KR101198212B1 - Rfid tag having self-destructing function - Google Patents

Abstract

PURPOSE: An RFID(Radio Frequency ID) tag with a self-destruct function is provided to prevent the reuse of the RFID tag by separately manufacturing a dielectric substrate and a feeding unit or forming a damage inducing unit on the dielectric substrate. CONSTITUTION: A radiation antenna(112) receives power from an RFID reader. A dielectric substrate(111) includes the radiation antenna. An RFID chip(123) includes attachment information. A feeding unit(120) includes a feeding loop(122) supplying power to the RFID chip. The feeding unit disconnects electrical combination between the feeding loop and the dielectric substrate as the feeding unit and the dielectric substrate are separated from each other during removal from an object of the dielectric substrate.

Description

RFID tag with self-destruction function {RFID TAG HAVING SELF-DESTRUCTING FUNCTION}

The present invention relates to an RFID tag having a self destruction function, and more particularly, to an RFID tag having a self destruction function that prevents reuse of an RFID tag when the RFID tag is removed from an object.

Recently, RFID (Radio Frequecy Identification) technology for automatically recognizing objects has been in the spotlight. In other words, it is called a wireless recognition technology, which refers to a system that can transmit and receive various data in a wireless manner using a predetermined frequency band.

In the case of magnetic or bar code, a specific mark that is exposed to the outside is required, and since it is displayed on the outer surface, the recognition rate gradually decreases over time due to damage or wear, but RFID tags can solve this disadvantage.

These RFID tags are emerging as a new solution used in various automation business, logistics management, distribution, etc., and credit card, prepaid / postpaid bus subway guard, parking card, postal delivery system, animal history display It is widely used in the field of distribution and material management together with electronic identification reader.

In general, an RFID system consists of an RFID tag and an RFID reader, and RFID tags are classified into active and passive types according to the presence or absence of a battery. Unlike magnetic systems used for conventional object recognition, RFID tags transmit and receive data to and from a reader in a non-contact manner, and are classified into low frequency, high frequency, and ultra high frequency (UHF) according to the high and low frequency used.

When an article attached to an RFID tag is placed in a read zone of an RFID reader, the RFID reader modulates an RF signal having a specific carrier frequency to send an interrogation to the RFID tag, and the RFID tag responds to the reader's question. do. In the passive RFID system, the RFID reader modulates a continuous electromagnetic wave having a specific frequency to send an interrogation signal to the RFID tag, and the RFID tag transmits its information stored in the internal memory to the RFID reader. The RFID tag can be recognized by back scattering modulation of the electromagnetic wave transmitted from the RFID reader and sent back to the RFID reader. Here, the backscattering modulation is a method of sending information of the RFID tag by changing the magnitude or phase of the scattered electromagnetic wave when the RFID tag scatters and sends back the electromagnetic wave transmitted from the RFID reader.

Conventionally, an RFID tag is attached to a vehicle or a motorcycle for use in access control, crackdown of an unregistered vehicle, or confirmation of a stolen vehicle. It has been. In addition, when using a method of separating only an RFID tag and combining it with a stolen vehicle, there is a problem in that it cannot be identified as a stolen vehicle.

The present invention is an RFID tag having a self-destructive function, and when the RFID tag is removed from an object, an object of the present invention is to prevent the reuse of the RFID tag by damaging the RFID antenna.

In addition, an object of the present invention is to manufacture the antenna of the RFID tag in a low-cost type to attach to the object, and to maximize the recognition power from the RFID reader.

The present invention is a radiation antenna for receiving power transmitted from the RFID reader; A dielectric substrate on which the radiation antenna is printed; A feeder for printing an RFID chip having information of an attachment and a feed loop for supplying power to the RFID chip; And a double-sided tape coupled to the dielectric substrate and the feeding portion, wherein the electrical coupling is separated between the dielectric substrate and the feeding loop when the dielectric substrate is removed from the object.

Further, the present invention is characterized in that the feed section uses a substrate separate from the dielectric substrate so that the feed section and the dielectric substrate are separated from each other when the dielectric substrate is removed from the object.

In addition, the present invention is characterized in that the dielectric substrate is more flexible than the power feeding portion.

In addition, the present invention, the double-sided tape is characterized in that the hole is formed so that the feed section can be located.

In addition, the present invention is characterized in that the dielectric substrate is formed with a breakage inducing portion, and the dielectric substrate is damaged when removed from the object.

