WO2021117314A1 - Rfig tag, tire having rfid tag included therein, and method for manufacturing rfid tag - Google Patents

Abstract

[Problem] To provide a RFID tag little affected by the relative dielectric constant of carbon black included in tire rubber even when used by being attached to or embedded in a tire. [Solution]A tire RFID tag 100 is provided with: an RF chip 10; a first element 50 formed by a braided conductor wire; a second element 60; a coupling transformer 20; and a printed board 90. A rail-like groove 65 is provided to the printed board 90. The first element 50 is disposed in the groove 65, and extends from the printed board 90. The first element 50 is connected to one end of the primary side 30 of the coupling transformer 20. The second element 60 is connected to the other end of the primary side 30 of the coupling transformer 20. The RF chip 10 is connected to the secondary side 40 of the coupling transformer 20. The number of windings of the the primary side 30 in the coupling transformer 20 is smaller than that of the secondary side 40.

Description

Manufacturing methods for RFID tags, tires with built-in RFID tags, and RFID tags

The present invention relates to an RFID tag, a tire with a built-in RFID tag, and a method for manufacturing the RFID tag.

Patent Document 1 (Re-Table 2007-083574) describes a power supply circuit board, a power supply circuit board connected to the wireless IC chip, and provided with a power supply circuit including a resonance circuit having a predetermined resonance frequency, and a power supply circuit board. Is attached or placed close to each other, and includes a radiation plate that emits a transmission signal supplied from the power supply circuit and / or receives a reception signal and supplies the reception signal to the power supply circuit. A wireless IC device is disclosed, wherein the frequency of the above substantially corresponds to the resonance frequency of the resonance circuit.

In Patent Document 2 (Japanese Unexamined Patent Publication No. 2011-097586), it is an assembly of an article body and an electronic tag, and the electronic tag is connected to and stored in an electronic device that stores unique data of the article. A type of tag that has an antenna for transmitting the data to a remote reader device, where some parts of the article consist of, at least in part, a material composition containing rubber, and the electronic device and antenna are of the article. An assembly that is attached to a portion and has external contact means, the antenna is flexible and consists of at least partially flexible conductive material, the flexible conductive material at least partially containing conductive rubber. Is described.

In Patent Document 3 (Japanese Unexamined Patent Publication No. 2017-132291), in an RFID tag built-in tire provided with an RFID chip and an antenna, the antenna is connected to a first antenna connected to the RFID chip and the outside of the first antenna. It is composed of a second antenna provided in the above and electromagnetically coupled to the first antenna, the RFID chip and the first antenna are fixed to the first fixing member, and the RFID tag is attached to the carcass ply end of the tire. A tire with a built-in RFID tag, which is arranged outside in the radial direction of the tire and has a second antenna electromagnetically coupled to a conductive carcass ply cord constituting the carcass ply, is disclosed.

Re-table 2007-083574 Japanese Unexamined Patent Publication No. 2011-097586 JP-A-2017-132291

As a non-contact type information recording / reproducing device capable of writing or reading information using radio waves, there is a passive radio frequency identification transponder (hereinafter, also referred to as an RFID tag). Tires can be managed by attaching the transponder to the tire and writing or reading information about the tire to the transponder.
For example, for tires for vehicles such as automobiles, manufacturing management, distribution management, maintenance management during tire use, manufacturing management of retread tires in which worn tread parts have been rehabilitated after the end of the primary life, and maintenance management thereof, etc. In, it is necessary to grasp the unique information of each tire such as its specifications, manufacturing history, and usage history.

By the way, the distortion in the tire generated when the vehicle is running is concentrated on the boundary surface between the covering rubber covering the electronic component such as the RFID tag and the adjacent member, and as a result, a crack is generated between the electronic component and the adjacent member. There is a risk and problems arise.
On the other hand, from the viewpoint of improving durability, if a large amount of carbon black is blended in the coating rubber that coats the electronic component, the communication performance of the RFID tag attached to the tire may be affected and communication may not be performed well.

Conventionally, most RFID tags used by embedding them in rubber products such as automobile tires use RFID tags using the half-wave dipole antenna method. However, when an RFID tag using a dipole antenna method is embedded in a rubber product containing carbon black, a resistor of several tens of KΩ to several hundreds of KΩ is connected between the two feeding points of the RFID tag. The presence between the two antenna elements of a half-wave dipole antenna greatly affects the impedance and effective electrical length of the antenna.

In addition, in a normal dipole antenna, the RF chip is placed in the center of the dipole antenna, so when the tire expands and contracts significantly, the joint between the RF chip and the two antenna wires connected to both ends of the RF chip is damaged. There is also the problem that communication will not be possible.

In addition, when an RFID tag equipped with a dipole antenna is directly embedded in the tire, the shape and electrical length of the dipole antenna change during the tire manufacturing process such as during vulcanization, and characteristics such as the communicable distance at the communication frequency of the RFID tag There is also a problem that the frequency is deteriorated.

