JP6922861B2 - RF tag antenna, RF tag module and RF tag label - Google Patents

Description

The present invention belongs to the technical field of managing an optical disc, which is one of the data recording media, by using an RF tag.

The use of RF tags for the management of optical discs, which are one of the data recording media (inventory management, theft prevention, unauthorized copy prevention, etc.), has been studied for some time. An optical disc is a disk-shaped data recording medium that reads and writes data using the reflection of light (laser light) by a reflective layer formed of metal foil. A typical optical disc is a CD (CD). There are Compact Disc), DVD (Digital Versatile Disk) and Blu-ray Disc (Blue-ray Disk).

A disk drive compatible with optical discs rotates the optical disc mounted on the turntable of the disc drive at high speed when reading and writing data. Therefore, the optical disc has a center hole for rotating the optical disc at high speed. It is located in the center of the disc.

Therefore, as described in the inventions disclosed in Patent Documents 1 and 2, when attaching an RF tag to an optical disc, an RF tag having a circular antenna having a diameter larger than that of the center hole is placed in a circle with the center of the center hole. It is common practice to attach the antenna to an optical disc with the center aligned. Further, in the invention disclosed in Patent Document 3, a dummy block having a mass equivalent to that of the IC chip is embedded in the target position of the IC chip of the RF tag, so that the device is mounted on the turntable of the disk drive. An invention for suppressing the occurrence of vibration and rotation unevenness of an optical disc is disclosed.

When an RF tag having a UHF band as a frequency band is used for managing an optical disc, a radiation element is required for the RF tag antenna in addition to an antenna element for impedance matching with an IC chip. In Patent Document 3, even if it is attached to an optical disk having a donut-shaped metal layer inside, the stability of operation and the reading performance of information can be improved without impairing the impedance matching with the IC chip. Possible RF tag modules are disclosed.

Japanese Unexamined Patent Publication No. 2005-339666 Japanese Unexamined Patent Publication No. 2005-71575 Japanese Unexamined Patent Publication No. 2005-209323 Japanese Unexamined Patent Publication No. 2011-166340

The RF tag antenna corresponding to the UHF band requires a radiation element in addition to the antenna element for impedance matching with the IC chip. Considering cost, it is desirable that the size of the RF tag antenna having a radiation element in addition to the antenna element for impedance matching with the IC chip can be made compact, but in the invention described in Patent Document 3, In this form, the length of the RF tag antenna in the width direction is almost the same as the diameter of the optical disk.

Therefore, the present invention can make the size compact so that the reflective layer using the metal foil can be substantially accommodated in the non-data recording portion of the optical disc formed in the data recording portion, and the medium has the metal layer such as the optical disc. The object is to provide an RF tag label that can obtain the communication performance required for media management even if it is attached to.

The first invention for solving the above-mentioned problems is at least from a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a hook-shaped crank portion, and a plate-shaped radiating element. The RF tag antenna is configured and characterized in that the meander-shaped radiating element and the plate-shaped radiating element are connected to the outside of the loop-shaped element in a state of facing each other.

Further, the second invention for solving the above-mentioned problems is a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a crank portion bent like a hook, and a plate-shaped radiating element. The meander-shaped radiating element and the plate-shaped radiating element are connected to the RF tag antenna connected to the outside of the loop-shaped element and the loop-shaped element of the RF tag antenna in a state of facing each other. It is an RF tag module characterized by having an IC chip.

Further, a third invention for solving the above-mentioned problems is a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a crank portion bent like a hook, and a plate-shaped radiating element. The meander-shaped radiating element and the plate-shaped radiating element are connected to the RF tag antenna connected to the outside of the loop-shaped element and the loop-shaped element of the RF tag antenna in a state of facing each other. The RF tag label is characterized by having a label base material on which an RF tag module having an IC chip is mounted and an adhesive layer laminated on the label base material.

According to the present invention, the plate-shaped radiating element of the RF tag antenna is electrostatically coupled to the metal layer of the medium. Therefore, by superimposing at least a part of the plate-shaped radiating element on the metal layer, the radiating element of the RF tag antenna A metal layer, such as the reflective layer of an optical disc, can be used as part of. If the metal layer can be used as a radiation element for an RF tag antenna, even if the size of the RF tag antenna is made compact enough to fit in the non-data recording section of an optical disc, it can be attached to a medium having metallic properties such as an optical disc. When attached, the communication performance required for managing media such as optical discs can be obtained.

The figure explaining the RF tag module which concerns on this embodiment. The figure explaining the RF tag label which concerns on this embodiment. The figure explaining the structure of a DVD. The figure explaining the DVD with the RF tag label attached. The figure explaining the positional relationship between the reflective layer of a DVD and an RF tag antenna. The figure explaining the RF tag module which concerns on the modification.

