JP5939832B2 - RFID antenna for RFID tag - Google Patents

Description

    The present invention relates to an RFID antenna of an RFID (Radio Frequency Identification) tag, and particularly, an RFID tag having excellent durability even when attached to various fabric products such as clothes or laundry products and other flexible material products. It relates to antennas.

    Conventionally, an RFID tag having an IC chip and an RFID antenna and capable of wirelessly writing and reading data is attached to various articles, and various data on these articles are read and written, and various necessary data management, etc. It is used in the field of

FIG. 9 shows various types of laundry products (laundry products, flexible material products) such as various sheets, nightclothes, and uniforms that have been proposed and reused after being used in a hotel or company. FIG. 10 is a cross-sectional view of the laundry RFID tag 1. FIG. 10 is a plan view showing an example of the laundry RFID tag 1 that is attached and used. In FIG. 10, the section of the RFID antenna 5 along the formation path is shown.
The laundry RFID tag 1 includes a tag base 2 and an RFID inlet 3 provided on the tag base 2 and is configured as a sheet-like component.

    The tag base 2 is made of a synthetic resin material having necessary flexibility and rigidity, such as polyethylene terephthalate (PET) or a laminated film thereof, and has a RFID inlet 3 on its surface.

The RFID inlet 3 includes an IC chip 4, an RFID antenna 5 connected to the IC chip 4, and a protective material 6 for the IC chip 4.
The RFID inlet 3 is, for example, UHF band (300 MHz to 3 GHz (preferably 860 to 960 MHz, more specifically 433 MHz, 900 MHz, 915 to 928 MHz, 950 to 958 MHz) or microwave (1 to 30 GHz, specifically 2 .45 GHz), HF band (3 MHz to 30 MHz (preferably 13.56 MHz)), 135 kHz or less, and other necessary radio waves in a predetermined frequency band and electromagnetic action, etc. are required for the IC chip 4 via the RFID antenna 5. Read and write data (data communication) wirelessly.
However, the specific configurations of the IC chip 4 and the RFID antenna 5 are appropriate according to the radio waves used.
In particular, in the case of using a radio wave having a wavelength in the UHF band (for example, 860 to 960 MHz), the communication distance is usually about 5 to 10 m, and applications in various fields are expected.

    The protective material 6 is made of an arbitrary hard material such as a glass epoxy resin, and in the example shown in FIG. 9 (FIG. 9), it is configured in a circular coin shape and can protect the IC chip from various external forces applied to the entire IC chip 4. is there.

    In such a RFID tag 1 for laundry, particularly, the RFID antenna 5 is made of a metal film or conductive ink obtained by etching an extremely thin metal foil made of copper, aluminum, or the like, and has a problem that it is easily disconnected. . When attached to a laundry article, there is a problem that the RFID antenna 5 having a small thickness is easily disconnected due to stress such as bending or twisting at the time of washing, resulting in failure of the laundry RFID tag 1 itself. For this reason, the RFID antenna 5 is reinforced by various additional processes such as covering with a hard protective material 6 or potting. The protective material 6 eliminates the occurrence of problems such as breakage of the IC chip 4 and disconnection of the IC chip 4 and the RFID antenna 5 from each other.

    However, since the entire RFID tag 1 for laundry is bent or twisted as shown by the dotted line in FIG. The stress is likely to accumulate at the intersection 5A between the protective member 6 and the outer periphery of the protective material 6, and the reinforcement process is damaged, the portion of the intersection 5A is broken and the RFID antenna 5 is damaged, and the data communication function as the laundry RFID tag 1 is impaired. There is a problem that it will be. In addition, there are various problems such as cost for replacement with a new one.

    Furthermore, as a result of the loss of the data communication function of the RFID tag for laundry 1, the individual ID code stored in the IC chip 4 cannot be read, and the ID code (not shown) printed in advance so as to be visible. There is a problem in that it takes time to read and rewrite the IC chip 4 of the new RFID tag 1 for laundry.

    Note that if an RFID antenna is formed of a conductive cloth or the like, there is a possibility that an RFID tag having resistance against external force can be obtained. However, the technology for directly bonding an IC chip to this RFID antenna is not enough. The technology for forming antennas on the order of several millimeters is required, and in addition, in order to conductively bond an IC chip to such an RFID antenna, high-precision flatness is required for the antenna, and it has flexibility and durability. There is a problem that it is very difficult to realize an RFID tag having an RFID antenna.

