KR101855520B1 - Long-range Ultra High Frequency RFID tag antenna - Google Patents

Abstract

An UHF RFID tag antenna for long-range recognition includes a printed circuit board where a UHF chip and an antenna electrode for receiving the radio signal of a UHF band are formed; a dielectric layer attached to the lower surface of the printed circuit board; and a metal thin film layer which surrounds the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure. The UHF RFID tag antenna can have high gain even if it is attached to metal.

Description

Description of the Related Art [0002] A long-range RFID tag antenna is a long-

Field of the Invention [0002] The present invention relates to a UL RFID tag antenna, and more particularly, to a UL RFID tag antenna capable of recognizing long distances.

When a signal of about 1 W is transmitted from the reader / writer using a radio signal of UHF band (860 to 960 MHz) and a response signal is sent back to the reader / writer side when the signal is received from the tag (tag) side, (Radio Frequency Identification) system in which a reader / writer is read by a reader / writer.

The communication distance varies depending on the gain of the antenna on the tag side, the operating voltage of the IC (integrated circuit) chip in the tag, and the surrounding environment, but is generally about 3 m.

The RFID (Radio Frequency Identification) system is a technology that recognizes objects using RF wireless communication and is applied in various fields such as inventory management, material distribution, livestock management, and safe eating.

RFID (Radio Frequency Identification) consists of reader system and tags. The reader system includes a host computer, a reader, and a reader antenna. The RFID tag is composed of an RF chip and a tag antenna. A passive tag that does not have its own power operates the RF chip using the signal transmitted from the reader, and transmits the tag information to the reader.

Since the radiation output of the reader system is limited to 36 dBm according to ISO (International Organization for Standardization) -18000-6, the tag recognition distance of the general dipole structure is limited. The recognition distance of general commercial tag is about 5 ~ 6m. Therefore, in order to design the passive tag to be recognizable at a long distance (10m or more), the structure of the antenna should be designed as a high gain antenna structure or a gain-enhancing structure.

The high-gain antenna structure includes a horn antenna, a Yagiwada antenna, and a patch antenna. The gain enhancement structure includes a cavity model, a meta-material, and an array structure. When the Yagi-Uda antenna is attached to the tag antenna, the recognition distance is about 8 m.

The UHF band (840-960 MHz) RFID transmits information in a far scattering manner using an electromagnetic wave in the far field. The general label tag does not operate if it is subject to electromagnetic interference due to the surrounding environment or if the impedance of the tag chip and tag antenna is mismatched. Therefore, when a general label tag is attached to a metal, the impedance of the tag antenna changes, and the tag does not operate normally because it is incompatible with the chip impedance.

That is, when a general label tag is attached to a metal, parasitic capacitance is generated between the tag antenna and the metal surface. The impedance of the tag antenna changes due to the parasitic capacitance, and the tag is not normally operated due to mismatch with the chip impedance. Therefore, the metal tag should be designed with a special structure other than the general label tag structure.

In order to solve the above problems, a conventional reference (Y.-K. Park, Y. Kim, K. Lee, YC Chung, "Various UHF RFID tag for metallic object," IEEE International Symposium on Antenna and Propagation, pp. 2258-2288, June 2007.) introduced a variety of small metal tags made of a combination of vias, meander lines, and patches on a PCB. The recognition distance of the commercial metal tag is 3 ~ 5m, and it is used in applications where the near field recognition is possible such as notebook and cabinet management.

However, in the case of managing large metal at long distance (5 ~ 10m) such as large iron plate, large metal warehouse, and heavy equipment management, current commercial metal tag can not be used because of limit of recognition distance. Therefore, in order to apply RFID to such environment, it is necessary to design a special tag that can recognize at long distance even if it attaches to metal, without significant performance change.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-described technical problems, and provides a UFI RFID tag antenna having a cavity structure which can have a high gain even if attached to a metal and can be recognized even at long distances.

According to an aspect of the present invention, there is provided a printed circuit board comprising: a printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed; A dielectric layer attached to a lower surface of the printed circuit board; And a metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure.