In the wireless IC device of the invention described in Patent Document 1, a feeding circuit including a resonance circuit having a predetermined resonance frequency is arranged between the wireless IC chip and the radiation plate, and the frequencies of the transmission signal and / or the reception signal are resonated. It is configured so as to substantially correspond to the resonance frequency of the circuit.
However, since the radiation plate is electromagnetically coupled and / or capacitively coupled to the feeding circuit (see the first embodiment, FIGS. 1 to 7), the signal source impedance of the radiation plate is high, and the wireless IC device is carbon black. When embedded in a rubber product containing the above, there is a problem that characteristics such as the communicable distance of the wireless IC device are easily affected by the impedance of carbon black and the relative permittivity of the rubber product.

The assembly of the article body such as the tire rubber of the invention described in Patent Document 2 and the electronic tag is mechanically incorporated into the article by using a flexible conductive material containing conductive rubber at least partially for the antenna. It is suitable for.
However, when the electronic tag is embedded in a rubber product containing carbon black, characteristics such as the communicable distance of the wireless IC device are easily affected by the impedance of the carbon black and the relative permittivity of the rubber product, and the conductivity. When the antenna is made of rubber, there is a problem that the resistance component is larger than that of the metal antenna.

The RFID tag built-in tire of the invention described in Patent Document 3 electromagnetically couples a first antenna connected to the RFID chip and a second antenna provided outside the first antenna, and also has a second antenna. This is an RFID tag built-in tire in which the antenna of the above is electromagnetically coupled with a conductive carcass ply cord.
However, since the first antenna and the second antenna are electromagnetically coupled and the signal source impedance of the second antenna is high, when the RFID tag is embedded in a rubber product containing carbon black, There is a problem that characteristics such as the communication range of RFID tags are easily affected by the impedance of carbon black and the relative permittivity of rubber products.

A main object of the present invention is to provide an RFID tag which is less affected by carbon black contained in a tire and the relative permittivity of the tire and has excellent communication characteristics even when used by being attached or embedded in a tire. It is to be.
A second object of the present invention is to provide an RFID tag that can be easily attached to or embedded in a tire.
A third object of the present invention is to provide an RFID tag having improved durability while maintaining or improving the communication performance of the RFID tag, and to provide a method for manufacturing the RFID tag.

(1)
An RFID tag according to one aspect includes an RF chip, a first element formed by braiding a conductor, a second element, a coupling transformer, and a printed circuit board, and a guide portion is provided on the printed circuit board. One element is arranged in the guide portion and extends from the printed circuit board, the first element is connected to one end on the primary side of the coupling transformer, and the second element is connected to the other end on the primary side of the coupling transformer. , The RF chip is connected to the secondary side of the coupling transformer, and the number of windings on the primary side of the coupling transformer is smaller than the number of windings on the secondary side.

In this case, by making the number of windings on the primary side of the coupling transformer smaller than the number of windings on the secondary side, the primary side to which the first element and the second element are connected is input with low impedance, and 2 The next side can be converted to high impedance to match the input impedance of the RF chip.
Further, the guide portion provided on the printed circuit board stabilizes the positional relationship between the printed circuit board and the first element.
Further, since the first element is formed of the braided wire (knitted copper wire, braided wire) of the conductor, even if the tire is greatly deformed, all the braided wires will not be broken at once, so that communication is maintained. It can be made and has excellent durability.
When the RFID tag of the present invention is attached to a rubber product such as a tire, the rubber product such as a tire is grounded by electrically connecting the second element to the rubber product such as a tire having an impedance. Because it functions as, it is possible to communicate with high sensitivity. Therefore, when attached to a rubber product such as a tire, an RFID tag having excellent communication characteristics can be obtained.

(2)
The RFID tag according to the second invention is an RFID tag according to one aspect, in which a guide portion is provided on the first surface of the printed circuit board, the second element is provided on the first surface of the printed circuit board, and the RF chip and the coupling transformer are provided. It is provided on the second surface of the printed circuit board, and the guide portion is provided with a plurality of through holes for connecting the first surface and the second surface of the printed circuit board, and the first element is the primary element of the coupling transformer through the through holes. Connected to one end on the side, one side end and the other side end of the first element extend outward from the end face of the printed circuit board, and the extension length of the other end is 1 of the total length of the first element. It may be 1/10 or less.

In this case, since one end of the first element extends greatly from the printed circuit board and most of the first element extends in one direction from the printed circuit board, the antenna of the RFID tag uses the second element as the ground plane and the second element. The operation is similar to that of a monopole antenna with one element as the antenna wire, and it shows good characteristics as an antenna.