Japanese Patent No. 4548074

    The present invention has been considered in view of the above problems, and RFID tags that can be directly attached to various fabric products such as clothes and laundry products, soft synthetic resin products, leather products, and other flexible material products. It is an object to provide an antenna.

    Another object of the present invention is to provide an RFID antenna of an RFID tag that can be easily attached to a flexible material product.

    It is another object of the present invention to provide an RFID antenna of an RFID tag that is resistant to stress such as bending or twisting during use of various clothes or laundry products or during washing.

    Another object of the present invention is to provide an RFID antenna of an RFID tag that is hard to be disconnected and has a data communication function even if it is disconnected.

    Another object of the present invention is to provide an RFID antenna of an RFID tag that is excellent in durability even when attached to various clothes, laundry items, and the like.

    It is another object of the present invention to provide an RFID antenna for an RFID tag that can realize material cost reduction, workability improvement, and mass productivity improvement.

    That is, the present invention focuses on configuring an RFID antenna with a conductive cloth, and is an RFID antenna of an RFID tag having a tag base material and capable of wireless data communication. An RFID antenna for an RFID tag, comprising an electrically conductive cloth fixed to the tag base with an antenna pattern.

    The RFID tag is provided on the tag base and has an IC chip and an RFID antenna, and has an RFID inlet capable of wireless data communication. The RFID antenna includes a resonant antenna unit connected to the IC chip. And a booster antenna portion that can be electromagnetically coupled to the resonant antenna portion and is provided at a position away from the IC chip.

    The booster antenna unit can be formed of the conductive cloth.

    The RFID inlet may have a protective material that protects the resonant antenna unit and the IC chip.

    The said protective material can comprise this from a glass epoxy resin.

    The IC chip, the resonant antenna part, and the protective material can be configured as an inlet core part that is a separate member from the booster antenna part.

    The RFID tag can be used by being attached to a flexible material product such as various clothes and laundry items (laundry items). However, the RFID tag is attached to various general products and parts and used for data management. be able to.

    In the RFID antenna of the RFID tag according to the present invention, since the RFID antenna is made of a conductive cloth having durability and flexibility, even if a torsion or other external force is applied, damage that easily occurs to the RFID antenna is avoided. In particular, even when it is attached to a flexible material product such as clothes or laundry goods, it is possible to maintain the data communication function with good durability.

It is a top view of the RFID tag 10 of the 1st example comprised using the RFID antenna 12 by the Example of this invention. 2 is a cross-sectional view of the RFID tag 10. FIG. 3 is an enlarged perspective view showing a part of the conductive cloth 17. FIG. 4 is an explanatory view of a RFID tag 30 of a second example using the RFID antenna 12 (particularly the booster antenna portion 15) according to the present invention, and FIG. 4 (1) is a cross-sectional view of a precursor laminate 30A of the RFID tag 30; FIG. 4 (2) is a cross-sectional view of the RFID tag 30. FIG. 5 is an explanatory view of a RFID tag 40 of a third example using the RFID antenna 12 (particularly the booster antenna portion 15) according to the present invention, and FIG. 5 (1) is a cross-sectional view of a precursor laminate 40A of the RFID tag 40; FIG. 5 (2) is a cross-sectional view of the RFID tag 40. It is a top view of the RFID tag 50 of the 4th example using the RFID antenna 12 (resonance antenna part 14, booster antenna part 15) by this invention. 2 is a cross-sectional view of the RFID tag 50. FIG. FIG. 8A is an explanatory view of a RFID tag 60 of a fifth example using the RFID antenna 12 (particularly the booster antenna portion 15) according to the present invention, and FIG. 8A is a cross-sectional view of a precursor laminate 60A of the RFID tag 60; FIG. 8B is a cross-sectional view of the RFID tag 60. Use RFID tags that have been proposed in the past, for example, by attaching them to various types of sheets, nightclothes and uniforms such as uniforms that are washed after use and reused in hotels and companies, etc. It is a top view which shows an example of the RFID tag 1 for laundry. It is sectional drawing of the RFID tag 1 for laundry same as the above.

    Since the present invention is composed of a conductive cloth fixed to a tag base material with a predetermined antenna pattern, it is durable even if it is attached to a flexible material product such as a cloth material or leather material that is subject to twisting or other external force. An RFID antenna for an RFID tag capable of data management has been realized.