In addition, the present invention is characterized in that the damage inducing portion is formed on the inner side or the edge of the dielectric substrate.

According to the present invention configured as described above it is possible to arbitrarily remove the RFID tag in the stolen goods, and to prevent reuse of the RFID tag.

In addition, it can be attached to a vehicle or a motorcycle, and can be used for access control, cracking down of unregistered vehicles, and confirming stolen vehicles, thereby increasing crime prevention and criminal arrest.

In addition, the dielectric substrate and the feeder may be manufactured separately, or a breakage induction part may be provided on the dielectric substrate to cause damage to the dielectric substrate and the radiation antenna when removing the dielectric substrate from the object, thereby making it possible to securely prevent reuse.

1 and 1b is an exploded view of an RFID tag according to the present invention.
2 is a view showing a state in which the radiation portion and the feed portion of the RFID tag in accordance with the present invention combined.
3A to 3C are views illustrating various embodiments of a damage induction part of an RFID tag according to the present invention.
4 is a view showing the top of the RFID tag according to the present invention.
5 is a diagram illustrating a radio wave equivalent circuit of an RFID antenna and an RFID chip according to the present invention.

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

1A and 1B are views illustrating an exploded view of an RFID tag according to the present invention, and FIG. 2 is a view showing an RFID tag according to the present invention.

First, the RFID tag 100 is divided into a radiating unit 110 and a feeding unit 120, the radiating unit 110 is composed of a dielectric substrate 111 and a radiation antenna 112, the feeding unit 120 is The feed loop 122 and the RFID chip 123. Specifically, the dielectric substrate 111 constituting the body of the RFID tag 100, the radiation antenna 112 formed on the dielectric substrate 111, and the RFID chip 123 having information on the object and positioned on the feed loop. And a feed loop 122 connected to the radiation antenna 112 and providing an RF signal to the RFID chip 123, and a double-sided tape 130 capable of coupling the RIFD tag 100 to the object.

In the RFID tag 100, the dielectric substrate 111 uses a rectangular or various types of PET substrate, polycarbonate substrate, or polymide substrate, and the feed loop 122 is formed together with the RFID chip 123 and the radiation antenna 112. It is formed by a method such as aluminum or copper foil etching, conductive ink printing and bonding to form the RFID tag 100. Here, the dielectric substrate 111 may be a dielectric having a dielectric constant of about 2.2, induce an electrical induction action, and maintain the shape of the radiation antenna 112.

In addition, the radiation antenna 112 is divided into a patch antenna and a dipole antenna. The antenna of the present invention may be any antenna applicable to an RFID tag as well as a dipole type. The RFID antenna includes a radiation antenna 112 and a feed loop 122, and receives a radio frequency signal transmitted from a radio wave identification reader, and uses a material such as aluminum. The feed loop 122 may be formed in various shapes such as a circle and a triangle, but the present invention illustrates a rectangular shape, and may be directly etched or printed with the radiation antenna 112 on the dielectric substrate 111, as well as the dielectric substrate. The feeder 120 may be provided separately from the 111 to form the feeder 120. Accordingly, the radiation antenna 112 is formed on the dielectric substrate 111, and the feed loop 122 is formed on the feed unit 120, so that the radiation antenna 112 and the feed unit 120 are electrically connected to each other. Can be attached to the object.

In this case, when the RFID tag 100, that is, the dielectric substrate 111 is removed and removed from the object, the electrical coupling is separated between the radiation antenna 112 and the feed loop 122, and information cannot be transmitted. For example, only the dielectric substrate 111 of the RFID tag is separated and the power supply unit 120 is attached to the object as it is, thereby leaving the electrical coupling between the dielectric substrate 111 and the power supply loop 122 to the RFID tag 100. Will lose its function. At this time, the electrical coupling is gradually reduced in proportion to the distance away.

