of identifying an object, and this process can be made contactless. However, this invention is used only in nuclear physics and is not intended to control product quality.
  • the invention is known “A method for ensuring the quality of blood components using bar codes)), RU patent, N ° 2129882, publ. 1999.05.10, IPC A61M1 / 38, in which a label is printed on the product containing encoded product information and glued onto the product bag.
  • the invention allows to reduce the complexity of the information processing during the procurement and manufacture of product components.
  • the invention solves the problem of eliminating errors during the work of personnel accompanying the product from procurers to consumers, but solves the problem of tracking the storage conditions of products.
  • the invention is known “A method for marking a product or product, or design with subsequent identification (options) and a system for identifying a product or product, or design with the specified marking (options)", patent RU, J ⁇ S 2199781, publ. 2003.02.27, IPC G06K5 / 00, G07D7 / 00, in which products are marked with data containing encoded information or an electronic digital signature. Verification of authenticity is carried out using an identification device configured to convert the recorded data into messages.
  • the invention allows to ensure the practical impossibility of falsification, or replacement, or other unauthorized actions in relation to these goods.
  • the invention does not solve the problem of combining functions while simplifying the design and manufacturing technology for controlling the quality of the goods and at the same time monitoring compliance with the storage conditions of the goods when using contactless information reading systems, as well as the function of automating the input of information.
  • the buyer must be sure that the product is genuine and manufactured without any violations leading to its unsuitability for use, for example, that its moisture content complies with GOST, etc.
  • a label it is required that it also function as an indicator and information carrier for enterprises involved in the process of delivering goods to the consumer. Those. it is required to accumulate information on the movement of goods, their safety, for example, on the presence or absence of unauthorized access to product, on the storage and transportation of this product that do not violate the requirements of the manufacturer.
  • the proposed label indicator provides:
  • Label - the Globik indicator is a combined device, the separate parts of which are structurally combined on the indicator flexible type-setting polymer film plate, includes, in addition to the plate, one or several color indicators and / or microdisplays, at least one or more resonant circuits and a semiconductor circuit.
  • the color indicator or microdisplay has one or several divisions, each of which shows the state of one of the monitored parameters and its qualitative (quantitative) characteristic and occupies an area of one part of the surface of either the magnetic layer itself or the optical device.
  • Each color indicator or microdisplay has a color characteristic in the form of a graphic sign or color background depending on the desired signal that is transmitted to the consumer, equipped with a symbol identifier detector, which in turn consists of an upper active magnetic layer and a lower passive magnetic layer, in which a magnetic pigment penetrated by layers of conductive paint with magnetic properties.
  • Layers of conductive paint made with the inclusion of, for example, magnetic powder, or any ingredient endowed with certain electromagnetic properties.
  • the magnetic layers are made in the form of honeycombs of magnetic powder. The magnetic layers are electrically separated by the polymer layer on which they are placed.
  • the lower passive magnetic layer of the symbol identification detector is made of a polymer structure, which is an insulator, with a magnetic layer placed inside it, and the upper active magnetic layer is made of a honeycomb structure consisting of magnetic powder and conductive paint.
  • the magnetic layers are made of magnetic powder and magnetic pigment with a given ratio of characteristics.
  • the magnetic layers do not touch each other, but the upper magnetic layer is in contact with the membrane of the symbol identifier detector.
  • the magnetic powder of the layers and / or the magnetic pigment of the layers has constant magnetic characteristics over a given period of time relative to a given decay rate during a given period of time of one of the characteristics transmitted by the antenna of the resonant circuit of the semiconductor circuit, and allowing one or another control parameter to be determined.
  • the color indicator on top of the symbol identifier detector may be coated with a protective layer, for example, of a glassy, smooth material.
  • the microdisplay also additionally contains the first reflective and second reflective, opposite layers - optical layers with optical elements where the optical elements are made in the form of blocks of glass microspheres, layer-by-layer embedded in a polymer gasket or in the form of non-contacting metal particles, layer-by-layer embedded in a polymer gasket. Metal particles can also be combined into blocks.
  • both glass microspheres and metal particles are coated with a thin metal layer that provides reflectivity and the ability to glow blocks when ions of charged particles pass through them, and the optical layer as a whole is made of the first and second reflective layers, each of which is made in the form of a discrete layer having a special structure of splashes divided into electrically insulated areas formed from thin-film metal shells deposited on Metal astitsy or glass microspheres, combined into blocks and one layer performs the function of the first reflective layer and second reflective layer is opposite to and has the function of the second reflective layer.