Further, when the RFID tag is attached to or embedded in the vulcanized rubber tire, the ground plane is further strengthened by electrically connecting the second element to the vulcanized rubber tire.
Further, since each member can be arranged on the printed circuit board at a high density, the size of the printed circuit board can be effectively reduced. As a result, it is possible to obtain an RFID tag that is hard to be damaged or peeled off and has excellent durability even when attached to a rubber product such as a tire that is deformed.

(3)
The RFID tag according to the third invention is the RFID tag according to the first aspect or the second invention, in which the second element is formed of a rectangular conductor and the surface is exposed on the surface of the printed circuit board. The next side and the RF chip may be sealed with a resin layer.

In this case, by making the second element rectangular and exposing the surface, the impedance between the second element and the vulcanized rubber tire can be lowered when the RFID tag is attached to or embedded in the vulcanized rubber tire. it can. Further, by sealing the secondary side of the coupling transformer and the RF chip with a resin layer, the physical strength of the RFID tag can be increased.

(4)
In the RFID tag according to the fourth invention, in the RFID tag according to the third aspect to the third invention, when the wavelength of the radio wave at the communication frequency of the RFID tag is λ, the electric length of the first element is λ / 4, λ. It may be / 2, (3/4) λ, (5/8) λ.

In this case, by setting the electrical length of the first element to λ / 4, λ / 2, (3/4) λ, and (5/8) λ, the resonance frequency of the first element matches the communication frequency of the RFID tag. The communication distance of the RFID tag can be extended.

(5)
The RFID tag according to the fifth invention is the RFID tag according to the fourth aspect to the fourth aspect. In the RFID tag according to the fourth aspect, the guide portion for arranging the first element at a fixed position may be provided with a rail-shaped groove on the printed circuit board.

When a coupling transformer is used between the RF chip and the first and second elements, the impedance is converted in proportion to the square of the winding number ratio of the coupling transformer. For example, if the impedance on the primary side of the coupling transformer, that is, between the first and second elements is 100Ω, and the number of windings on the secondary side is four times the number of windings on the primary side, the coupling transformer The impedance on the secondary side of is 1.6 kΩ. Therefore, the ratio of the number of windings of the coupling transformer is basically set so that the input impedance of the RF chip and the impedance between the first and second elements are matched. However, increasing the number of windings on the secondary side has restrictions such as the area of the coupling transformer, and the ratio of the number of windings on the secondary side to the primary side is from 3: 1 to 6: 1. It is desirable to be between. ‥

(6)
The RFID tag according to the sixth invention is the RFID tag according to the fifth aspect to the fifth invention, in which four terminals are provided on the secondary side of the coupling transformer, and the RF chip is sealed in a BGA package to form the coupling transformer. It is placed on the surface of the secondary side, and depending on the placement angle of the RF chip, the terminal of the RF chip and one of the two terminals of the four terminals or the other two terminals are connected, and the RF chip is formed. , The number of windings on the secondary side of the coupling transformer may be different depending on whether the transformer is connected to one of the two terminals or the other two terminals.

In this case, the winding number ratio of the coupling transformer can be changed simply by changing the arrangement angle of the same RF chip using the same printed circuit board. Therefore, for example, when it is desired to change the impedance on the primary side of the coupling transformer depending on the material of the rubber of the tire to be attached or embedded, the impedance on the primary side is changed by changing the arrangement angle of the RF chip. There is an advantage that it can be done.

(7)
The RFID tag according to the seventh invention further includes a first insulator and a second insulator laminated on the printed circuit board in the RFID tag according to the first aspect to the sixth invention, and includes the first insulator, the printed circuit board, and the RFID tag. The second insulator is laminated in this order, and the second element may be electrically connected to the tire via the second insulator.

In this case, the printed circuit board is coated with the first insulator and the second insulator, so that even when the tire rubber expands and contracts, such as when the automobile is running, the printed circuit board is fixed to the groove of the first element formed by the braided wire. And the conductive connection with the through hole can be stabilized. Therefore, the durability of the RFID tag is increased. Further, since the first element formed by the braided wire of the conductor is also covered, the braided wire is not easily deformed even when it is attached to the tire, so that the RFID tag can be easily attached and has excellent communication characteristics.
Further, by covering the first element with the first insulator, it is possible to obtain an RFID tag whose antenna length is not easily affected by the dielectric constant of the rubber of the tire.

(8)
In the RFID tag according to the eighth invention, the second insulator may be a butyl rubber sheet in the RFID tag according to the seventh invention.