The antenna electrode may include a left port line 21 connected to the left side of the microfluid chip 10; A left antenna line 23 connected to the left port line 21 and extending in the left direction; A left loop line 25 connected to the left antenna line 23 and extending downward; A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction; A right port line 31 connected to the right side of the Yu-chip chip 10; A right antenna line 33 connected to the right port line 31 and extending in the left direction; A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).

According to another aspect of the present invention, there is provided a printed circuit board comprising: a printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed; A dielectric layer attached to a lower surface of the printed circuit board; And a metal thin film layer surrounding the lower surface of the dielectric layer to form a cavity structure; A < / RTI > RFID tag is provided.

The antenna electrode may include a left side mat line 20 connected to the left side of the microfluid chip 10; A left M-loop line 22 connected to the left mat line 20 and extending in an upward direction; A left antenna line 23 extending in the left direction from the center area and connected to the left side of the left E-loop line 22 at one side; A left loop line 25 connected to the left antenna line 23 and extending downward; A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction; A right side mat line 30 connected to the right side of the Yu-chip chip 10; A right side M loop line 32 connected to the right side mat line 30 and extending in an upward direction; A right antenna line 33 extending in the right direction from the center area and connected to the lower side of the right M-loop line 32; A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).

According to another aspect of the present invention, there is provided a printed circuit board comprising: a printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed; A dielectric layer attached to a lower surface of the printed circuit board; A metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure; And a metal layer in the shape of a trunk tube formed to surround the outer periphery of the printed circuit board at a predetermined angle while extending from the upper surface of the metal thin film layer.

The antenna electrode may include a left side mat line 20 connected to the left side of the microfluid chip 10; A left M-loop line 22 connected to the left mat line 20 and extending in an upward direction; A left antenna line 23 extending in the left direction from the center area and connected to the left side of the left E-loop line 22 at one side; A left loop line 25 connected to the left antenna line 23 and extending downward; A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction; A right side mat line 30 connected to the right side of the Yu-chip chip 10; A right side M loop line 32 connected to the right side mat line 30 and extending in an upward direction; A right antenna line 33 extending in the right direction from the center area and connected to the lower side of the right M-loop line 32; A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).

According to another aspect of the present invention, there is provided a printed circuit board comprising: a printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed; A dielectric layer attached to a lower surface of the printed circuit board; A metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure; And a metal layer in the form of a trumpet tube formed to surround the outer periphery of the printed circuit board at a predetermined angle with a space spaced apart from the upper surface of the metal thin film layer.

The antenna electrode may include a left side mat line 20 connected to the left side of the microfluid chip 10; A left M-loop line 22 connected to the left mat line 20 and extending in an upward direction; A left antenna line 23 extending in the left direction from the center area and connected to the left side of the left E-loop line 22 at one side; A left loop line 25 connected to the left antenna line 23 and extending downward; A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction; A right side mat line 30 connected to the right side of the Yu-chip chip 10; A right side M loop line 32 connected to the right side mat line 30 and extending in an upward direction; A right antenna line 33 extending in the right direction from the center area and connected to the lower side of the right M-loop line 32; A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).

The RFID tag according to an embodiment of the present invention includes:

Cavity structure, and even if it is attached to a non-metallic material or a metal material, it can have a high gain and can be recognized even at a long distance.

1 is a diagram showing a configuration of a UE RFID ID tag antenna 1 according to a first embodiment of the present invention.
Fig. 2 is a perspective view of the YUFIL RF ID tag antenna 1 of Fig.
Fig. 3 is a view showing the actual view of the Yu-
3A is a diagram showing reflection coefficients of a UE RFID ID tag antenna 1
3B is a view showing the measurement distance of the UE RFID ID tag antenna 1
FIG. 4 is a diagram showing the structure of a YUFIDRF ID tag antenna 2 according to a second embodiment of the present invention
5 is a perspective view of the YUFIL RF ID tag antenna 2 of FIG.
Fig. 6 is an actual view of the YUFIL RF ID tag antenna 2 of Fig.
6A is a diagram showing the reflection coefficient of the RFID tag ID tag antenna 2
6B is a view showing a gain pattern of the RFID tag ID tag antenna 2
FIG. 7 is a diagram showing the configuration of a UE RFID ID tag antenna 3 according to a third embodiment of the present invention
8 is a perspective view of the YUFIL RF ID tag antenna 3 of FIG.
9 is an actual view of the YUFIL RF ID tag antenna 3 of Fig.
Fig. 10 is a diagram showing the structure of a Yu-ichi RF ID tag antenna 4 according to the fourth embodiment of the present invention
11 is a perspective view of the YUFIL RF ID tag antenna 4 of Fig.
12 is a diagram showing a configuration of a UE RFID ID tag antenna 5 according to a fifth embodiment of the present invention
13 is a perspective view of the YUFIL RF ID tag antenna 5 of Fig.
FIG. 14 is a diagram showing the actual view of the YUFIL RF ID tag antenna 5 of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention.