Next, an RFID antenna 12 according to an embodiment of the present invention and a first example RFID tag 10 configured using the same will be described with reference to FIGS. However, the same parts as those in FIGS. 9 and 10 are denoted by the same reference numerals, and detailed description thereof will be omitted.
FIG. 1 is a plan view of the RFID tag 10, and FIG. 2 is a cross-sectional view of the RFID tag 10. In addition, in FIG. 2, about the part of the booster antenna part 15, the cross section along the formation path is shown.
The RFID tag 10 includes the tag base 2 and an RFID inlet 11 provided on the tag base 2.

    The tag base 2 can be attached to a flexible material product such as various clothes and laundry items, but can be attached to a product of any material as necessary.

    The RFID inlet 11 includes the IC chip 4, the RFID antenna 12, and a protective material 13, and enables wireless data communication.

The RFID antenna 12 includes a resonant antenna unit 14 and a booster antenna unit 15.
In the illustrated example, the resonant antenna unit 14 is formed of a circular metal foil or metal film, and is directly connected to the IC chip 4.
The booster antenna unit 15 can be electromagnetically coupled (radio wave coupled) to the resonant antenna unit 14, and the resonant antenna unit 14 is attached to the central portion of the booster antenna unit 15 in an overlapping manner.

The protective material 13 protects the resonant antenna unit 14 and the IC chip 4 from an external force applied to the RFID tag 10, and is made of, for example, a glass epoxy resin or other hard material.
The inlet core portion 16 composed of the protective material 13, the IC chip 4 and the resonant antenna portion 14 is configured as a separate member from the booster antenna portion 15, and the inlet core portion 16 can have resistance to bending due to external force. .

    As described above, the resonant antenna unit 14 can be formed of a metal foil, a metal film, or any other conductive material. Note that, similarly to the booster antenna unit 15 described below, the resonant antenna unit 14 can also be formed of a conductive cloth 17 (FIG. 3).

The booster antenna unit 15 as a part of the RFID antenna 12 is composed of a conductive cloth 17.
FIG. 3 is an enlarged perspective view showing a part of the conductive cloth 17, and a metal film 19 made of a metal such as copper or nickel on an arbitrary cloth base material 18 by a method such as plating, baking, vapor deposition, or sputtering. Is formed. The metal film 19 may be formed on both surfaces of the cloth substrate 18. The metal film 19 may be formed on the entire surface of the fibers constituting the cloth base 18.
As the booster antenna unit 15, the conductive cloth 17 can be processed into a predetermined antenna pattern by an arbitrary cutting method such as a blade press or laser irradiation, and has a predetermined flexibility, so that it is resistant to external forces such as bending and twisting. Have Of course, it has lightness and thinness as a cloth material, has high bending resistance, and has good fit when worn.
The booster antenna portion 15 formed of the conductive cloth 17 is fixed to one surface (for example, the surface) of the tag base 2 with an adhesive or the like. Alternatively, after the conductive cloth 17 is temporarily attached to the tag base 2 and processed into an antenna pattern, it may be fixed.

In particular, as shown in FIG. 2, an inlet core portion 16 (resonant antenna portion 14 and IC chip 4) is superposed in the thickness direction at substantially the central portion of the booster antenna portion 15, and is bonded to each other by an adhesive or any other means. It is integrated.
Therefore, there is no need to directly connect the IC chip 4 itself and the booster antenna unit 15, and the RFID tag 10 can be manufactured easily and at low cost.

In the RFID tag 10 and the RFID antenna 12 (resonant antenna unit 14 and booster antenna unit 15) having such a configuration, the resonant antenna unit 14 and the IC chip 4 are protected by the protective material 13 as the inlet core unit 16, and the booster antenna. Since the portion 15 is formed of the flexible conductive cloth 17, even if an external force is applied to the RFID tag 10 or the tag base member 2 or the booster antenna portion 15 itself to cause twisting or distortion, they are damaged. In addition, the data communication function of the RFID antenna 12 as a whole can be maintained.
That is, the resonant antenna unit 14 resonates and receives communication radio waves from a data communication reader / writer (not shown), obtains an electromotive force, activates the IC chip 4, and further electromagnetically couples to the resonant antenna unit 14. The possible booster antenna unit 15 can amplify the received radio wave, enabling data communication as the RFID tag 10.
In particular, if a radio wave having a wavelength in the UHF band (for example, 860 to 960 MHz) level is used, relatively long distance data communication is possible.
Even if the booster antenna unit 15, which is an external antenna, is damaged, near data communication by the inner inlet core unit 16 (resonant antenna unit 14) is possible.