In this case, since the butyl rubber has high adhesion to the braided wire, the first element can be stably fixed.
In addition, butyl rubber has excellent adhesion to vulcanized rubber and maintains adhesion even when subjected to vibration, expansion or contraction or thermal shock for a long period of time, so it can be used as an RFID tag that does not easily peel off even when attached to the rubber surface of a tire. can do.
Further, by measuring the communication characteristics with the RFID tag sandwiched between the butyl rubber sheet and the second insulator, the communication characteristics of the RFID tag when the RFID tag is attached to the tire or embedded in the tire can be confirmed. There is also the advantage of being able to.
Further, since the second element is electrically connected to the tire via the second insulator, the second element and the tire can be electrostatically coupled. Therefore, it is possible to obtain an RFID tag having improved durability while maintaining or improving the communication performance of the RFID tag.
When embedding the RFID tag in the tire, it is desirable to use a rubber sheet of vulcanized rubber as the second insulator.

(9)
In the RFID tag according to the ninth invention, the material of the first insulator and the second insulator may be the same material as the tire in the RFID tag according to the seventh invention.

In this case, since the first insulator and the second insulator are made of the same material as the tire, they can be easily embedded with the tire. Further, in the case of vulcanization, it can be embedded and integrated.

(10)
The RFID tag according to the tenth invention may be used for sticking to the inside of a tire or embedding it in the rubber of a tire in the RFID tag according to the ninth aspect to the ninth aspect.

RFID tag attached or embedded in the tire. In this case, the tire can be managed by the function of the RFID tag.

(11)
The RFID tag built-in tire according to the eleventh invention may have the RFID tag according to the tenth invention from one aspect attached to the inside of the tire or embedded in the rubber of the tire.

It is a tire with an RFID tag attached. In this case, the tire can be managed by the function of the RFID tag.

(12)
The method for manufacturing an RFID tag according to the twelfth invention includes a braided roll, a butyl rubber roll, a tag stacker, a second rubber roll, an idler, and a cutter to provide an RFID tag according to the eighth invention. This is a manufacturing method in which the knitted wire sent from the braided roll is superposed on the butyl rubber sheet sent out from the butyl rubber roll, and the knitted wire is arranged on the guide portion of the printed substrate by a tag stacker to form the knitted wire. A step as the first element, a step of arranging the second rubber sheet sent from the second rubber roll on the printed substrate on which the braids on the butyl rubber sheet are arranged, the butyl rubber sheet, the printed substrate, and the first A step of crimping the 1 element and the second rubber sheet through an idler, and a step of cutting and individualizing the RFID tag that has been crimped and integrated with the butyl rubber sheet and the second rubber sheet. Including.

In this case, the arrangement of the braided wire as the first element on the printed circuit board, the adhesion of the butyl rubber sheet, the printed circuit board on which the braided wire is arranged, and the second rubber sheet, and the individualization of the adhered RFID tag. Can be performed in a continuous assembly line.
The printed circuit board according to the twelfth invention is equipped with a second element, a coupling transformer, and an RF chip.

(13)
The method for manufacturing an RFID tag according to a thirteenth invention comprises a tag supply roll, an idler, and a take-up roll instead of a tag stacker in the method for manufacturing an RFID tag according to the twelfth invention, from a butyl rubber roll. The braided wire sent from the braided roll and the printed circuit board in the taped state sent out from the tag supply roll are superposed on the sent butyl rubber sheet, and the braided wire is arranged on the guide portion of the printed circuit board with an idler. It may include a step in which the braided wire is the first element.

In this case, the RFID tag can be manufactured using the printed circuit board in the taping state.

(14)
In the method for manufacturing an RFID tag according to the fourteenth invention, a first rubber sheet is sent out from a roll around which a first rubber sheet made of a butyl rubber sheet is wound, and is sent out from a braided roll onto the first rubber sheet. The process of stacking the braided wires, the process of stacking the printed substrates on the first rubber sheet so that the braids are arranged on the guide portion formed on the first surface of the printed substrate, and the process of stacking the printed substrates on the second surface of the printed substrate. , The step of stacking the second rubber sheet sent from the second rubber sheet roll, the first rubber sheet, the printed substrate, the braided wire, and the second rubber sheet are laminated in this order. It includes a step of pressurizing the body and a step of cutting the laminated body.

In this case, the arrangement of the braided wire on the printed circuit board, the adhesion of the butyl rubber sheet, the printed circuit board on which the braided wire is arranged, and the second rubber sheet, and the individualization by cutting the adhered RFID tag. Can be performed in a continuous assembly line.

(15)
In the method for manufacturing an RFID tag according to the fifteenth invention, in the method for manufacturing an RFID tag according to the fourteenth invention, the step of stacking a printed circuit board on a first rubber sheet is performed from a stacker in which a plurality of printed circuit boards are laminated. , The step of sequentially supplying the printed circuit board onto the butyl rubber sheet, may be included.

In this case, since the RFID tag can be performed in a sheet-like continuous assembly line, it can be a highly productive method for manufacturing the RFID tag.