FIG. 1 is a configuration diagram of a UE RFID tag antenna 1 according to a first embodiment of the present invention, FIG. 3 is an actual view of a UE RFID tag antenna 1 of FIG. 1, 1 is an actual view of a UE RFID ID tag antenna 1.

The RFID tag 1 according to the present embodiment includes only a simple structure for clearly explaining the technical idea to be proposed.

Referring to FIGS. 1 to 3, the RFID tag 1 includes a printed circuit board 100, a dielectric layer 200, and a metal thin film layer 300.

The detailed configuration and major operation of the UE RFID tag antenna 1 configured as above will be described below.

The printed circuit board 100 is formed with an antenna electrode for receiving a radio signal of the FM chip 10 and the FM band.

In this embodiment, FR-4 is used as the printed circuit board 100, but the antenna may be made of conductive ink on the flexible film.

The dielectric layer 200 is attached to the lower surface of the printed circuit board 100.

In this embodiment, styrofoam (? = 1.01) having a dielectric constant similar to that of air is used as the dielectric layer 200, but the air itself may be used as the dielectric layer 200 or various materials having similar dielectric constants to air may be used.

The metal thin film layer 300 forms a cavity structure by simultaneously enclosing the lower surface and the side surface of the dielectric layer 200 and the side surface of the printed circuit board 100.

In this embodiment, the metal thin film layer 300 is made of a copper material. However, according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel or an alloy material containing at least one of them may be used.

The antenna electrode formed on the printed circuit board 100 will be described in detail.

A left port line 21 connected to the left side of the FC chip 10,

A left antenna line 23 connected to the left port line 21 and extending in the left direction,

A left loop line 25 connected to the left antenna line 23 and extending downward,

A left teat mat line 27 connected to the left loop line 25 and extending in the right direction,

A right port line 31 connected to the right side of the FC chip 10,

A right antenna line 33 connected to the right port line 31 and extending in the left direction,

A right loop line 35 connected to the right antenna line 33 and extending in the downward direction,

And a right teat mat line 37 connected to the right loop line 35 and extending in the leftward direction and connected to the left teat mat line 27. [

In the present embodiment, the right line and the left line are formed symmetrically with respect to each other with the Yu-chip chip 10 therebetween, symmetrically with respect to the length and width, and specific values thereof are shown in Table 1.

ant_w ant_h pcb_w pcb_h tmat_w tmat_h loop_w loop_h port_w cav 61.8 mm 7mm 140mm 60mm 65mm 1mm 5mm 32mm 2.2 mm 10mm

The YUFID RFID tag antenna 1 of the first embodiment comprises:

A dielectric layer 200 having a dielectric constant similar to that of air and a styrofoam (ε = 1.01) are inserted in an antenna having a cavity structure and a cavity for enclosing the side and rear portions of the outer side with the metal thin film layer 300 ) Structure.

The antenna size is 140mm x 60mm x 10mm and the parameters are set as ant_w = 61.8mm, ant_h = 7mm, tmat_h = 1mm, loop_w = 5mm, loop_h = 32mm and port_w = 2.2mm.

The designed antenna is simulated by CST program and the antenna impedance is designed to be conjugate to the impedance of RFID Higgs3 chip.

3A is a diagram showing reflection coefficients of the RFID tag ID tag antenna 1.

3A, the magnitude of the reflection coefficient by the simulation and the magnitude of the reflection coefficient measured by the Network Analyzer are compared with each other in the case of the Yu-FF RF ID tag antenna 1 having a cavity structure.