From here, preferred embodiments of the present invention will be described. The following description does not constrain the technical scope of the present invention, but is described to aid understanding.

According to the present invention, even if the size of the reflective layer using a metal foil is compact enough to fit in the non-data recording section of an optical disk formed in the data recording section, the communication required for managing a medium such as an optical disk is achieved. An object of the present invention is to provide an RF tag label capable of obtaining performance, and in the present invention, this problem is solved by devising an RF tag antenna mounted on the RF tag label.

From here, the RF tag module composed of at least the RF tag antenna according to the present embodiment and the IC chip connected thereto, and the RF tag label on which this RF tag module is mounted will be described, and then the effects obtained in the present invention will be described. This will be described in detail.

FIG. 1 is a diagram for explaining the RF tag module 2 according to the present embodiment, and the RF tag module 2 according to the present embodiment is at least from the RF tag antenna 1 according to the present embodiment and the IC chip 20 connected thereto. It is composed.

The frequency band used by the RF tag module 2 according to the present embodiment is the UHF band (860 to 960 Mhz), and the RF tag antenna 1 according to the present embodiment has a loop-shaped element 10, a meander-shaped radiating element 11, and a plate shape. It is a dipole antenna including three antenna elements of the radiation element 12.

The shape of the loop-shaped element 10 of the RF tag antenna 1 according to the present embodiment is a loop-shaped (substantially circular) shape, and the IC chip 20 is electrically connected to the loop-shaped element 10. The loop-shaped element 10 of the RF tag antenna 1 is an antenna element for matching the impedance with the IC chip 20 connected to the RF tag antenna 1. Since there is a capacitive reactance (capacitance) between the input terminals of the IC chip 20, the loop-shaped element 10 of the RF tag antenna 1 is looped, and the input terminal of the IC chip 20 is connected to the RF tag antenna 1. The loop element 10 is provided with an inductive reactance (inductance) corresponding to the capacitive reactance existing between them. The inductive reactance of the loop element 10 does not necessarily have to be the same as the capacitive reactance existing between the input terminals of the IC chip 20.

Two radiating elements used for power supply and signal transmission / reception are connected to the outside of the loop-shaped element 10 of the RF tag antenna 1 so as to face each other. One radiating element connected to the loop-shaped element 10 of the RF tag antenna 1 is a meander-shaped radiating element 11, and the meander-shaped radiating element 11 has a meander-like shape having a crank portion 110 in which a conducting wire is bent like a hook. .. Another radiating element connected to the loop-shaped element 10 of the RF tag antenna 1 is a plate-shaped radiating element 12, and the plate-shaped radiating element 12 has a plate-like shape similar to that of the plate electrode.

One of the radiating elements connected to the loop-shaped element 10 of the RF tag antenna 1 is the meander-shaped radiating element 11, which is the UHF frequency band used by the RF tag module 2 for the resonance frequency of the RF tag module 2. This is to make it easier to fit the band. Since the crank portion 110 included in the meander-shaped radiating element 11 has an inductive reactance, it becomes easy to design the RF tag antenna 1 so that the resonance frequency of the RF tag module 2 matches the UHF band.

As for the resonance frequency of the RF tag module 2, the resonance frequency is 840 Mhz to 920 Mhz when the optical disc to which the RF tag module 2 is attached is not overlapped, and the optical disc to which the RF tag module 2 is attached is overlapped. It is desirable that the resonance frequency in this state is changed from 920 Mhz to 1000 Mhz.

In FIG. 1, the central portion of the optical disc is shown in order to make it easy to understand the size of the antenna element constituting the RF tag antenna 1. A center hole 50 is processed in the center of the optical disc. The peripheral portion of the center hall 50 is an annular non-data recording unit 51 that is not used for data recording, and the outside of the non-data recording unit 51 is a data recording unit 52 used for data recording.

As shown in FIG. 1, the loop-shaped element 10 and the meander-shaped radiating element 11 constituting the RF tag antenna 1 are designed to fit in the non-data recording unit 51 of the optical disk. On the other hand, the plate-shaped radiating element 12 constituting the RF tag antenna 1 is designed so that at least a part of the plate-shaped radiating element 12 overlaps with the data recording unit 52 of the optical disk.

FIG. 2 is a diagram for explaining the RF tag label 3 according to the present embodiment. The RF tag label 3 according to the present embodiment is in the form of an annular seal label on which the RF tag module 2 described with reference to FIG. 1 is mounted, that is, a donut-shaped perforated seal label.

