KR101516257B1 - RFID tag device for thick steel plate - Google Patents

Abstract

The present invention relates to a tag product attached to a steel product having various external environments according to lamination and movement, and particularly when having a laminate structure in which an RFID tag is inserted between the upper plate and the lower plate, The present invention provides an RFID tag that can overcome the problem of inadmissibility due to various lamination environments that can excite an internal field in a laminated structure in consideration of characteristics and enable stable transmission and reception.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an RFID tag,

The present invention relates to an RFID tag antenna that can be recognized even in a steel plate steel plate, and more particularly, to an RFID tag that solves the problem of performance deterioration due to various lamination shapes when a yard is mounted on a steel product.

RFID (Radio Frequency Identification) technology attaches a tag composed of a small chip and an antenna to an object, wirelessly recognizes the ID of the object, collects information, and provides the position and state through the tag. Among them, the RFID tag operates in an electromagnetic back scattering manner. More specifically, the RFID tag antenna receives radio waves transmitted through a reader antenna, and then converts the received radio wave into a DC using a rectifier circuit. The converted energy operates the chip and the chip information is sent to the reader again through the RFID tag antenna.

An integrated management system for distribution and logistics that applies these RFID technologies to steel products is being developed. The application of RFID technology to steel logistics distribution has advantages such as simplification or elimination of integrated inspection process, construction of crane automation, real time product information transmission and reduction of product inconsistency rate.

1 is a view showing a conventional steel product and a general tag attached thereto. As shown, the tag is attached to the side of the steel product, and in particular, the lower the height (T), the more various applications are possible from a thin steel product to a thick product. The narrower the width (h) low.

2 is a view showing a classification according to a shape in which a steel product according to the prior art is stacked upon yard loading. In general, the metal RFID tags applied to steel products consider only the metal attached at the time of designing and do not take into consideration various shapes due to lamination. Therefore, performance deterioration occurs in practical application. Particularly, as in Case E, There is a problem that the RFID tag antenna can not be recognized by a general RFID tag antenna.

In addition, general metal tags realize stable radiation performance by using attached steel products as the ground plane. However, this is because the matching characteristics are sensitively changed in arbitrary size and various lamination environments of steel products, there was.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an RFID tag having a laminated structure in which a tag product attached to a steel product protrudes to the outside or an RFID tag is embedded between a top plate and a bottom plate, The RFID tag device which can recognize even when buried between steel products is proposed.

According to another aspect of the present invention, there is provided an RFID tag apparatus comprising: a steel product; an insulated base plate; a radiator for transmitting and receiving radio waves; a radiator having a helical structure; And a fixed jig part.

The RFID tag apparatus for steel according to the present invention has an advantage of being capable of stable transmission and reception by overcoming the problem of inability to recognize that is buried among steel products stacked in various forms.

1 is a view showing a conventional steel product and a general tag attached thereto.
2 is a view showing a classification according to a shape in which a steel product according to the prior art is stacked upon yard loading.
3 is a view showing steel products stacked according to the viewpoint of radio waves in order to explain the RFID tag apparatus according to the present invention.
4 is a diagram showing the configuration of an RFID tag apparatus according to the present invention.
5 is a view showing a base unit of the RFID tag apparatus according to the present invention.
6 is a view showing a radiating section of the RFID tag apparatus according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

3 is a view showing steel products stacked according to the viewpoint of radio waves in order to explain the RFID tag apparatus according to the present invention.

The state of the steel product 120 is influenced by the incident or radiated electromagnetic waves. The state in which the steel product 120 is loaded is referred to as a propagation environment.

The propagation environment is divided into an open type and a parallel flat transmission line type. The open type is a radio wave environment considering only the influence of the steel product 120. The parallel flat transmission line type is a radio wave environment in which the upper and lower parts of the target steel product 120 are surrounded by other steel products 120. In both propagation environments, the electric field is minimized and the magnetic field is maximized by the boundary conditions of the radio waves incident on or radiating from the surface of the conductor. In a propagation environment, it is better to use a radiator with excellent magnetic field. A radiator such as a helical structure or a loop structure has a magnetic field excellent in properties.

4 is a diagram showing the configuration of an RFID tag apparatus according to the present invention.