Simulation results show -14dB at 920Mhz and -10dB. Also, the -3dB bandwidth showed a width of about 50Mhz from 940Mhz to 890Mhz.

The recognition distance of the UE RFID ID tag antenna 1 showed a maximum recognition distance of 15m using the LP reader antenna and the recognition distance of the CP reader antenna was about 10m.

3B is a view showing a measured distance of the RFID tag ID tag antenna 1.

Referring to FIG. 3B, the distance measurement was performed using an Alien program using Alien's ALR 9900 reader and a reader antenna (gain of 5.9 dBi).

3B shows values obtained by measuring the recognition distances of the UE RF ID tag antenna 1 in theta (? Direction) and Phi (? Direction).

Theta direction recognition distance is about 15 m from the front which is 0 degree. At 180 degrees, only the recognition distance of 2.5 m was shown due to the cavity structure. The recognition distance on the Phi plane showed similar results.

5 is a perspective view of the UE RFID tag antenna 2 of FIG. 4, and FIG. 6 is a cross-sectional view of the UHF ID tag antenna 2 of FIG. 4 according to the second embodiment of the present invention. And is an actual view of the RFID tag antenna 2.

The UE RFID ID tag antenna 2 according to the present embodiment includes only a simple structure for clearly explaining the technical idea to be proposed.

Referring to FIGS. 4 to 6, the RFID tag ID tag antenna 2 includes a printed circuit board 100, a dielectric layer 200, and a metal thin film layer 300.

The detailed configuration and main operation of the above-configured UE RFID ID tag antenna 2 will be described below.

The printed circuit board 100 is formed with an antenna electrode for receiving a radio signal of the FM chip 10 and the FM band.

In this embodiment, FR-4 is used as the printed circuit board 100, but the antenna may be made of conductive ink on the flexible film.

The dielectric layer 200 is attached to the lower surface of the printed circuit board 100.

In this embodiment, styrofoam (? = 1.01) having a dielectric constant similar to that of air is used as the dielectric layer 200, but the air itself may be used as the dielectric layer 200 or various materials having similar dielectric constants to air may be used.

The metal thin film layer 300 surrounds the lower surface of the dielectric layer 200 to form a cavity structure.

In this embodiment, the metal thin film layer 300 is made of a copper material. However, according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel or an alloy material containing at least one of them may be used.

The antenna electrode formed on the printed circuit board 100 will be described in detail.

A left side mat line 20 connected to the left side of the UF chip 10,

A left side E-loop line 22 connected to the left side mat line 20 and extending in an upward direction,

A left antenna line 23 extending in the left direction from the central region and connected to the left side of the left side of the left side of the left side of the left side of the antenna,

A left loop line 25 connected to the left antenna line 23 and extending downward,

A left teat mat line 27 connected to the left loop line 25 and extending in the right direction,

A right side mat line 30 connected to the right side of the UF chip 10,

A right side E-loop line 32 connected to the right side mat line 30 and extending in the upward direction,

A right antenna line 33 extending in the right direction from the central region and connected to the right side M loop line 32 at one side thereof,

A right loop line 35 connected to the right antenna line 33 and extending in the downward direction,

And a right teat mat line 37 connected to the right loop line 35 and extending in the leftward direction and connected to the left teat mat line 27. [

In the present embodiment, the right line and the left line are formed symmetrically with respect to each other with the Yu-chip chip 10 therebetween, symmetrically with respect to the length and width, and specific values thereof are shown in Table 2.

ant_w ant_h pcb_w pcb_h tmat_w tmat_h loop_w loop_h cav mloop_w mloop_h mat_w mat_h 65mm 10mm 140mm 60mm 65mm 4mm 5mm 36mm 10mm 5mm 15mm 19mm 2.2 mm

For reference, the YUFLID RFID tag antenna 1 of the first embodiment described above is formed so as to surround the rear surface and the side surface with the metal thin film layer 300,

The YUFIDRF ID tag antenna 2 of the second embodiment is manufactured by attaching the metal thin film layer 300 to the back side only.

The dimensions of the antenna are 140mm x 60mm x 10mm and the parameters are ant_w = 65mm, ant_h = 10mm, tmat_w = 65mm, tmat_h = 4mm, loop_w = 5mm, loop_h = 36mm, mat_w = 19mm, mat_h = 2.2mm, mloop_w = 5 mm and mloop_h = 15 mm.