As such, the double-sided tape 130 is coupled to the dielectric substrate 111 on which the radiation antenna 112 is etched or printed, and the RFID tag 100 may be attached to an object such as an automobile. Looking at the configuration in which the electrical coupling is separated between the dielectric substrate 111 and the feed loop 122, the double-sided tape 130 is coupled to the dielectric substrate 111, the radiation antenna 112 is formed, as shown in Figure 1a, The feeder 120 is coupled again. In this case, the dielectric substrate 111 may be made of a more flexible material than the feeder 120, and thus, when the dielectric substrate 111 is removed from the object, the relatively hard feeder 120 remains on the object, thereby preventing reuse of the RFID tag. have. As another example, as shown in FIG. 1B, the double-sided tape 130 has a hole 132 through which the feeder 120 can be positioned, and the feeder 120 is positioned in the hole 132 to feed the feeder 120. May not be attached to the dielectric substrate 111. That is, the double-sided tape 130 is coupled to the bottom surface of the power supply unit 120 so as to be adhered to the object, and the upper surface of the power supply unit 120 facing the dielectric substrate 111 is formed with a hole in the double-sided tape 130. As the adhesive material is not applied, the adhesive is not attached to the dielectric substrate 111. Therefore, when the RFID tag 100 is removed from the object, since the power supply unit 120 is not attached to the dielectric substrate 111, only the dielectric substrate 111 is removed from the object, and the power supply unit 120 is attached to the object. Will remain.

In addition, the feeder 120 is more firmly attached to the object, the feeder 120 is a material of the dielectric substrate 111 to help the separation of the feeder 120 and the dielectric substrate 111 when removing the RFID tag. The use of less flexible materials has been described. For example, the thickness of the substrate used for the feeder 120 may be made thicker than that of the dielectric substrate, or a hard material may be used to facilitate separation of the feeder 120 from the dielectric substrate when the RFID tag 100 is removed from an object. It can be done.

Meanwhile, the radiation antenna 112 used in the present invention basically uses a dipole antenna. The dipole antenna refers to an antenna whose overall length is half-wavelength with respect to the operating frequency. The dipole antenna can be implemented in a flat type, has a directivity characteristic received in a vertical direction with respect to the plane, and has a non-directional characteristic when transmitted to an RFID reader. It is a form suitable for the RFID tag 100. Looking at the RFID antenna according to the present invention, the feeder 120 of the rectangular shape in the center and the feeder loop 122 is printed on the feeder, the RFID chip 123 is located on the feeder loop (122). In addition, the power supply unit 120 is composed of a radiation antenna 112 is radiated in both left and right symmetry and printed on the dielectric substrate 111. The RFID chip 123 may modulate the magnitude or phase of the electromagnetic wave transmitted by an RFID reader (not shown) in order to transmit information of an object to which the RFID tag 111 is attached. As the material of the radiation antenna 112 and the feed loop 122, a metal material having good malleability and ductility, such as aluminum, brass, and iron, is suitable. Since such a material has a high degree of backscattering, the medium and long distance transmission is possible. It is a UHF band antenna capable of high speed transmission and has good characteristics.

In addition, the RFID chip 123 transmits information by changing its input impedance, and the chip impedance repeats two states of a matched state and a shorted state to transmit data. This causes the effect of changing the radar cross section (RCS) of the dipole type antenna to cause backscatter modulation.

Referring to FIG. 2, an RFID tag is coupled to an object, and a dielectric substrate (radiator) on which the radiation antenna 112 is etched or printed, and a feed unit on which the feed loop 122 is printed ( It can be seen that 1200 is divided into. A double-sided tape 130 is attached to the back surface of the dielectric substrate 111, and a hole 132 may be formed in the center of the double-sided tape 130, and thus the hole 132 is formed. The power supply unit 120 may be positioned to correspond to the power supply unit 120. The portion where the hole 132 is positioned does not have an adhesive material, and thus the power supply unit 120 is not adhered to the dielectric substrate 111, or the hole 132 is Although not formed, if the feed unit 120 is made of a different material from the radiating part or a thicker or harder material than the radiating part, when the RFID tag 100 is separated from the object, the radiating part 110 and the feeding part 120 are separated from each other. Done.

3A-3C illustrate various embodiments of a dielectric substrate in accordance with the present invention.

Referring to FIGS. 3A through 3C, breakage induction parts 113, 114, and 115 are positioned at the edges of the inner side of the dielectric substrate 111 or the side of the dielectric substrate 111. When the damage induction parts 113, 114, and 115 remove the RFID tag 100, the parts of the damage induction parts 113, 114, and 115 are torn by the damage induction parts 113, 114, and 115, thereby damaging the dielectric substrate 100 and the radiation antenna 112. The reuse of the tag 100 can be prevented. In this case, the breakage induction parts 113, 114, and 115 may have an inner or dielectric substrate on which the feed part 120 of the dielectric substrate 111 is located so that the dielectric substrate 111 may be easily torn when the RFID tag 100 is removed. Cut out the edge of the 111 to form. When the sheath is formed on at least one of the outer edges, it is preferable to make it obliquely oblique or Y-shaped so that the dielectric substrate 111 can be torn along the sheath when the object is removed from the object. Although not shown in the drawings, damage induction parts 113, 114, and 115 are provided on the dielectric substrate 111, and separate feed parts 120 are placed together to cause damage to the RFID tag when the RFID tag 100 is removed from an object. At the same time to separate from the feeder may be used to prevent reuse of the RFID tag (100).