The diameter of the label hole 33 formed in the RF tag label 3 is smaller than the diameter of the loop element 10 included in the RF tag antenna 1 of the RF tag module 2 mounted on the RF tag label 3, and is a non-data recording unit of the optical disk. The RF tag module 2 is mounted on the annular portion of the RF tag label 3, which is larger than the inner diameter of 51.

The layer structure of the RF tag label 3 according to the present embodiment will be described. The RF tag label 3 according to the present embodiment has a configuration in which at least the label base material 30, the adhesive layer 31, and the release paper 32 on which the RF tag module 2 described with reference to FIG. 1 is mounted are laminated.

As the base material of the label base material 30 constituting the RF tag label 3, for example, a synthetic resin film such as polyethylene terephthalate (PET) or polypropylene (PP) can be used. It is preferable that the surface of the label base material 30 on which the RF tag module 2 is not mounted has printability for an inkjet printer.

As a method of forming the RF tag antenna 1 of the RF tag module 2 on the base material of the label base material 30, a screen that prints the shape of the RF tag antenna 1 on one side of the base material of the label base material 30 using conductive ink. A printing method or an etching method in which a metal foil formed on all or a part of the base material of the label base material 30 is etched into the shape of the RF tag antenna 1 can be used.

The adhesive layer 31 constituting the RF tag label 3 is a layer used when the RF tag label 3 is attached to an optical disc, and is laminated on the surface of the label base material 30 on which the RF tag module 2 is mounted in the present embodiment. There is. An acrylic or rubber-based adhesive that maintains adhesiveness can be used for the pressure-sensitive adhesive layer 31 that constitutes the RF tag label 3.

The release paper 32 constituting the RF tag label 3 is a layer for protecting the pressure-sensitive adhesive layer 31 constituting the RF tag label 3. As the release paper 32 constituting the RF tag label 3, a synthetic resin film or paper having a release agent such as silicone coated on the surface in contact with the pressure-sensitive adhesive layer 31 can be used.

From here, the effects of the RF tag label 3 and the like according to the present embodiment will be described with reference to an example when the optical disc is a DVD.

FIG. 3 is a diagram illustrating the structure of the DVD 4. The recording surface of the DVD 4 illustrated in FIG. 3 is only one side, and the hard protective layer 420 formed by using a UV curable resin or the like and the reflective layer 421 formed of a metal foil are formed in order from the label surface to which the RF tag label 3 is attached. A data recording layer 422 on which pits for recording data are formed, and a transparent resin layer 423 formed by using a resin such as polycarbonate are laminated.

In the DVD 4 illustrated in FIG. 3, a part of the periphery and the outer circumference of the center hole 40 formed in the center of the DVD 4 is an annular non-data recording unit 41, and the protective layer 420 is formed on the entire surface of the DVD 4. There is. The reflective layer 421, the data recording layer 422, and the transparent resin layer 423 are formed at locations corresponding to the data recording unit 42 of the DVD 4. In FIG. 3, the outer diameter of the DVD 4 is 120 mm, the inner diameter of the non-data recording unit 41 (diameter of the center hole 40) is 15 mm, and the outer diameter of the non-data recording unit 41 (diameter of the center hole 40) is 37 mm. ..

FIG. 4 is a diagram illustrating a DVD 4 in a state where the RF tag label 3 is attached. The RF tag label 3 designed based on the DVD 4 illustrated in FIG. 3 uses the adhesive layer 31 exposed by peeling off the release paper 32 to form the center of the label hole 33 of the RF tag label 3 and the center hole 40 of the DVD 4. It is attached to the DVD 4 with the center aligned.

In the RF tag label 3 designed based on the DVD 4 illustrated in FIG. 3, the loop-shaped element 10 and the meander-shaped radiating element 11 constituting the RF tag antenna 1 of the RF tag module 2 are center holes formed in the center of the DVD 4. It is designed to fit in the non-data recording unit 41 existing around the 40. On the other hand, the plate-shaped radiating element 12 constituting the RF tag antenna 1 of the RF tag module 2 is designed so that a part of the plate-shaped radiating element 12 overlaps with the data recording unit 42 of the DVD 4.

FIG. 5 is a diagram illustrating the positional relationship between the reflective layer 421 of the DVD 4 and the RF tag antenna 1. Since the reflective layer 421 of the DVD 4 exists only at the location of the data recording unit 42, the loop-shaped element 10 and the meander-shaped radiating element 11 arranged so as to fit in the non-data recording unit 41 of the DVD 4 which is the region where the reflective layer 421 does not exist. The inductive reactance of each does not change significantly even when the RF tag label 3 is attached to the DVD 4, and the communication distance of the RF tag label 3 does not significantly deteriorate.