    Thus, the RFID tag 10 and the RFID antenna 12 having extremely high durability can be obtained in various processes in the washing process of clothes and laundry items and the attachment process thereof, and the booster antenna unit 15 is made of cloth so that it can be used in the washing process. The RFID tag 10 can be made extremely thin because it does not require extra reinforcement material or additional processing to the booster antenna unit 15, reducing the feeling of foreign objects when worn on clothes, etc. And can be manufactured at low cost.

Next, in the RFID tag using the RFID antenna 12 (resonance antenna part 14 and booster antenna part 15) according to the present invention, the external force is applied by covering the inlet core part 16 and the booster antenna part 15 with a protective film or a protective layer. The resistance can be further enhanced.
That is, FIG. 4 is an explanatory diagram of the RFID tag 30 of the second example using the RFID antenna 12 (particularly, the booster antenna unit 15) according to the present invention, and FIG. 4A is a cross-sectional view of the RFID tag 30. FIG.

As shown in FIG. 4 (1), as the precursor laminate 30A, the tag base 2 made of a resin film such as polyester cloth or PET, a hot melt adhesive layer 31 applied to the surface of the tag base 2, and The booster antenna unit 15 and the inlet core unit 16 (the protective material 13, the IC chip 4, and the resonant antenna unit 14) described above are prepared.
The hot-melt adhesive is an adhesive having, for example, ethylene vinyl acetate resin or polyolefin resin as a main component, solid at room temperature, melted by heating, and thermoplasticity.

As shown in FIG. 4B, the RFID tag 30 is formed by hot pressing from the upper and lower layers of the precursor laminate 30A at a predetermined temperature and pressure.
That is, when the booster antenna portion 15 and the inlet core portion 16 are buried in the hot melt adhesive layer 31 melted by heating, the hot melt adhesive layer 31 covers the front and back surfaces of the booster antenna portion 15 and the inlet core portion 16. It will coat | cover and can protect the whole.

In the RFID tag 30 having such a configuration, the inlet core portion 16 to the RFID inlet 11 can be covered with an adhesive (hot melt adhesive layer 31) and can be fixed to the tag base 2; This can be integrated with the tag base material 2 to have higher durability.
Furthermore, since the inlet core portion 16 and the booster antenna portion 15 are covered with the hot-melt adhesive layer 31, the RFID tag 30 may have a single leaf structure or a plurality of strips such as a belt-like mount (not shown). An arbitrary label attached to the tag base 2 (or the hot-melt adhesive layer 31) can be loaded into an arbitrary printer (for example, a thermal printer, not shown) as a band-like RFID tag continuous body temporarily attached to a sheet. Arbitrary variable information can be efficiently printed on the piece 32) as necessary.

In addition, according to the RFID tag using the RFID antenna 12 (resonance antenna unit 14, booster antenna unit 15) according to the present invention, the hot melt adhesive layer 31 is laminated on either the front or back surface of the RFID tag, and the RFID tag Either one of the front and back surfaces of the inlet 11 can be covered with a synthetic resin film.
For example, FIG. 5 is an explanatory diagram of the RFID tag 40 of the third example using the RFID antenna 12 (particularly the booster antenna unit 15) according to the present invention, and FIG. FIG. 5B is a cross-sectional view of the RFID tag 40. FIG.

    As shown in FIG. 5 (1), as the precursor laminate 40A, the tag base 2 made of a resin film such as polyester cloth or PET, the hot melt adhesive layer 31 applied to the surface of the tag base 2, and The booster antenna unit 15 and the inlet core unit 16 described above, a base material 41 for coating with a resin film such as polyester cloth or PET, and a hot melt agent layer 42 for application applied to the surface of the base material 41 for coating. prepare.

As shown in FIG. 5 (2), the RFID tag 40 is obtained by hot pressing from the upper and lower layers of the precursor laminate 40A at a predetermined temperature and pressure.
That is, when the booster antenna portion 15 and the inlet core portion 16 are buried in the hot melt adhesive layer 31 melted by heating, the hot melt adhesive layer 31 covers the front and back surfaces of the booster antenna portion 15 and the inlet core portion 16. It will coat | cover and can protect the whole.
Further, the base material 41 for coating and the hot melt agent layer 42 for pasting can be laminated on the hot melt adhesive layer 31, and when the RFID tag 40 is pasted on clothes, laundry products or any other product M, for pasting. The hot melt agent layer 42 can be bonded again by heating.