4 is a diagram illustrating an upper surface of an RFID tag.

Referring to FIG. 4, the capacitance value of the RFID chip 133 and the inductance of the antenna are adjusted by adjusting the length of the radiation antenna etched or printed on the dielectric substrate and the distance between the radiation unit 110 and the power supply unit 120. Resonance is performed in the corresponding frequency band by completing complex conjugate matching on the shielding structure using the values. Therefore, the position D1 and D2 of the radiator 110 and the power supply unit 120 may be adjusted to design an inductive reactance component Xa having a large impedance Za of the RFID antenna. In addition, by adjusting the number and interval of the line of the radiation antenna 122, it is possible to control so that the impedance of the RFID antenna has a small resistance component. By adjusting these two components, the RFID tag 100 can be controlled to resonate at the resonant frequency of the UHF band. In addition, the feed loop 122 maintains two contacts that can be connected to the high frequency front end of the RFID chip 123, and may have one of several shapes such as oval, circular, triangular, and polygonal. .

5 is a diagram illustrating an impedance matched RFID tag according to a variable value.

Referring to FIG. 5, the feed loop 122 is adjacent to the radiation antenna 112 to facilitate magnetic coupling, and is partially connected to the radiation antenna 112 and electrically connected to the RFID chip 123. Connected to supply power to the RFID chip 123.

The impedance of the RFID antenna and the impedance of the RFID chip 123 based on the dotted line in the vertical direction, wherein the impedance of the voltage source and the RFID antenna (Za) is a high frequency front end portion (RF) of the impedance (Zc) of the RFID chip 123 Front-end) equivalent circuit. The impedance Za of the RFID antenna has a real part Ra and an imaginary part Xa, and the impedance Zc of the RFID chip 123 has a real part Rc and an imaginary part Xc. At this time, if the impedance Za of the RFID antenna and the shear impedance Zc of the RFID chip 123 are conjugately matched according to the equation, the maximum power is transmitted to the high frequency front end of the RFID chip 123.

Ra = Rc (1)

Xa = -Xc (2)

Typical RF shear impedances have arbitrary complex impedances other than 50 Ω. That is, the RF shear impedance Zc has a small resistance component Rc and a large capacitive reactance component (capacitance) Xc, and the reactance Xc is composed of a rectifier circuit using a diode. Has a value For conjugate matching, the impedance Za of the RFID antenna 132 must have a small resistance component Ra and a large inductive reactance component (inductance) Xa to resonate with a corresponding frequency of electromagnetic waves transmitted from the reader.

In the above, the present invention has been described in detail with reference to the embodiments of the present invention and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the contents described in the claims below.

100: RFID tag 111: dielectric substrate
120: feeder 130: double-sided tape

Claims (6)

A radiation antenna for receiving power transmitted from the RFID reader;
A dielectric substrate on which the radiation antenna is printed;
A feeder for printing an RFID chip having information of an attachment and a feed loop for supplying power to the RFID chip; And
And a double-sided tape coupled to the dielectric substrate and the feeder, wherein the feeder uses a substrate separate from the dielectric substrate, so that the feeder and the dielectric substrate are separated from each other and the electrical RFID tag with self-destructive function, characterized in that the bond is released. The method of claim 1,
The dielectric substrate is RFID tag with a self-destructive function, characterized in that more flexible than the feed portion. The method of claim 1,
RFID tag with a self-destructive function, characterized in that the double-sided tape is formed so that the feed section is located. 4. The method according to any one of claims 1 to 3,
The dielectric substrate has a self-destructive function, characterized in that the breakage induction portion is formed, the dielectric substrate is damaged when removed from the object. 5. The method of claim 4,
RFID tag having a self-destructive function, characterized in that the damage inducing portion is formed on the inner side or the edge of the dielectric substrate. delete

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