(16)
In the method for manufacturing an RFID tag according to the sixteenth invention, in the method for manufacturing an RFID tag according to the fourteenth or fifteenth invention, the step of stacking the printed circuit board on the first rubber sheet causes the printed circuit board to be intermittently attached. The step of transferring the printed circuit board to the butyl rubber sheet by stacking the tape on the butyl rubber sheet and crimping it may be included.

In this case, the RFID tag can be manufactured using the printed circuit board in the taping state. Moreover, mass production can be easily realized.

(17)
The method for manufacturing an RFID tag according to the seventeenth invention includes a braided roll, a butyl rubber roll, a tag stacker, a second rubber roll, an idler, and a cutter, and comprises the RFID tag according to the eighth invention. A step of stacking a printed substrate from a tag stacker on a butyl rubber sheet sent from a butyl rubber roll, arranging a knitted wire on a guide portion of the printed substrate, and using the knitted wire as a first element. A step of arranging the second rubber sheet sent from the second rubber roll on the printed substrate and the braided wire on which the braided wire is arranged on the butyl rubber sheet, the butyl rubber sheet, the printed substrate, and the first element. This includes a step of crimping the second rubber sheet through an idler, and a step of cutting and individualizing the RFID tag that has been crimped and integrated with the butyl rubber sheet and the second rubber sheet. ..

In this case, the arrangement of the braided wire as the first element on the printed circuit board, the adhesion of the butyl rubber sheet, the printed circuit board on which the braided wire is arranged, and the second rubber sheet, and the individualization of the adhered RFID tag. Can be performed in a continuous assembly line.
The printed circuit board according to the seventeenth invention is equipped with a second element, a coupling transformer, and an RF chip.

(18)
In the method for manufacturing an RFID tag according to the eighteenth invention, a first rubber sheet is sent out from a roll around which a first rubber sheet made of a butyl rubber sheet is wound, and a second rubber sheet of a printed circuit board is placed on the first rubber sheet. The process of placing the surface, the process of arranging the braided wire sent from the braided roll so that the braided wire is arranged on the guide portion formed on the first surface of the printed circuit board, the braided wire and the printed circuit board. The step of stacking the second rubber sheet sent from the second rubber sheet roll on the first surface, the first rubber sheet, the printed circuit board, the braided wire, and the second rubber sheet are laminated in this order. It includes a step of pressurizing the laminated body and a step of cutting the laminated body.

In this case, since the RFID tag can be performed in a sheet-like continuous assembly line, it can be a highly productive method for manufacturing the RFID tag.

(A)
The RFID tag according to still another aspect is the RF chip, the second element, the printed circuit board provided with the rail-shaped groove, and the first element formed by the braided wire of the conductor, which is arranged in the groove of the printed circuit board. The first element is connected to one end on the primary side, the second element is connected to the other end on the primary side, the RF chip is connected to the secondary side, and the number of windings on the primary side is increased. It includes a coupling transformer, which is smaller than the number of windings on the secondary side.

It is a schematic front view of the RFID tag seen from the first side of the printed circuit board. It is a schematic plan view seen from the 1st surface side of the printed circuit board. It is a schematic rear view seen from the 2nd surface side of the printed circuit board. It is a schematic cross-sectional view of the printed circuit board when it is cut along the aa'line of FIG. It is an equivalent circuit diagram of an RFID tag. It is a schematic drawing which shows the connection between the RF chip and the secondary side of the coupling transformer when the RF chip is arranged at the 1st angle. FIG. 5 is a schematic drawing showing a connection between an RF chip and a secondary side of a coupling transformer when the RF chip is arranged at a second angle orthogonal to the first angle. It is a schematic plan view of the RFID tag in the state of being adhesively arranged on the butyl rubber sheet, viewed from the second surface side of the printed circuit board. FIG. 5 is a schematic cross-sectional view of a rubber-coated RFID tag viewed from the side, in a state where the RFID tag is sandwiched between a butyl rubber sheet and a second rubber sheet. It is a figure which shows an example of the frequency characteristic of the communicable distance of an RFID tag measured by sticking a rubber-coated RFID tag on the inside of a tire. It is a schematic cross-sectional view which shows the state which attached the rubber-coated RFID tag to the inside of a tire. It is a schematic diagram which shows an example of the manufacturing line of a rubber-coated RFID tag. It is a schematic drawing which shows a part of the production line in the case of manufacturing a rubber-coated RFID tag using an RFID tag in a taping state. It is a schematic cross-sectional view which shows the other example of FIG. It is a schematic diagram which shows another example of the production line of a rubber-coated RFID tag. It is a schematic diagram of a frequency and a communication distance when an RFID tag is attached to a tire.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are designated by the same reference numerals. Moreover, in the case of the same code, their names and functions are also the same. Therefore, the detailed description of them will not be repeated.