6A is a diagram showing the reflection coefficient of the RFID tag ID tag antenna 2.

Referring to FIG. 6A, there is shown a simulation of a UE ID tag antenna 2 and a magnitude of a reflection coefficient measured using a network analyzer.

Simulation shows that the measured value is about -25dB at 920Mhz and -5dB. The -3dB bandwidth is about 35Mhz. When the actual recognition distance was measured, the maximum recognition distance was 13.5m using the LP antenna, and the recognition distance of the CP antenna was about 9m.

6B is a diagram showing a gain pattern of the RFID tag ID tag antenna 2.

Referring to FIG. 6B, the beam pattern of the antenna has directivity in the antenna gain pattern of the RFID tag ID tag antenna 2.

The main antenna gain at 920MHz is 7.02dBi due to the antenna, and the width of the -3dB angle is 92.2 degrees (sky blue line). The characteristic feature is that the gain of the rear side is larger because the direction of the main lobe is small in the ground plane.

FIG. 7 is a configuration diagram of a UE RFID tag antenna 3 according to a third embodiment of the present invention, FIG. 8 is a perspective view of the UE RFID tag antenna 3 of FIG. 7, and FIG. 9 is a cross- And is an actual view of the RFID tag antenna 3.

The RFID tag ID tag antenna 3 according to the present embodiment includes only a simple structure for clearly explaining the technical idea to be proposed.

7 to 9, the UE RFID tag antenna 3 includes a printed circuit board 100, a dielectric layer 200, a metal thin film layer 300, and a metal layer 400 in the form of a fall tube, .

The detailed configuration and main operation of the above-configured UE RFID ID tag antenna 3 will be described below.

The printed circuit board 100 is formed with an antenna electrode for receiving a radio signal of the FM chip 10 and the FM band.

In this embodiment, FR-4 is used as the printed circuit board 100, but the antenna may be made of conductive ink on the flexible film.

The dielectric layer 200 is attached to the lower surface of the printed circuit board 100.

In this embodiment, styrofoam (? = 1.01) having a dielectric constant similar to that of air is used as the dielectric layer 200, but the air itself may be used as the dielectric layer 200 or various materials having similar dielectric constants to air may be used.

The metal thin film layer 300 surrounds the lower surface of the dielectric layer 200 to form a cavity structure.

In this embodiment, the metal thin film layer 300 is made of a copper material. However, according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel or an alloy material containing at least one of them may be used.

The metal foil 400 is formed to surround the outer periphery of the printed circuit board 100 at a predetermined angle while extending from the upper surface of the metal foil layer 300.

In this embodiment, the metal layer 400 of the trunk tube type is made of a copper material, but according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel, or an alloy material containing at least one of them may be used .

The antenna electrode formed on the printed circuit board 100 will be described in detail.

A left side mat line 20 connected to the left side of the UF chip 10,

A left side E-loop line 22 connected to the left side mat line 20 and extending in an upward direction,

A left antenna line 23 extending in the left direction from the central region and connected to the left side of the left side of the left side of the left side of the left side of the antenna,

A left loop line 25 connected to the left antenna line 23 and extending downward,

A left teat mat line 27 connected to the left loop line 25 and extending in the right direction,

A right side mat line 30 connected to the right side of the UF chip 10,

A right side E-loop line 32 connected to the right side mat line 30 and extending in the upward direction,

A right antenna line 33 extending in the right direction from the central region and connected to the right side M loop line 32 at one side thereof,

A right loop line 35 connected to the right antenna line 33 and extending in the downward direction,

And a right teat mat line 37 connected to the right loop line 35 and extending in the leftward direction and connected to the left teat mat line 27. [

In the present embodiment, the right line and the left line are formed symmetrically with respect to each other with the Yu-chip chip 10 therebetween, symmetrically with respect to the length and width, and specific values thereof are shown in Table 3.

ant_w ant_h pcb_w pcb_h tmat_w tmat_h loop_w loop_h horn_h, angle cav mloop_w m_loop_h mat_w mat_h 65mm 5mm 140mm 40mm 65mm 7mm 5mm 13mm 10mm, 45degree 10mm 12mm 10mm 29mm 2.5 mm

The UE RFID tag antenna 3 of the third embodiment has the following structure:

A dielectric layer 200 having a dielectric constant similar to that of air and a styrofoam (ε = 1.01) are inserted in an antenna having a cavity structure and a cavity for enclosing the side and rear portions of the outer side with the metal thin film layer 300 ) Structure.