The RFID tag device 110 is attached to the side surface of the steel product 120 and is insulated from the steel product 120. The RFID tag device 110 includes a substrate unit 430 having an RFID IC chip and a line pattern, a radiation unit 420 having a helical structure for transmitting and receiving radio waves, a substrate unit 430 and a radiation unit 420 And a jig 410 having one side attached to the steel product 120.

5 is a view showing a base unit of the RFID tag apparatus according to the present invention.

5 (a) is a view showing the base unit of the RFID tag apparatus according to the present invention.

The substrate unit 430 includes a connection part 440 connected to the radiation part 420 and an RFID IC chip 431.

5 (b) is a view showing a configuration in which a matching portion 432 is further provided on the base portion of the RFID tag apparatus according to the present invention.

The substrate unit 430 may further include a matching unit 432 in addition to the connection unit 440 and the RFID IC chip 431 that are connected to the radiation unit 420.

The surface on which the radiation part 420, the connection part 440 and the RFID IC chip 431 are formed on the base part 430 is referred to as a front side and the rear side is referred to as a rear side.

The substrate portion 430 is not electrically connected to the steel product 120 to be attached. The rear surface of the substrate portion 430 is attached to the inside of the jig 410.

The matching portion 432 provided according to need is constituted by a capacitor, an inductor, or a meander line structure.

The meander line structure means that the line of the antenna has a serpentine shape in order to reduce the length of the antenna, and it has various shapes. The meander line is widely used as a transmission line to implement an RF device or a matching inductor for RF circuit matching.

RF transmission lines, such as microstrip lines, are widely used to implement RF passive components consisting of capacitors and inductors. Passive components for RF have a fairly large footprint over the entire RF circuit. When the meander type line is used, the length of the transmission line constituting the RF element is greatly reduced. The meander line is widely used as a matching inductor on an RF circuit, and has an advantage that parasitic components are very small as compared with a conventional spiral inductor.

The matching unit 432 can perform complex conjugate matching with the RFID IC chip 431. [ The RFID IC chip 431 is an active element and has a complex impedance at an output terminal.

Impedance matching is a technology for preventing transmission signals from being reflected by a difference in impedance of each signal line when two different signal lines are connected. For this, the radiating unit must perform complex conjugate matching with the RFID IC chip 431.

Complex conjugate matching refers to a design method that minimizes the reflected signal by canceling the design by designing the sign of the imaginary value between two connected terminals differently.

The matching unit 432 serves to assist the antenna when the complex conjugate matching is not sufficient in the antenna design. .

The reason why the matching portion 432 is provided as necessary is to cope with various frequencies. If the radiating part 420 is designed to have a complex conjugate matching with a design frequency using a helical antenna, the frequency is fixed.

It may happen that the frequency is additionally changed after impedance matching is performed by matching the radiation part 420 with a specific frequency. For example, since the required RF frequency differs from country to country, it is necessary to make all the radiating parts 420 differently. If all of the radiation parts 420 are fabricated at different frequencies, a large amount of mold cost is incurred. In this case, it is possible to solve the problem that the radiation part 420 needs to be made again by providing the matching part 432 so that it can be fitted to another frequency.

6 is a view showing a radiating section of the RFID tag apparatus according to the present invention.

The radiation part 420 has one or more wires of one or more helical structures 421 connected to the substrate part 430. The helical structure 421 has a helical antenna element. The helical structure 421 includes a monopole type and a dipole type.

The monopole method uses a conductor surface as a ground plane.

The dipole type is a structure having a conductor having a helical structure 421 from the center to both sides.

The monopole method has a disadvantage in that the input impedance has an abrupt change depending on the shape of the conductor surface. Therefore, it is appropriate that the radiation part 420 has a helical structure 421 of a dipole type. The radiation unit 420 is designed to have complex conjugate matching with the design frequency.

One or more conductors connected to the substrate unit 430 have a helical structure 421. One end of each of the conductors is connected to the connection unit 440 and the other end thereof is bent toward the connection unit 440, To ensure matching characteristics. The folded structure 422 stabilizes the impedance through the coupling with the steel product 120. The conductor pattern of the helical structure 421 is formed in various shapes including a circle, an ellipse and a polygon such as a triangle, a rectangle, a square, and a pentagon. The above-described objects can be attained as long as the structures 422 bent in the direction of the connection part 440 are structured to induce a propagation environment and coupling irrespective of the folding direction and deformation.