Since a part of the plate-shaped radiating element 12 of the RF tag antenna 1 overlaps with the reflecting layer 421 of the DVD 4, the plate-shaped radiating element 12 of the RF tag antenna 1 and the reflecting layer 421 of the DVD 4 are electrically coupled. Regarding the region overlapping the reflective layer 421 of the DVD 4, the adhesive layer 31 laminated on the RF tag label 3 and the protective layer 420 of the DVD 4 are present between the plate-shaped radiating element 12 of the RF tag antenna 1 and the reflective layer 421 of the DVD 4. Therefore, the electrical coupling between the plate-shaped radiating element 12 of the RF tag antenna 1 and the reflective layer 421 of the DVD 4 becomes an electrostatic coupling.

Unless the plate-shaped radiating element 12 of the RF tag antenna 1 and the reflective layer 421 of the DVD 4 are electrostatically coupled, the reflective layer 421 of the DVD 4 does not contribute to the communication of the RF tag module 2, but the RF tag antenna 1 By electrostatically coupling the plate-shaped radiation element 12 and the reflection layer 421 of the DVD 4, the reflection layer 421 of the DVD 4 functions as a part of the radiation element of the RF tag antenna 1. Specifically, the radio wave of the reader / writer that hits the reflection layer 421 of the DVD 4 is propagated to the RF tag module 2 via the plate-shaped radiating element 12, and the radio wave carrying the signal from the RF tag module 2 is plate-shaped. It is propagated to the reflective layer 421 of the DVD 4 via the radiating element 12 and transmitted from the reflective layer 421 of the DVD 4. Therefore, the form of the RF tag module 2 in the state where the RF tag label 3 is attached to the DVD 4 is not the form shown in FIG. 1 but the form shown in FIG.

If the reflective layer 421 of the DVD 4 can be used as the radiating element of the RF tag antenna 1, the size of the radiating element of the RF tag antenna 1 (here, the meander-shaped radiating element 11 and the plate-shaped radiating element 12) can be determined by the non-data of the DVD 4. Even if it is compact enough to fit in the recording unit 41, the communication performance required for managing the DVD 4 can be obtained in the state where the RF tag label 3 is attached to the DVD 4.

The shape of the RF tag antenna 1 of the RF tag module 2 described so far is only an example, and the specific content of the RF tag antenna 1 of the RF tag module 2 depends on the specifications of the optical disk.

Finally, a modified example of the RF tag module 2 according to the present embodiment will be described. FIG. 6 is a diagram illustrating an RF tag module 6 according to a modified example. In FIG. 6, the same elements as those of the RF tag module 2 according to the present embodiment are designated by the same reference numerals. When the optical disk is read and written, it is mounted on the turntable of the disk drive corresponding to the optical disk and rotates at high speed. Therefore, in the RF tag module 6 according to the modification shown in FIG. 6, the IC chip 20 is used. A dummy pattern 60 having a mass equivalent to that of the IC chip 20 is provided at a target position. The dummy pattern 60 does not have to be electrically connected to the loop element 10 of the RF tag module 6 according to the modified example.

1 RF tag antenna 10 Loop-shaped element 11 Meander-shaped radiating element 12 Plate-shaped radiating element 2 RF tag module 20 IC chip 3 RF tag label 30 Label base material 31 Adhesive layer 32 Release paper 33 Label hole 4 DVD
40 Center hole 41 Non-data recording unit 42 Data recording unit 420 Protective layer 421 Reflective layer 422 Data recording layer 423 Transparent resin layer

Claims (3)

It is composed of at least a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a hook-shaped crank portion, and a plate-shaped radiating element, and the meander-shaped radiating element and the plate-shaped radiating element. The radiating elements are connected to the outside of the loop-shaped element while facing each other.
RF tag antenna characterized by that. It is composed of at least a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a hook-shaped crank portion, and a plate-shaped radiating element, and the meander-shaped radiating element and the plate-shaped radiating element. With the radiating elements facing each other, the RF tag antenna connected to the outside of the loop-shaped element and
The IC chip connected to the loop element of the RF tag antenna and
RF tag module characterized by having. It is composed of at least a loop-shaped element connected to an IC chip, a meander-shaped radiating element having a hook-shaped crank portion, and a plate-shaped radiating element, and the meander-shaped radiating element and the plate-shaped radiating element. With the radiating elements facing each other, the RF tag antenna connected to the outside of the loop-shaped element and
A label base material on which an RF tag module having an IC chip connected to the loop-shaped element of the RF tag antenna is mounted, and a label base material.
The adhesive layer laminated on the label substrate and
RF tag label characterized by having.

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