  • each reflective layer is provided on at least those metal particles or blocks of glass microspheres that are located in the region or regions of the antenna or communication antennas of the resonant circuit.
  • the resonant circuit has a resonant frequency equal to the sum of two different modulation frequencies of the radiation of the active radio frequency emitter of the semiconductor circuit, the resonant circuit including a passive radiator that emits a tone-modulated signal at the indicated total frequency, which is a response to the active radio frequency emitter (antenna), and reflects the characteristics of the radio frequency module identification, and an active emitter that emits a duplicate signal.
  • the resonant circuit is made as a spatial structure of an integrated circuit, forming an antenna network consisting of passively active antennas - transponders and placed on an indicator flexible type-setting film plate in each color indicator and microdisplay. A protective layer is applied to the color indicator symbol identification detector and the first optical layer of the color indicator.
  • a non-linear impedance semiconductor circuit for summing radio frequency signals comprises a resonant circuit including an active radio frequency emitter, the radiation of which is modulated in frequency by the two nearest frequencies, equal to the arithmetic average of the frequencies selected for operation in a given range and the receiving antenna, as well as at least one microprocessor in the form of an integrated circuit, a device for storing current information received from each sensor, a comparison unit, a device for storing specified parameters for controlled characteristics and also being a carrier the information required for product identification, the activation matrix in the form of a narrow-band receiver for receiving and demodulating the carrier signal by subtracting the radio frequency a different (RF) signal and its harmonics with the detection of a modulating low-frequency signal (LF), a power supply, a radio frequency identification unit.
  • RF radio frequency a different
  • LF modulating low-frequency signal
  • a polymer gasket for optical elements is, for example, made of glass or plastic or a polymer film or ceramic or mica, made in the form of a plurality of cells, inside which a magnetic powder is placed.
  • the radiation of each resonant circuit can be toned modulated, respectively, by one radio frequency identification module.
  • sensors that can be placed both on the product itself and in the room where the product is stored they can use time switches or temperature sensors or humidity sensors or pressure sensors or other known sensors.
  • the current information storage device receives electromagnetic signals from external sources, which reflect the readings of sensors, which use time relays or temperature sensors or humidity sensors or pressure sensors, and will transfer the signal to internal devices that compare the received signal, distribute, redistribute and identification of these signals.
  • the carrier signals after filtering and comparing data from the device database storing current information with the data base of the device for storing the specified parameters is detected, for example, by signals from sensors previously stored in the device for storing current information that contain digital data falling into the band of a narrow-band receiver that creates a digital data stream and is designed to detect the presence of a passive transponder in the detection zone when the intensity and duration of the signal generated by said transponder and received by said narrowband receiver, will exceed the minimum values of these parameters.
  • the resonant circuit of the color indicator can be performed using transponders.
  • the resonant circuit of the microdisplay can also be performed using transponders.
  • the resonant circuit of the semiconductor circuit can also be performed using transponders.
  • the magnetic layer can be made of any magnetic material, for example, soft magnetic pigment, and metallic inclusions can be made of magnetic powders.
  • the magnetic pigment which is also a magnetic powder with selected magnetic characteristics; also performs the function of a dye with a color that varies depending on the characteristics being monitored.
  • Magnetic pigments depending on the technology of its manufacture, for example, in the synthesis of pigments prepared using alkaline seedless and soda methods for the synthesis of goethite, provide different colors of pigments - yellow, red, brown - red, black. The property to change the color of the pigment.
  • magnetic pigment i.e. material with constant magnetic characteristics for a given period of time and with a given decay rate of a selected characteristic over a given period of time
  • Hc coercive force
  • BR residual magnetization
  • saturation magnetization Bs saturation magnetization Bs depending on the characteristics of the material
  • the label - indicator v can carry out the following functions:
  • an indicator of the freshness of the product (implementation period); - an indicator of compliance with storage conditions, for example, compliance with the storage temperature in a given range, for example, from -40 to + 105 ° C
  • ⁇ - indicator - temperature controller i.e. operating as a semi-passive transponder that continuously monitors temperature changes over time
  • an indicator - a controller of the characteristics of the environment in which the product is stored, for example, humidity, pressure, temperature, etc .;
  • an indicator for personification of a person for example, being a contactless individual card designed to work in access control systems with increased security requirements, in wireless transaction systems and various payment applications, playing the role of an electronic wallet or an electronic document “Personal Identity” ;
  • FIG. 1 - shows the general layout of the label indicator
  • FIG. 2 - a color indicator device is shown (a color indicator opened on a resonant circuit is conventionally shown);
  • FIG. 3 schematically shows the placement of the layers of the identifier of the symbol
  • FIG. 5 - shows a block diagram of the “semi-conductor circuit”
  • FIG. 6 - shows the upper magnetic layer of the symbol identifier
  • FIG. 7 - shows the lower magnetic layer of the symbol identifier
  • FIG. 10 - shows an optical layer with optical elements in the form of metal particles
  • FIG. 11 - shows an optical layer with optical elements in the form of blocks of microspheres
  • FIG. 12 - shows one block of glass microspheres
  • FIG. 13 - shows placement options for individual color indicator divisions, each of which responds to a change in one controlled characteristic: in Fig. 13 a shows a sector placement of divisions, in Fig.