(First Embodiment)
FIG. 1 is a schematic front view of the RFID tag 100 as viewed from the first surface 91 side of the printed circuit board 90, and the RFID tag 100 including the first element 50, the second element 60, and the printed circuit board 90 of the antenna. Is shown. FIG. 2 is a schematic plan view seen from the first surface 91 side of the printed circuit board 90, FIG. 3 is a schematic rear view seen from the second surface 92 side of the printed circuit board 90, and FIG. 4 is FIG. It is a schematic cross-sectional view when the printed circuit board 90 is cut along the aa'line. Further, FIG. 5 is an equivalent circuit diagram of the RFID tag 100.

As shown in FIGS. 1 to 4, a rail-shaped groove 65 (see FIG. 4) is formed on the first surface 91 of the printed circuit board 90 formed in a rectangular parallelepiped shape, and a rectangle is formed on the first surface 91 of the printed circuit board 90. A second element 60 formed of a rectangular parallelepiped conductor is provided. A plurality of through holes 70 are provided at the bottom of the groove 65. The plurality of through holes 70 can be provided at appropriate intervals. In this embodiment, five through holes 70 are provided, but two or more are preferable, and four or more are more preferable. A first element 50 formed by braiding a conductor is arranged in the groove 65.

Here, the fact that the first element 50 is arranged in the groove 65 does not matter as long as the first element 50 and the through hole 70 are electrically connected. For example, the first element 50 having deformability may be press-fitted into the groove 65, and the first element 50 is arranged in the groove 65 and a part of the butyl rubber sheet 120 enters the groove 65 to enter the first element. The 50 and the through hole 70 may be electrically connected, or may be capacitively coupled.
The first element 50 is arranged in the groove 65, and one side end portion and the other side end portion of the first element 50 are in a state of extending outward from the printed circuit board 90. In the case of the present embodiment, the extended length of one side end is about 1/10 of the total length of the first element 50, and the extended length of the other side end is about 4/5 of the total length of the first element 50. is there. The extending direction of the other end of the first element 50 is substantially along the longitudinal direction of the printed circuit board 90.

(First element 50)
As the braided wire used for the first element 50, a wire (including a net wire) formed by knitting an arbitrary metal wire such as a copper wire, an iron wire, and a brass wire can be used. In addition, other flexible and conductive metal materials (eg, tape-like, ribbon-like, etc.) can also be used.
Since the braided wire is composed of a set of a plurality of metal wires, the components of the butyl rubber sheet 120 (see FIG. 9) permeate into the inside of the braided wire, the braided wire is integrated with the butyl rubber sheet 120, and the RFID tag 100 is formed. It is possible to reliably prevent peeling from the butyl rubber sheet 120 and the tire 160 (see FIG. 11).

Further, by forming the first element 50 by braiding, the first element 50 can be bent, twisted, deformed, and the like. Therefore, when the tire 160 is deformed or vibrated, the first element 50 follows the deformation and vibration of the tire 160, so that the first element 50 is prevented from being broken and the connection portion with the printed circuit board 90 is formed. Peeling is also suppressed.

The second element 60 can be formed of a metal pattern, a metal foil, a metal plate, or the like. The surface of the second element 60 is exposed on the surface of the printed circuit board 90 in order to lower the impedance with the tire 160. The size of the second element 60 is not limited, but in the case of the present embodiment, it has a rectangular shape of about 5.5 mm × 2.5 mm. The shape of the second element 60 does not necessarily have to be rectangular, and may be, for example, circular. However, in order to lower the connection impedance between the second element 60 and the tire 160, the area of the second element 60 ^{is preferably 3 mm 2} or more, and more preferably 5 mm ² or more.

Next, the RF chip 10 and the coupling transformer 20 are provided on the second surface 92 of the printed circuit board 90. The two terminals on the primary side 30 of the coupling transformer 20 are the first element 50 and the second element, respectively, via the through holes 70 provided at the bottom of the groove 65 and the through holes 80 provided at the printed circuit board 90. It is connected to 60. Further, the two terminals of the secondary side 40 of the coupling transformer 20 are respectively connected to the terminals of the RF chip 10 by wire bonds.
In the present embodiment, the case where the primary side 30 and the secondary side 40 of the coupling transformer 20 are both provided on the second surface 92 of the printed circuit board 90 will be described, but the present invention is not limited to this. The side 30 and the secondary side 40 may be provided on different surfaces of the printed circuit board 90 to form a coupling transformer 20, or a plurality of printed circuit boards 90 may be laminated and provided on different layers.

