KR20120140514A - Hf rfif tag antenna formed by embroidery of electroconductive thread - Google Patents

Abstract

PURPOSE: An HF RFID tag antenna formed by embroidery of electroconductive thread is provided to form HF RFID antenna pattern by sewing conductive yarn. CONSTITUTION: Conductive yarn(11) is sewed. Antenna patterns(10) form loops. A RFID tag chip(20) is fixed between one end of an antenna pattern and the other end connecting antenna patterns. Therefore, the antenna pattern is easily controlled to improve the recognition rate and the recognition distance of the tag.

Description

HF RFID tag antenna formed by embroidery or stitched with conductive yarn {HF RFIF antenna formed by embroidery of electroconductive thread}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tag antenna formed of conductive yarns, and more particularly, to an HF RFID tag antenna formed by embroidering or stitching with conductive yarns formed with an antenna pattern by embroidering or sewn with conductive yarns on a fiber.

In general, radio frequency identification (RFID) is a technology for non-contact recognition or recording of a tag's information using radio frequency. It recognizes and tracks a tagged object, animal, or person. , Technology that can be managed. The RFID system has a unique identification information and is attached to a tag (tag or transponder) attached to an object or animal, and connected to a reader or interrogator and a reader for reading or recording the identification information of the tag. Includes a computer.

In such an RFID system, an RFID tag is composed of an antenna and an RFID IC chip, and a reader transmits and receives an electric magnetic field through a reader antenna to exchange data with a tag while supplying power to a passive tag.

The microchip of the tag is located at the feed point of the tag antenna and receives all the necessary energy from the reader's signal. The tag sends the coded signal back to the reader at HF frequency by electromagnetic backscattering. send. In other words, the tag sends back a portion of the energy received from the reader. The tag is powered by a Schottky rectifier circuit to convert microwave energy into direct current. In the case of passive tags, It operates by using rectified DC voltage.

In order to employ such RFID tag in textile products such as clothing, the tag formed on the label is packaged with urethane or a specific substance and attached to the textile product in the form of nametech.

Therefore, the RFID label tag requires a cumbersome process of packaging the RFID tag, which not only increases manufacturing time but also increases manufacturing cost such as labor cost, thereby degrading economic efficiency.

In addition, there is a problem that the RFID label tag can be easily separated from the product, so that the RFID label tag is separated from the product due to the carelessness of the operator, or the RFID label tag is removed from the product intentionally, resulting in a product that is not tagged. .

HF (13.56 MHz) tags are typically card-shaped tags in the form of films or printed with cards or conductive inks. These tags, that is, the card may be broken in the pocket or purse, the film form is wrinkled or broken, and when the tag is erased or bent due to washing with conductive ink, the continuity problem does not work as a tag. There was a problem that caused.

In order to solve the above problems, it is possible to think of a fiber tag that forms an RFID antenna pattern by directly stitching or printing a conductive yarn or a conductive ink onto the fiber and clothing.

However, there is a problem in that it is not easy to attach the RFID tag chip on the fiber when the conductive yarn is directly sewn onto the garment.In the case of printing conductive ink on the textile and clothing, the iron, the laundry, the wrinkle, etc. There was a problem that the form of the RFID fiber tag cannot be guaranteed because it cannot preserve its shape.

SUMMARY OF THE INVENTION In view of the above circumstances, the present invention has been made to solve various drawbacks and problems of conventional RFID label tags and to spread the adoption of RFID tags in the field of textiles and clothing. The present invention provides an HF RFID tag antenna formed by embroidering or stitching a conductive yarn capable of operating as a tag regardless of bending or packing by forming a HF RFID antenna pattern by stitching.

Another object of the present invention is to form a HF RFID antenna pattern on the inside of the sleeve of the clothes or clothing itself by the embroidery or stitching of the conductive yarns, while the RFID tag chip can operate stably while the size of the antenna pattern can be easily adjusted The present invention provides an HF RFID tag antenna formed by embroidery or stitching as a conductive yarn that improves the recognition distance and recognition rate.