  • FIG. 13 c in the form of sectors on a triangle
  • FIG. 13 g built divisions of the color indicator, each of which has the shape of either a circle, or a rectangle, or a triangle.
  • - indicators - controllers which act as an indicator indicating that an event has occurred. For example, when activating (highlighting) one division indicator - the controller of freshness of products - the product is suitable, and when another division is activated - the product is not suitable; b) - indicator - an interactive base controller. For example, an indicator that acts as an interactive database for product labeling - when activated, the product is available, with a passive indicator - the product is not in stock; c) an indicator indicating the gradation of the characteristic.
  • the indicator - the storage temperature controller - activating one division - was stored without violations, the activation of the second division - was stored with minor violations, while the activation of the third division - was stored with significant violations, leading to the product becoming unusable.
  • the proposed technical solution for the label indicator (Fig. 1) consists of a flexible stacked film plate (1), a color indicator (2) (Fig. 2), a microdisplay (3) (Fig. 3) and a semiconductor circuit (4) . Inside the color indicator and microdisplay there is a resonant circuit (5) (see Figs. 2,3 and 4).
  • the color indicator (2) has one (Fig. 13 g) or several (Fig. 13 a, b and c) divisions (6). These divisions can be of different shapes - in the form of sectors of a circle, ellipse, or stripes of a rectangle or triangle, and can be placed in the form of a single division on one color indicator.
  • Each color indicator (2) and each microdisplay (3) are placed in a row on a flexible film plate (1), forming “B” divisions on the optical device (7) of the indicator label.
  • Each division (6) of the color indicator has a specific color.
  • the color of the indicator is changed by changing the color of the magnetic pigment included as a separate component in the conductive paint.
  • a magnetic field emanating from the resonant circuit (5) the pigment changes the color of the paint, from, for example, light to dark or vice versa.
  • the pigment can have a gradation - with a minimum magnetic field - the paint will be, for example, the lightest, with an average magnetic field - the paint will be medium in color intensity, and with a maximum magnetic field - the paint will be the darkest.
  • the indicator will be able to show the occurrence of an event, for example, the storage period has been exceeded or not.
  • the indicator will be able to show the suitability of the product by an indicator that can vary in a certain interval.
  • the storage temperature may be optimal, then the paint is the lightest, or the temperature varies within the acceptable range, then the average paint intensity, for example, did not go beyond a certain interval, or the temperature exceeded the allowable limits, then the darkest paint, for example, the product was thawed .
  • the magnetic field of the magnetic layer changes with the attenuation in time according to the selected characteristics of the magnetic field, the color of the indicator also changes. The color change depends on the strength of the magnetic field on the magnetic pigment.
  • a conductive paint with magnetic pigment can be included in the form of threads that are in the form of SYMBOLs and placed in a medium of magnetic pigment (see Fig. 6 and 7).
  • the color indicator (2) and the microdisplay (3) are equipped with a symbol identifier detector (8) (see Fig. 4), which consists of an upper active layer (9), which is a magnetic layer and a lower passive magnetic layer (10), containing magnetic pigment.
  • the passive magnetic layer (see Fig. 6) is made of conductive paint with the inclusion of magnetic powder with the addition of magnetic pigment. Together, paint, magnetic powder and magnetic pigment react to changes in the magnetic field.
  • the symbol identifier detector also includes a polymer layer (11), on which the upper and lower magnetic layers (9, 10) are placed, as well as a polymer structure (12), in which the magnetic layers of the lower magnetic layer (10) are placed, and in which the polymer is an insulator for them. Both layers, both passive and active, are made of conductive paint with the inclusion of magnetic powder. In the magnetic layer (9) of the magnetic layer, magnetic powder is also added to the magnetic paint, which is a magnetic pigment.