    In the RFID tag 40 having such a configuration, the inlet core portion 16 to the RFID inlet 11 can be covered with an adhesive (hot melt adhesive layer 31) and can be fixed to the tag base 2; This can be integrated with the tag base material 2 to make it more durable, and further, the RFID tag 40 can be attached and fixed to the product M by the hot melt agent layer 42 for application. .

    Next, in the RFID tag using the RFID antenna 12 (resonance antenna unit 14, booster antenna unit 15) according to the present invention, the booster antenna unit 15 and the inlet core unit 16 (protective material 13, IC chip 4 and resonant antenna). The relative position with respect to the unit 14) can be changed to a different one from the RFID tag 30 (FIG. 4) and the RFID tag 40 (FIG. 5).

For example, FIG. 6 is a plan view of an RFID tag 50 of a fourth example using the RFID antenna 12 (resonant antenna unit 14, booster antenna unit 15) according to the present invention, and FIG. 7 is a cross-sectional view of the RFID tag 50. . In addition, in FIG. 7, about the part of the booster antenna part 15, the cross section along the formation path is shown.
The RFID tag 50 includes the tag base 2 and the RFID inlet 11, and the RFID inlet 11 includes the IC chip 4, the RFID antenna 12, and the protective material 13 as described above, and is wireless. Can be used for data communication.

However, as described above, the booster antenna portion 15 of the RFID antenna 12 is formed from the conductive cloth 17 (FIG. 3) with a predetermined antenna pattern, and the resonant antenna portion 14 (more precisely, the protective material 13). A small gap G is separated from the outer peripheral portion.
As the gap G, the resonant antenna unit 14 and the booster antenna unit 15 can be electromagnetically coupled to each other, and the mechanical force between the protective material 13 and the booster antenna unit 15 against distortion caused by an external force applied to the entire RFID tag 50. A range that does not cause general interference is desirable.

In particular, as shown in FIG. 7, in the state where the inlet core portion 16 (the resonant antenna portion 14 and the IC chip 4) is located at a substantially central portion of the booster antenna portion 15 and a gap G is opened between them, They are integrated with each other by any means.
Therefore, as in the RFID tag 30 (FIG. 4) and the RFID tag 40 (FIG. 5) (unlike the conventional RFID tag 1 (FIG. 9)), the connection between the IC chip 4 itself and the booster antenna unit 15 is performed. It is possible to easily manufacture at a low cost by omitting the configuration.

    In the RFID tag 50 having such a configuration, the resonant antenna unit 14 and the IC chip 4 are protected by the protective material 13 as the inlet core unit 16, and the inlet core unit 16 (resonant antenna unit 14) and the booster antenna unit 15 are connected to each other. Since a slight gap G is formed between them, even if an external force is applied to the RFID tag 50 or the tag base member 2 or the booster antenna unit 15 itself to cause twisting or distortion, the RFID antenna is not damaged. The data communication function as a whole can be maintained.

    Thus, the RFID tag 50 having extremely high durability in various processes in the washing process of clothes and laundry items and its attached processes can be obtained, and the booster antenna unit 15 is made of cloth and is extremely strong in the washing process. Since the booster antenna unit 15 does not require extra material, reinforcing material, or additional processing, the thickness of the RFID tag 50 can be made extremely thin, reducing the feeling of foreign objects when worn on clothes, etc. Manufacturing at low cost is possible.

In the RFID tag using the RFID antenna 12 (resonance antenna part 14 and booster antenna part 15) of the present invention, the inlet core part 16 and the booster antenna part 15 are covered with a protective film or a protective layer to further protect against external force. Resistance can be strengthened.
8 is an explanatory diagram of the RFID tag 60 of the fifth example using the RFID antenna 12 (particularly the booster antenna unit 15) according to the present invention. FIG. 8A is a precursor stack of the RFID tag 60. FIG. FIG. 8B is a cross-sectional view of the body 60A, and FIG.