Further, a metal layer 400 in the shape of a trunk tube is further formed so that the energy of the radio wave is transmitted to the tag to increase the gain. The metal foil 400 is formed to extend from the upper surface of the metal foil layer 300 to surround the outer periphery of the printed circuit board 100 at a predetermined angle (0 to 90 degrees).

The antenna size is 140mm x 40mm x 10mm and parameters are ant_w = 65mm, ant_h = 5mm, tmat_w = 65mm, tmat_h = 7mm, loop_w = 5mm, loop_h = 13mm, mat_w = 29mm, mat_h = 2.5mm, mloop_w = 12 mm, mloop_h = 10 mm, and horn_h = 10 mm (angle of 45 degrees).

FIG. 10 is a diagram illustrating the structure of a UE RFID tag antenna 4 according to a fourth embodiment of the present invention, and FIG. 11 is a perspective view of a UE RFID tag antenna 4 of FIG.

10 and 11, the YAG RF ID tag antenna 4 of the fourth embodiment is basically formed to have the same structure as the YAG RF ID tag antenna 3 of the third embodiment, and a part of the antenna electrode The parameters (cavity thickness, etc.) have changed. The specific values are shown in Table 4.

ant_w ant_h pcb_w pcb_h tmat_w tmat_h loop_w loop_h horn_h, angle cav mloop_w m_loop_h mat_w mat_h 60mm 5mm 140mm 60mm 60mm 2.5 mm 5mm 32mm 20mm, 45degree 20mm 5mm 15mm 16.5 mm 2.5 mm

The antenna size is 140mm x 60mm x 20mm and parameters are ant_w = 60mm, ant_h = 5mm, tmat_w = 60mm, tmat_h = 2.5mm, loop_w = 5mm, loop_h = 32mm, mat_w = 16.5mm, mat_h = 2.5mm, mloop_w = 5 mm, mloop_h = 15 mm, and horn_h = 20 mm (angle of 45 degrees).

12 is a configuration diagram of a UE RFID tag antenna 5 according to a fifth embodiment of the present invention, FIG. 13 is a perspective view of the UE RFID tag antenna 5 of FIG. 12, and FIG. 14 is a cross- And is an actual view of the RFID tag antenna 5.

The UE RFID ID tag antenna 5 according to the present embodiment includes only a simple structure for clearly explaining the technical idea to be proposed.

12 to 14, the UE RFID tag antenna 5 includes a printed circuit board 100, a dielectric layer 200, a metal thin film layer 300, and a metal layer 400 in the form of a fall tube, .

The detailed configuration and major operations of the UE RFID ID tag antenna 5 configured as described above will be described below.

The printed circuit board 100 is formed with an antenna electrode for receiving a radio signal of the FM chip 10 and the FM band.

In this embodiment, FR-4 is used as the printed circuit board 100, but the antenna may be made of conductive ink on the flexible film.

The dielectric layer 200 is attached to the lower surface of the printed circuit board 100.

In this embodiment, styrofoam (? = 1.01) having a dielectric constant similar to that of air is used as the dielectric layer 200, but the air itself may be used as the dielectric layer 200 or various materials having similar dielectric constants to air may be used.

The metal thin film layer 300 surrounds the lower surface of the dielectric layer 200 to form a cavity structure.

In this embodiment, the metal thin film layer 300 is made of a copper material. However, according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel or an alloy material containing at least one of them may be used.

The metal foil 400 is formed to surround the outer surface of the printed circuit board 100 at a predetermined angle with a predetermined space from the upper surface of the metal foil layer 300.

In this embodiment, the metal layer 400 of the trunk tube type is made of a copper material, but according to an embodiment, a single material of silver, aluminum, gold, platinum and nickel, or an alloy material containing at least one of them may be used .

The antenna electrode formed on the printed circuit board 100 will be described in detail.