  • magnetic powders are magnetic information carriers
  • magnetic pigments are magnetic powders that change color depending on the magnetic field.
  • the identifier detector of the symbol identifier also includes the membrane of the identifier detector (13), which activates the upper active magnetic layer (9) in contact with it directly.
  • the active magnetic layer (9) is made of magnetic powder, which is placed in the conductive paint in the form of cells (see Fig. 6) paint is placed around the magnetic powder in the form of honeycombs.
  • the passive magnetic layer (10) is made of magnetic powder, which is a pigment mixed with conductive paint and this mixture is separated by a polymer structure, which is an insulator.
  • the polymer structure (12) is also made in the form of cell cells in which conductive paint with magnetic pigment is placed. In this case, both the magnetic pigment of the passive layer and the magnetic powder of the active layer have a predetermined ratio of magnetic characteristics that depend on the magnetic field created by the membrane (13) and the resonant circuit (5).
  • the material of the magnetic layers (9 and 10) has constant magnetic characteristics over a given period of time relative to a given decay rate over a given period of time of one of the characteristics that allows one to determine one or another control parameter.
  • Such a dependence can be realized due to the generation of a magnetic field by the resonant circuit (5) in proportion to the energy stored by the transponders, of which the resonant circuit (5) consists.
  • the energy accumulated by transponders is proportional to the energy transmitted to the transponder from the device for storing current information from sensors that monitor one or another parameter, for example, temperature, pressure, etc.
  • the resonant circuit (5) is an antenna cobweb or grid made in the form of a CHIP, including passively active antennas, the function of which is performed by transponders.
  • the color indicators (2) can perform the following functions (see Fig. 14):
  • A an indicator that either “burns” - a bright color, i.e. the product is good, or “sweat” - dark color - the product is not good, which means, for example, the expiration date has expired or the information base of the label is broken, or the package was opened, etc., depending on the parameter being monitored.
  • “6” the indicator is on (normally closed), which keeps the circuit operational or the indicator is off, i.e. an open circuit, which means, for example, is paid for the goods, or vice versa, the indicator works as normally open, for example, when notifying about the price, removing the excise stamp from the goods, personifying the buyer when paying with a credit card, etc.
  • “C” is an indicator that shows the gradation of color, whether there were violations by the regime of the environment in which the products are stored or violations of the characteristics of the products themselves, for example, temperature, humidity, pressure, etc.
  • the microdisplay (3) includes an optical layer (14) with optical elements (15) and a reflective layer (16).
  • the optical layer is made of glass microspheres (17) layer-by-layer embedded polymer gasket (18).
  • the optical layer can also be made of metal particles (19) layer-by-layer embedded in a polymer gasket (20). Glass microspheres and metal particles can be combined into blocks (see Fdg. 12). Metal particles do not touch each other. Metal particles and microspheres are coated with a metal layer that forms a reflective layer (16), which provides the reflectivity of these particles or blocks.
  • the optical microdisplay layer (3) has two layers - the first reflective layer (21) and the second reflective layer (22) (see Fig. 8).
  • Each reflective layer is made in the form of a discrete layer having a special structure of inclusions (23) divided into electrically isolated sections formed of thin-film metal shells deposited on metal particles or glass microspheres combined into blocks (see Fig. 12).
  • One performs the function of the first reflective layer (21), and the second performs the function of the second reflective layer (22) and is the opposite layer.
  • Each reflective layer (21 and 22) is provided on at least those metal particles or glass microsphere blocks that are located above the region or regions of the antenna or communication antennas of the resonant circuit (5), and a magnetic active layer (24) is placed between the optical layers and a magnetic passive layer (25), which are made similar to the magnetic layers (9 and 10) of the color indicator (2).
  • the resonant circuit (5) of the microdisplay (3) is made in such a way that its resonant frequency is equal to the sum of two different modulation frequencies of the radiation of the active radio frequency emitter, and the resonant circuit (5) includes a passive radiator that emits a response from the active radio frequency emitter at the indicated total frequency ( antennas) semiconductor circuit (4) tone-modulated signal reflecting characteristics of the radio frequency identification module (26) of the semiconductor circuit (4).
  • the active emitter of the resonant circuit (5) emits a back-up signal.