The RF chip 10 is adhered to the surface of the secondary side 40 of the coupling transformer 20 or to the printed circuit board 90 by an adhesive such as an epoxy-based die bond material. Further, the secondary side 40 of the coupling transformer 20 and the RF chip 10 are sealed with a resin layer.
As the resin layer, an insulating resin such as an epoxy resin, an acrylic resin (a resin containing an acrylic resin and a derivative as a main component), and a urethane resin can be used.
As the RF chip 10, a commercially available product that is generally used can be used, and it is particularly preferable to use one that has resistance to a vulcanization temperature of about 120 ° C.
As shown in FIG. 9, the RFID tag 100 of the present embodiment is usually attached to the tire 160 in a state of being sandwiched between the first rubber sheet 120 made of a butyl rubber sheet and the second rubber sheet 130. Used with or embedded.

The specific configuration is as follows.
An RFID tag 100 is arranged between the first rubber sheet 120 and the second rubber sheet 130, and the first rubber sheet 120, the RFID tag 100, and the second rubber sheet 130 are laminated in this order. An RFID tag (hereinafter, also referred to as a rubber-coated RFID tag 150) is formed by crimping the body and covering it with rubber. Here, the first element 50 and the first surface 91 of the printed circuit board 90 are arranged on the first rubber sheet 120 side, and the first element 50 and the second surface 92 of the printed circuit board 90 are the second rubber sheet 130. The RFID tag 100 is sandwiched between the first rubber sheet 120 and the second rubber sheet 130 so as to be arranged on the side. In the obtained rubber-coated RFID tag 150, the first surface 91 of the printed circuit board 90 is coated with the first rubber sheet 120, and the second surface 92 is coated with the second rubber sheet 130.

(First rubber sheet 120)
The first rubber sheet 120 used in the present invention is formed by forming a rubber composition containing butyl rubber into a sheet. For example, the first rubber sheet 120 having a predetermined size can be easily obtained by rolling the rubber composition with a roll or the like into a long sheet and cutting the sheet into a predetermined shape and size.
The content of butyl rubber in the first rubber sheet 120 is preferably 50% by weight or more, and is in the range of 70% by weight or more and 95% by weight or less in order to improve adhesiveness, gas permeability and the like. Is even more preferable. The rubber composition can contain butyl halogenated rubber, diene-based rubber, epichlorohydrin rubber and the like.
Examples of the diene rubber include natural rubber (NR), isoprene rubber (IR), styrene-butadiene copolymer rubber (SBR), acrylonitrile-butadiene rubber (NBR), and chloroprene rubber (CR). These diene rubbers may be used alone or in combination of two or more.

The first rubber sheet 120 further contains a compounding agent usually used in the rubber industry, for example, a reinforcing filler, a softening agent, an antiaging agent, an anti-scorch agent, zinc oxide, stearic acid, etc., depending on the purpose. It can be appropriately blended. Commercially available products can be preferably used as these compounding agents. The thickness of the first rubber sheet 120 is arbitrary, but can be in the range of 5 μm or more and 500 μm or less, and particularly preferably 10 μm or more and 200 μm or less.
Since the first rubber sheet 120 is usually an unvulcanized rubber sheet and has excellent adhesiveness, it can be used as an inner liner member of, for example, a pneumatic tire 160.

(Second rubber sheet 130)
The second rubber sheet 130 is formed by forming a second rubber composition containing rubber into a sheet. For example, the second rubber sheet 130 having a predetermined size can be easily obtained by rolling the second rubber composition with a roll or the like into a long sheet and cutting the sheet into a predetermined shape and size. Can be done.
As the type of rubber, one or more of the conventionally widely used natural rubber and / or various synthetic rubbers can be appropriately selected and used.
Specific examples of the synthetic rubber include nitrile rubber (NBR), butadiene rubber (BR), isoprene rubber (IR), styrene butadiene rubber (SBR), butyl rubber (IIR), halogenated IIR, and ethylene propylene diene rubber ( EPDM), chloroprene rubber (CR), ethylene propylene rubber, acrylonitrile butadiene rubber and the like.

As the second rubber composition, the above-mentioned first rubber composition can be used, but it is preferable that the second rubber composition contains a cross-linking agent. As such a cross-linking agent, any kind of cross-linking agent usually used for cross-linking a rubber composition can be used. For example, sulfur, organic peroxides, organic sulfur compounds and the like can be mentioned. The blending amount of the cross-linking agent can be usually 0.1 parts by weight or more and 10 parts by weight or less, preferably 1 part by weight or more and 5 parts by weight or less with respect to 100 parts by weight of the rubber component.

Further, various rubber additives such as a vulcanization accelerator, a filler, an oil, and an antiaging agent, which are usually used in the rubber industry, can be appropriately blended in the rubber composition.
Examples of the vulcanization accelerator include stearic acid, N-cyclohexyl-2-benzothiazyl sulfenamide (CZ), N, N'-dicyclohexyl-2-benzothiazolyl sulfenamide (DZ), and di-2. -Benzothiazolyl disulfide (DM) and the like can be mentioned. These may be used alone or in combination of two or more. The blending amount of the vulcanization accelerator can be usually 0.1 parts by weight or more and 10 parts by weight or less, preferably 1 part by weight or more and 3 parts by weight or less with respect to 100 parts by weight of the rubber component.