In addition, the antenna 421 may have a structure in which a conductor of the helical structure 421 surrounds an antenna cylinder or an antenna rod 423 having a dielectric or magnetic property.

The cylinder is a three-dimensional body surrounded by a curved surface formed by turning a single straight line around a straight line. The antenna cylinder is a circular cylindrical antenna with hollow inside.

The term "rod" means that the perimeter is rounded, and the antenna rod is an antenna with rounded circumference.

The number of winding wires of the wire having the helical structure 421 in the radiation part 420 is determined according to the material of the jig 410 and the input impedance of the RFID IC chip 431. The number of winding wires refers to the number of turns of the wire having the helical structure 421.

The radiation part 420 is not electrically connected to the steel product 120 to be attached. The radiating unit 420 has a feature that the radiating unit 420 that depends only on the magnetic field can be realized, so that the input matching is not sensitively changed even in the change of the surrounding environment and the stable performance can be ensured.

The jig 410 has a sealing structure that constitutes the substrate portion 430 and the radiation portion 420 or has a structure in which a part of the substrate portion 430 and the radiation portion 420 are open have. The jig 410 may have various shapes including a hexahedral shape, a cylindrical shape, and a tapered cylindrical shape. The jig 410 can improve the radiation efficiency of the radiation part 420 when using a material having a high permittivity or a high permeability. For example, among metals, gold, silver, copper, aluminum, iron, and alloys.

The jig 410 may be formed of a metal material that is in contact with the steel product 120 as a metal, and may be thermally bonded, bonded or taped with a plastic material, So that it can be stably attached.

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While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

110: RFID tag device 120: Steel product
410: jig portion 420: radiation portion
430: substrate portion 440: connection portion

Claims (18)

In an RFID tag device,
Steel products and insulated board parts;
A radiating part configured to transmit and receive radio waves and configured to have a helical structure; And
And a jig part which surrounds the base part and the radiating part and has one side attached to the steel product,
The substrate portion includes:
A connection part connected to the radiation part; And
An RFID IC chip,
The radiating portion includes:
And one or more leads connected to the substrate portion,
Each of the conductors has a helical structure,
Wherein one end of each of the conductors is connected to the connection portion and the other end of the wire is bent in the direction of the connection portion.
delete The apparatus of claim 1, wherein the substrate portion
And a matching unit for matching the impedance of the RFID tag. 4. The apparatus of claim 3, wherein the matching portion
A capacitor and an inductor, or a meander line structure. delete delete delete 2. The method of claim 1,
And the impedance is stabilized through the coupling with the steel product. The apparatus of claim 1,
An antenna cylinder or an antenna rod connected to one side of the substrate unit,
And a conductor of the helical structure surrounds the antenna cylinder or the antenna rod. The apparatus of claim 1,
Wherein the wire shape of the helical structure has one of a circular shape, an elliptical shape, and a polygonal shape. The apparatus of claim 1,
Wherein the number of winding wires of the conductive wire of the helical structure is determined by the material of the jig. The apparatus of claim 1,
Wherein a number of winding wires of the conductive wire of the helical structure is determined according to an input impedance of the RFID IC chip. The apparatus of claim 1,
Wherein the insulator is insulated from the steel product. 2. The apparatus of claim 1, wherein the jig
Wherein the RFID tag has an airtight structure in which the substrate portion and the radiating portion are formed inside. 2. The apparatus of claim 1, wherein the jig
Wherein the base portion and the radiating portion are formed inside and a part of the base portion and the radiating portion are open. 2. The apparatus of claim 1, wherein the jig
Wherein the RFID tag has a hexahedral shape, a cylindrical shape, or a tapered cylindrical shape. 2. The apparatus of claim 1, wherein the jig
Wherein the RFID tag is made of a metal. 2. The apparatus of claim 1, wherein the jig
And the rear surface is joined to the steel product by any one of welding, bonding, taping, inserting, and engaging.

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