  • the resonant circuit (5) is made as the spatial structure of the integrated circuit, forming an antenna network consisting of passively active antennas - transponders and placed on the indicator flexible type-setting film plate (1) in each color indicator (2) and microdisplay (3).
  • the metal particles (19) of the optical element (15) can be angular reflectors and can be made in the form of prisms.
  • a polymer gasket (18) for optical elements is made of glass or plastic or a polymer film or ceramic or mica, as well as a polymer layer (11).
  • the radiation of each resonant circuit (5) is tone-modulated respectively by one radio frequency identification module (26). Both the color indicator symbol identifier detector (2) and the first reflection layer (21) of the micro display (3) are covered with a protective layer (34).
  • the microdisplay can reflect information on the optical layer (21), which is the first reflective layer, in the form of labels that are displayed on the basis of the program embedded in the resonant circuit chip (5), it is placed above the active magnetic layer (24), and can reflect information based on the color change of the pigment that is transmitted through the second reflective layer is the opposite (22) from the passive magnetic layer (25), which is located under the second reflective layer (22).
  • the semiconductor circuit (4) (see Fig. 5) with a nonlinear impedance for summing radio frequency signals received from sensors located in an external quality control system, contains: a resonant circuit (27), including an active radio frequency emitter, the radiation of which is frequency-modulated by two the nearest frequencies equal to the arithmetic average of the frequencies selected for operation in a given range and the receiving antenna, as well as at least one microprocessor (28) in the form of an integrated circuit, a storage device for current information uu (29) as a receiver) sensor and memory unit, which stores received from each of the external quality control of the sensor information, a comparison unit (30) the received information and stored information in the storing predetermined parameters apparatus (31), the apparatus storing the specified parameters ( 31), the number of which should correspond to the number of controlled characteristics, the storage device for the specified parameters is also the carrier of the information required for product identification, an activation matrix (32) in the form of a narrow-band receiver, for receiving and demodulating the carrier signal by subtracting the RF signal and its
  • the manufacturer of the label - indicator places on the film plate (1) as many color indicators (2) and / or microdisplays (3) as it is necessary to control the parameters of the goods.
  • the passive magnetic layer (10) of each symbol identifier detector is selected according to the magnetic characteristics that correspond to a given decay rate of the magnetic field in the layer, which corresponds, for example, to the product storage time.
  • control for example, of the storage temperature of the product
  • the magnetic field of the passive layer (10) is exposed to the magnetic field of the active magnetic layer (9), which increases (decreases), respectively, with a decrease or increase in storage temperature
  • the specified attenuation rate of the magnetic field of the passive layer increases that affects the color change of the pigment.
  • the magnetic field of the active magnetic layer is adjusted in accordance with the program stored in the chip of the antenna spider line (grid) of the resonant circuit (5) of the color indicator or microdisplay ils based on the received radio frequency signal from the resonant circuit (27) of the semiconductor circuit (4). Moreover, from the resonant circuit (5) it generates microcurrents in the membrane (13) that create a magnetic field in the active magnetic layer (9). Moreover, the surface of the passive magnetic layer (10), in which there is a magnetic pigment, darkens or brightens. If magnetic paint with magnetic pigment is embedded in the passive layer in the form of threads depicting symbols, then these symbols are displayed or disappear.
  • the microdisplay due to the presence of reflective layers (21.22), which are devices for displaying information stored in the active magnetic layer (24), displays the requested information. Information is requested by means of an active emitter available from the controlling organization, the signal from which receives the resonant circuit (5) of the microdisplay (3).
  • the microdisplay screen due to the presence of a passive magnetic layer (25) of the symbol identification detector, is illuminated through the optical layers (21.22) with a color that corresponds to the state of the product quality characteristic. Signs are displayed on the reflective layers when requesting information, and are visible due to the internal illumination that occurs when the active magnetic layer (24) of the symbol identification detector is irradiated with an active antenna of the resonant circuit (5) located behind the reflective layer (21).
  • the reflective layer (21) is reflective for the light incident from the front side of the passive magnetic layer (25), and transmitting for light propagating from the side of the active magnetic layer (24).
  • the microdisplay can be double-sided, on which, on one side of the label on the reflective layer (21), the backlight of the passive magnetic layer (25) is visible, and on the other hand, the requested information is visible on the reflective layer (21) on the other side, which is located on side of the active magnetic layer (24). (see Fig. 9). Both color indicators and microdisplays can be combined based on a single symbol identifier detector.