Another object of the present invention is to form a HF RFID antenna pattern on the inside of the sleeve of the clothes or the clothing itself by the embroidered or stitched by the conductive yarn, which can be used as an access security card or a traffic card, regardless of bending or packing. It is to provide an HF RFID tag antenna formed by embroidery or stitched with a conductive yarn.

It is still another object of the present invention to provide an HF RFID tag antenna formed by embroidering or stitching an RFID tag chip with a conductive yarn that can be stably attached on a fiber to increase the radiation efficiency of the antenna, and can be used semi-permanently, and can vary in application possibilities. To provide.

HF RFID tag antenna formed by embroidering or stitching with the conductive yarn of the present invention for achieving the above object is a plurality of loops by embroidering or stitching the conductive yarn 11 on the fiber A to a certain width and length. A plurality of antenna patterns 10 formed; The RFID tag chip 20 is fixed between one end of one of the plurality of antenna patterns 10 and the other end of the plurality of antenna patterns 10 connected to each other.

The present invention can form a HF RFID antenna pattern with a conductive yarn embroidered or stitched, and can operate as a tag regardless of bending or packing. By forming HF RFID antenna pattern on its own, RFID tag chip can be operated stably and easy to adjust the size of antenna pattern, improving the recognition distance and recognition rate of tag, and the sleeve of clothes by embroidery or stitching of conductive yarn HF RFID antenna pattern is formed on the inside or the clothes itself, so it can be used for access security or transportation card regardless of bending or packing, and RFID tag chip is stably attached on the fiber, so the radiation efficiency of antenna is high. It can be used semi-permanently, but there is a special advantage that can vary the application possibilities.

1 is a view showing the configuration of an HF RFID tag antenna formed by embroidery or stitched with the conductive yarn of the present invention according to the first embodiment,
Fig. 2 is a sectional view of Fig. 1,
3 is a view showing the configuration of the HF RFID tag antenna formed by embroidery or stitched with the conductive yarn of the present invention according to the second embodiment,
4 is a graph showing the reflection coefficient characteristics for each frequency of the HF RFID tag antenna of the present invention.

Hereinafter, the HF RFID tag antenna formed by embroidery or stitching with the conductive yarn of the present invention will be described in detail with the accompanying drawings and preferred embodiments.

1 is a view showing the configuration of the HF RFID tag antenna formed by embroidering or stitched with the conductive yarn of the present invention according to the first embodiment, Figure 2 is a cross-sectional view of Figure 1, Figure 3 is a conductive yarn according to the second embodiment 4 is a graph showing the reflection coefficient characteristic of each HF RFID tag antenna of the present invention, which is formed by embroidery or stitching. HF RFID is embroidered and formed by the conductive yarn of the first embodiment of the present invention. The tag antenna includes: a plurality of antenna patterns 10 which form a plurality of loops by embroidering or stitching a conductive yarn 11 on a fiber A in a predetermined width and a predetermined length; The RFID tag chip 20 is fixed between one end of one of the plurality of antenna patterns 10 and the other end connecting the plurality of antenna patterns 10 to each other.

Each of the plurality of antenna patterns 10 is formed by embroidery or stitching so that the conductive yarn 11 alternately enters and exits the front and rear surfaces of the fiber A. FIG.

Here, it is preferable to attach a wick (stabi lizer) or a cloth having a velcro tape (BT) to one side of the fiber (A) so that it can be attached to or detached from the sleeve of the garment.

In addition, the antenna pattern 10 may be formed by embroidering or sewn directly on the clothing.

FIG. 2 is the same as the second embodiment of the present invention except that the conductive yarn 11 is formed in a zigzag loop on the fiber A as in the first embodiment shown in FIG. That is, the HF RFID tag antenna formed by embroidering or stitching the conductive yarn of the second embodiment of the present invention is embroidered or stitched the conductive yarn 11 on the fiber A by a zigzag of a predetermined width and a predetermined length. A plurality of antenna patterns 10 'forming a loop; The RFID tag chip 20 'is fixed between one end of the plurality of antenna patterns 10' and the other end of the plurality of antenna patterns 10 'connected to each other.