A left side mat line 20 connected to the left side of the UF chip 10,

A left side E-loop line 22 connected to the left side mat line 20 and extending in an upward direction,

A left antenna line 23 extending in the left direction from the central region and connected to the left side of the left side of the left side of the left side of the left side of the antenna,

A left loop line 25 connected to the left antenna line 23 and extending downward,

A left teat mat line 27 connected to the left loop line 25 and extending in the right direction,

A right side mat line 30 connected to the right side of the UF chip 10,

A right side E-loop line 32 connected to the right side mat line 30 and extending in the upward direction,

A right antenna line 33 extending in the right direction from the central region and connected to the right side M loop line 32 at one side thereof,

A right loop line 35 connected to the right antenna line 33 and extending in the downward direction,

And a right teat mat line 37 connected to the right loop line 35 and extending in the leftward direction and connected to the left teat mat line 27. [

In this embodiment, the right line and the left line are formed symmetrically with respect to each other with the Yu-chip chip 10 therebetween, symmetrical with each other in length and width, and specific values thereof are shown in Table 5.

ant_w ant_h pcb_w pcb_h tmat_w tmat_h gap loop_w loop_h horn_h, angle cav mloop_w m_loop_h mat_w mat_h 60mm 5mm 140mm 60mm 60mm 2.5 mm 5mm 5mm 32mm 10mm, 45degree 10mm 3mm 12.5 mm 22mm 2.2 mm

The YUFIDRF ID tag antenna 5 of the fifth embodiment includes:

A dielectric layer 200 having a dielectric constant similar to that of air and a styrofoam (ε = 1.01) are inserted in an antenna having a cavity structure and a cavity for enclosing the side and rear portions of the outer side with the metal thin film layer 300 ) Structure.

Further, a metal layer 400 in the shape of a trunk tube is further formed so that the energy of the radio wave is transmitted to the tag to increase the gain. The metal foil 400 is formed to surround the outer periphery of the printed circuit board 100 at a predetermined angle (0 to 90 degrees) with a predetermined space from the upper surface of the metal foil layer 300.

Non-conductive material may be provided in the spacing space. In this embodiment, non-conductive materials are provided on each corner of the printed circuit board 100, and a metal layer 400 in the shape of a trunk tube is disposed on the non-conductive material.

The antenna size is 140mm x 60mm x 10mm and parameters are ant_w = 60mm, ant_h = 5mm, tmat_w = 60mm, tmat_h = 2.5mm, loop_w = 5mm, loop_h = 32mm, mat_w = 22mm, mat_h = 2.2mm, mloop_w = 3 mm, mloop_h = 12.5 mm, and horn_h = 10 mm (angle of 45 degrees).

For reference, in the UL RFID ID tag antenna of the first to fifth embodiments,

It is preferable to be packaged in a plastic case and attached to a non-metallic material or metal material. In this case, ABS (Acrylonitrile, Butadiene, Styrene) having a dielectric constant of about 3 may be used.

In addition, the metal oxide layer 400 may be further disposed on the YUFLID RFID tag antenna 1 of the first embodiment to improve the gain. At this time, the metal layer 400 in the shape of the trunk tube may be arranged in a form extending from the upper part of the metal thin film layer 300 or spaced apart from the metal thin film layer 300 by a certain space.

The RFID tag according to an embodiment of the present invention includes:

Cavity structure, and even if it is attached to a non-metallic material or a metal material, it can have a high gain and can be recognized even at a long distance.

In this embodiment, a UHF band tag which can be attached to an iron cart or a pallet for automobile parts distribution is designed. Tag to recognize the movement of the product in real time by managing information such as the basic information of the product, the goods receipt, the goods issue, and the inventory when moving the exported product.

In addition, it is possible to increase the recovery rate of carts and pallets that are missing when exporting carts or pallets exported as parts overseas, and to increase the tariff recovery rate as they can get back the tariffs of carts and pallets paid to the exporting country at the time of collection.

UHF band iron carts and pallet tags are metal tags that can be recognized over a long distance using a cavity structure. The cavity antenna is a metal reflector on the back .

The antenna was developed as an antenna with a size of 140mm x 60mm x 10mm, and it is a tag that can be applied to a metal environment such as a pallet or a cart, and the recognition distance is about 15m.