  • the time intervals, as well as the decay rate of the magnetism level of the magnetic layers, are programmed using the information recorded in the storage device of the set parameters (31), as well as the microprocessor (28). And they are controlled using a comparison unit (30), a device for storing current information (29), a radio frequency identification unit (26) and a resonant circuit (27).
  • the label is activated using the activation matrix (32), and it is impossible to enable or disable the launched label device with the information prescribed by the manufacturer.
  • the power supply unit (33) is connected only at the moments of image change, or the implementation of an audio signal, etc., and is not required to maintain the operation of transponders, which greatly saves batteries and has little effect on the operation of the device.
  • transponders used in labels are designed to work in industrial applications; they are resistant to chemical and temperature effects, high humidity and pressure, are made of high-strength plastic, have round and square shapes.
  • Transponders, both passive and semi-passive, and active are designed for mounting on various objects, including metal, and provide reading information at a distance of more than 5 meters.
  • Semi-passive transponders allow you to additionally control the temperature selectively at predetermined intervals.
  • transponders mounted on metal, cardboard, plexiglass, glass.
  • Special transponders are a group of products designed to work in contactless identification systems for industrial use. They are made in the form of glass capsules 23, 32, 50 mm long., 3.85 mm in diameter. and 16 mm., in the form of durable cylinders and disks of different lengths (up to 120 mm.) and diameters (up to 85 mm.), are made of special composition, as well as in the form of rectangular modules with holes for mounting. T, e. the technical feasibility of the proposed device is provided with a well-prepared elemental base.
  • Typesetting indicator flexible film polymer plate can be made in large sizes, from a few centimeters to several meters, include up to several hundred color indicators and / or color displays in various combinations.
  • Such a flexible plate can be used as an electronic newspaper or magazine, TV screens, computer displays, mobile phone displays, displays of electronic devices and devices, or in the form of labels for large, bulky cargo or billboards.
  • the proposed technical device ensures the achievement of a technical result, is new and industrially applicable.
  • Labels with microchips and transponder antennas allow you to read information without contact, at a distance of 1 to 100 meters or more, to prevent theft from trading floors, libraries, etc. Labels serve as the basis for the latest systems of logistics of goods or accounting in warehouses.

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  • General Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Theoretical Computer Science (AREA)
  • Near-Field Transmission Systems (AREA)

Abstract

L'étiquette indicatrice 'Globus' est un dispositif combiné qui comprend un ou plusieurs afficheurs couleur et/ou micro-écrans à contours de résonance ainsi qu'un circuit à semi-conducteurs. Elle est munie d'un détecteur d'identificateur de symboles dans lequel la poudre magnétique et/ou le pigment magnétique des couches possède des caractéristiques magnétiques constantes sur une période déterminée par rapport à une vitesse d'affaiblissement déterminée pendant la période de temps prédéterminée d'une des caractéristiques transmises par l'antenne du contour de résonance du circuit à semi-conducteurs. Chaque couche réfléchissante du micro-écran se présente comme des particules métalliques ou des blocs de microsphères en verre, disposés dans le domaine où se situent les antennes de communication du contour de résonance. Le contour de résonance a une fréquence de résonance égale à la somme de deux fréquences différentes de la modulation de rayonnement de l'émetteur à radiofréquences actif du circuit à semi-conducteurs.
PCT/RU2006/000574 2006-11-02 2006-11-02 Étiquette indicatrice WO2007117178A1 (fr)

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Application Number Priority Date Filing Date Title
PCT/RU2006/000574 WO2007117178A1 (fr) 2006-11-02 2006-11-02 Étiquette indicatrice

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Application Number Priority Date Filing Date Title
PCT/RU2006/000574 WO2007117178A1 (fr) 2006-11-02 2006-11-02 Étiquette indicatrice

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WO2007117178A1 true WO2007117178A1 (fr) 2007-10-18

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN112736484A (zh) * 2020-12-28 2021-04-30 中国科学院长春光学精密机械与物理研究所 一种分光分频器件

Citations (5)

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RU2183372C2 (ru) * 1997-07-19 2002-06-10 Самсунг Электроникс Ко., Лтд. Двухдиапазонная антенна
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Publication number Priority date Publication date Assignee Title
CN112736484A (zh) * 2020-12-28 2021-04-30 中国科学院长春光学精密机械与物理研究所 一种分光分频器件
CN112736484B (zh) * 2020-12-28 2022-11-04 中国科学院长春光学精密机械与物理研究所 一种分光分频器件

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