    As shown in FIG. 8A, as the precursor laminate 60A, the tag base 2 made of a resin film such as polyester cloth or PET, and the hot melt adhesive layer 31 ( 4) and the above-described booster antenna unit 15 and inlet core unit 16 (protective material 13, IC chip 4 and resonant antenna unit 14) are prepared.

As shown in FIG. 8 (2), the RFID tag 60 is formed by hot pressing from the upper and lower layers of the precursor laminate 60 </ b> A at a predetermined temperature and pressure.
That is, when the booster antenna portion 15 and the inlet core portion 16 are buried in the hot melt adhesive layer 31 melted by heating, the hot melt adhesive layer 31 covers the front and back surfaces of the booster antenna portion 15 and the inlet core portion 16. It will coat | cover and can protect the whole.

In the RFID tag 60 having such a configuration, the inlet core portion 16 to the RFID inlet 11 can be covered with an adhesive (hot melt adhesive layer 31) and can be fixed to the tag base 2; This can be integrated with the tag base material 2 to have higher durability.
Further, since the inlet core portion 16 and the booster antenna portion 15 are covered with the hot-melt adhesive layer 31, the RFID tag 60 is configured as a single leaf or a plurality of strips such as a belt-like mount (not shown). An arbitrary label attached to the tag base 2 (or the hot-melt adhesive layer 31) can be loaded into an arbitrary printer (for example, a thermal printer, not shown) as a band-like RFID tag continuous body temporarily attached to a sheet. Arbitrary variable information can be efficiently printed on the piece 32) as necessary.

    6 and FIG. 7, the RFID tag 50 as shown in FIG. 5 has a hot melt adhesive layer 31, a covering base 41, and a surface of the covering base 41, like the RFID 40 shown in FIG. The applied hot melt agent layer 42 for application is prepared, and the inlet core portion 16 or the RFID inlet 11 can be covered with an adhesive (hot melt adhesive layer 31), and the tag base 2 This can be fixed to the tag base material 2 or can be integrated with the tag base 2 so as to be more durable.

    Further, since the inlet core portion 16 and the booster antenna portion 15 are configured as separate members, the above-described RFID tag 30 (FIG. 4), RFID tag 40 (FIG. 5), RFID tag 50 (FIG. 6), and RFID Like the tag 60 (FIG. 8), an RFID tag corresponding to various applications can be easily designed and manufactured.

1 RFID tag for laundry (conventional, Fig. 9)
2 Tag base material 3 RFID inlet 4 IC chip 5 RFID antenna 5A Intersection of RFID antenna 5 and outer periphery of protective material 6 6 Protective material 10 RFID tag using RFID antenna 12 (first example, FIG. 1)
11 RFID inlet 12 RFID antenna (Example, FIG. 1)
13 Protective Material 14 Resonant Antenna Part 15 Booster Antenna Part (Example, FIG. 1)
16 Inlet core part 17 Conductive cloth (Fig. 3)
18 Fabric base material 19 Metal film 30 RFID tag using RFID antenna 12 (second example, FIG. 4)
30A Precursor laminate 31 of RFID tag 30 Hot melt adhesive layer 32 Label strip 40 RFID tag using RFID antenna 12 (third example, FIG. 5)
40A Precursor Laminate 41 of RFID Tag 40 Covering Base Material 42 Adhesive Hot Melt Agent Layer 50 RFID Tag Using RFID Antenna 12 (Fourth Example, FIG. 6)
60 RFID tag using the RFID antenna 12 (fifth example, FIG. 8)
M Clothes, laundry supplies and other optional products (Figure 5)

Claims (1)

Having a tag substrate,
An RFID tag RFID antenna capable of wireless data communication,
The RFID tag is equipped with the tag base material and has an RFID inlet having an IC chip and an RFID antenna and capable of wireless data communication,
The RFID antenna includes a resonant antenna unit connected to the IC chip, and a booster antenna unit that is electromagnetically coupled to the resonant antenna unit and provided at a position away from the IC chip.
The booster antenna unit is a flexible conductive cloth that is fixed to the tag base material with a predetermined antenna pattern, and a metal film is formed on the cloth base material using at least one of plating, baking, vapor deposition, and sputtering. Consists of
The RFID inlet, have a protective material for protecting the resonant antenna unit and the IC chip from at least front and rear two surfaces,
An RFID antenna for an RFID tag, wherein the IC chip, the resonant antenna portion, and the protective material are configured as an inlet core portion that is a separate member from the booster antenna portion .

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