Many companies export pallets and carts that include parts as export items when exporting automotive parts overseas. Pallets and carts are also subject to customs duties at the time of customs clearance and can be reimbursed if they are recovered from abroad. (Article 99 of the Customs Act and Article 27 (12) of the VAT Act).

In fact, most carts and pallets have a large number of exported local waste, and even when it is difficult to get recognition as an exported company's goods, the actual recovery rate is not high. In addition, it is difficult to check the information of many parts of automobile, and it is difficult to check the position of the product in real time during transportation, warehousing and warehousing of logistics.

By attaching RFID UHF long distance recognition tag antenna to cart or pallet, it will be possible to reduce loss of cart or pallet from abroad, increase recovery rate, increase logistics efficiency through movement of goods and management of product.

Thus, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: printed circuit board
200: dielectric layer
300: metal thin film layer
400: metal layer in the form of a fallopian tube
10: Yu-chip chip
20: Left side mat line
21: Left port line
22: Left E-loop line
23: Left antenna line
25: left loop line
27: Left Tea Mat Line
30: Right side mat line
31: Right port line
32: right side E loop line
33: right antenna line
35: Right loop line
37: Right Tea mat line

Claims (8)

A printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed;
A dielectric layer attached to a lower surface of the printed circuit board; And
A metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure;
YUFID RF ID tag antenna containing.
The method according to claim 1,
The antenna electrode
A left port line 21 connected to the left side of the Yuft chip 10;
A left antenna line 23 connected to the left port line 21 and extending in the left direction;
A left loop line 25 connected to the left antenna line 23 and extending downward;
A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction;
A right port line 31 connected to the right side of the Yu-chip chip 10;
A right antenna line 33 connected to the right port line 31 and extending in the left direction;
A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And
And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).
delete delete A printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed;
A dielectric layer attached to a lower surface of the printed circuit board;
A metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure; And
A metal layer in the form of a trunk tube formed to surround the outer periphery of the printed circuit board at a predetermined angle while extending from an upper surface of the metal thin film layer;
YUFID RF ID tag antenna containing.
6. The method of claim 5,
The antenna electrode
A left side mat line 20 connected to the left side of the wafer chip 10;
A left M-loop line 22 connected to the left mat line 20 and extending in an upward direction;
A left antenna line 23 extending in the left direction from the center area and connected to the left side of the left E-loop line 22 at one side;
A left loop line 25 connected to the left antenna line 23 and extending downward;
A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction;
A right side mat line 30 connected to the right side of the Yu-chip chip 10;
A right side M loop line 32 connected to the right side mat line 30 and extending in an upward direction;
A right antenna line 33 extending in the right direction from the center area and connected to the lower side of the right M-loop line 32;
A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And
And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).
A printed circuit board on which an antenna electrode for receiving a radio signal of a UHF chip and a UHF band is formed;
A dielectric layer attached to a lower surface of the printed circuit board;
A metal thin film layer surrounding the lower surface and the side surface of the dielectric layer and the side surface of the printed circuit board to form a cavity structure; And
A metal layer in the form of a trunk tube formed to surround the outer periphery of the printed circuit board at a predetermined angle with a space spaced apart from the upper surface of the metal thin film layer;
YUFID RF ID tag antenna containing.
8. The method of claim 7,
The antenna electrode
A left side mat line 20 connected to the left side of the wafer chip 10;
A left M-loop line 22 connected to the left mat line 20 and extending in an upward direction;
A left antenna line 23 extending in the left direction from the center area and connected to the left side of the left E-loop line 22 at one side;
A left loop line 25 connected to the left antenna line 23 and extending downward;
A left Ti mat line 27 connected to the left loop line 25 and extending in the right direction;
A right side mat line 30 connected to the right side of the Yu-chip chip 10;
A right side M loop line 32 connected to the right side mat line 30 and extending in an upward direction;
A right antenna line 33 extending in the right direction from the center area and connected to the lower side of the right M-loop line 32;
A right loop line 35 connected to the right antenna line 33 and extending in a downward direction; And
And a right teat mat line (37) connected to the right loop line (35) and extending in the leftward direction and connected to the left teat mat line (27).

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