Each of the plurality of antenna patterns 10 'is formed by embroidery or stitching so that the conductive yarn 11 comes out on one side of the fiber A. FIG.

Here, the other side of the fiber (A) is preferably attached to the wick (stabi lizer) having a Velcro tape (BT) or cloth so that it can be attached and detached to the sleeve of the garment.

In addition, the antenna pattern 10 'may be formed by embroidering or stitching directly on clothing.

Example

Antenna patterns according to the first and second embodiments of the present invention were actually fabricated and the reflection coefficient and impedance of the tag were measured by simulation.

The simulation tool is designed using CST Microstudio 2009, the chip impedance is matched to Philips' NXP chip impedance, and the tag's center frequency is 910MHz.

HF RFID tags forming the antenna patterns of the first and second embodiments were fabricated using the tag antennas, respectively, and reflection coefficients and impedances of the produced tags were measured by a simulation tool, and are shown in FIG. 3. As can be seen from FIG. 3, the center frequency is 910 MHz, and the reflection coefficient of the tag is excellent as about -19.32 dB, indicating that the tag can be used as a good tag. It can be seen that the operation is possible in the HF RFID frequency band.

As shown in FIG. 3, the center frequency is 1.025 GHz and the reflection coefficient of the tag is -0.85 dB, indicating that it can be used as a good tag. In the reflection coefficient of -0.3 dB, the frequency bandwidth is 400 MHz (850 to 1250 MHz). It can be seen that the operation is possible in the UHF RFID frequency band.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto, and various modifications can be made without departing from the gist of the invention.

10, 10 ': center zigzag embroidery pattern 11: conductive yarn
20, 20 ': single line embroidery pattern 30, 30': zigzag pattern
40, 40 ': left and right figure pattern 50: figure pattern

Claims (8)

A plurality of antenna patterns 10 on which the plurality of loops are formed by embroidering or stitching a conductive yarn 11 on a fiber A in a predetermined width and a predetermined length; HF RFID tag formed by embroidery or stitched with a conductive yarn composed of a fixed RFID tag chip 20 connected between one end of any one of the plurality of antenna patterns 10 and the other end connecting the plurality of antenna patterns 10 to each other antenna. 2. The conductive yarn of claim 1, wherein each of the plurality of antenna patterns 10 is embroidered or stitched to form a conductive yarn so that the conductive yarn 11 alternately enters and exits the front and rear surfaces of the fiber A. HF RFID tag antenna formed by 3. The conductive material according to claim 1 or 2, wherein a wick or cloth having a velcro tape BT is attached to one side of the fiber A to attach or detach a sleeve to the garment. HF RFID tag antenna formed by embroidery or stitching. The HF RFID tag antenna according to claim 1 or 2, wherein the antenna pattern (10) is formed by embroidering or stitching it with a conductive yarn, characterized in that it is formed by embroidering or stitching directly on clothing. A plurality of antenna patterns (10 ') having a plurality of loops formed by embroidering or stitching a conductive yarn (11) on a fiber A in a zigzag of a predetermined width and a predetermined length; It is formed by embroidery or stitched with a conductive yarn consisting of a fixed RFID tag chip 20 'connected between one end of any one of the plurality of antenna patterns (10') and the other end connected to the other antenna pattern (10 '). HF RFID Tag Antenna. 6. The conductive yarns of claim 5, wherein each of the plurality of antenna patterns 10 'is embroidered or stitched with conductive yarns, characterized in that the conductive yarns 11 are embroidered or stitched so as to emerge from one side of the fiber A. One HF RFID Tag Antenna. 7. The conductive material according to claim 5 or 6, wherein a wick or cloth having a velcro tape BT is attached to the other side of the fiber A so as to be attached to and detached from the sleeve of the garment. HF RFID tag antenna formed by embroidery or stitching. 7. The HF RFID tag antenna according to claim 5 or 6, wherein the antenna pattern (10 ') is formed by embroidering or stitching directly onto clothing.

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