Examples of the filler include carbon black, silica, calcium carbonate, calcium sulfate, talc, clay, mica, zinc oxide, barium sulfate, titanium oxide and the like, and these may be used alone or in combination of two. The above can be used together. The blending amount of the filler can be usually 10 parts by weight or more and 200 parts by weight or less, preferably 30 parts by weight or more and 150 parts by weight or less with respect to 100 parts by weight of the rubber component.

Examples of oils include paraffin-based, naphthen-based, aromatic process oils, ethylene-α-olefin co-oligomers, paraffin wax, liquid paraffin and other mineral oils, sesame oil, cottonseed oil, linseed oil, rapeseed oil, soybean oil, and the like. Oils such as palm oil, palm oil, vegetable oil such as peanut oil can be used. These can be used alone or in combination of two or more. The blending amount of the oil can be usually 0.1 parts by weight or more and 100 parts by weight or less, preferably 1 part by weight or more and 50 parts by weight or less with respect to 100 parts by weight of the rubber component.

Examples of the anti-aging agent include naphthylamines such as phenyl-α-naphthylamine; diphenylamines such as octyldiphenylamine; N-isopropyl-N'-phenyl-p-phenylenediamine, N- (1,3-dimethylbutyl)-. P-phenylenediamines such as N'-phenyl-p-phenylenediamine, N, N'-di-2-naphthyl-p-phenylenediamine; polymers of 2,2,4-trimethyl-1,2-dihydroquinoline. Kinolin type such as; 2,6-di-t-butyl-4-methylphenol, styrenated phenol, tetrakis- [methylene-3- (3', 5'-di-t-butyl-4'-hydroxyphenyl)) Propionate] Examples include phenolic antioxidants such as methane. The blending amount of the antiaging agent can be usually 0.1 parts by weight or more and 20 parts by weight or less, preferably 0.5 parts by weight or more and 10 parts by weight or less, based on 100 parts by weight of the rubber component.
These additives may be added to the rubber composition of the first rubber sheet 120.
The thickness of the second rubber sheet 130 is arbitrary, but can be in the range of 5 μm or more and 500 μm or less, and particularly preferably 10 μm or more and 200 μm or less.

When the second rubber sheet 130 contains an vulcanizing agent and is an unvulcanized rubber sheet that is cured by heating, in order to produce the vulcanized sheet by heating, the second rubber sheet 130 is usually used at 120 ° C. As described above, it is preferable to heat and vulcanize at a temperature of 125 ° C. or higher and 200 ° C. or lower, more preferably 130 ° C. or higher and 180 ° C. or lower. A vulcanized sheet is obtained by this heating. This heating / vulcanization treatment is usually performed when the tire is vulcanized.
In this way, when the second rubber sheet 130 is heated and vulcanized during vulcanization of the tire, the rubber-coated RFID tag 150 is heated with the first rubber sheet 120 side adhered to the inner surface of the tire 160. -Vulcanization can be performed.

(Tire 500 with built-in RFID tag)
FIG. 11 is a schematic cross-sectional view showing a state in which the rubber-coated RFID tag 150 is attached to the inside of the tire 160, and shows the RFID tag built-in tire 500 in which the rubber-coated RFID tag 150 described later is attached to the tire 160. .. The rubber-coated RFID tag 150 may be attached to the inside of the tire 160 or may be embedded in the rubber of the tire 160.
In the present embodiment, the rubber-coated RFID tag 150 is attached to the tire 160, but the RFID tag 100 may be attached to the tire 160. The tire 160 is typically a tire containing carbon black, which affects the impedance of the tire.
By attaching the RFID tag 100 or the rubber-coated RFID tag 150 to the tire 160, the second element 60 is electrically connected to the tire 160, so that the tire 160 functions as a ground of the RFID tag 100. Therefore, the RFID tag 100 or the rubber-coated RFID tag 150 of the present invention can communicate with high sensitivity even when attached to the tire 160. The connection between the second element 60 and the tire 160 may be a capacitance connection or may be a direct connection.

(Tire 160)
The tire 160 that can be used in the present invention is not particularly limited, but is usually a rubber pneumatic tire, typically a tire 160 containing carbon black. The RFID tag 100 is embedded or attached to the inner peripheral surface side of the tire 160. The vehicle to which the tire 160 is attached is not particularly limited, and examples thereof include automobiles, motorcycles, bicycles, construction machines, and airplanes.
In FIG. 11, the tire 160 includes a wheel rim 161, a sidewall 166 and a tread 165, with a bead wire 162, a carcass 163 and a breaker cord 164 embedded therein.
The tire 160 contains a rubber component (natural rubber, synthetic rubber), carbon black, a vulcanizing agent, a filler, and the like. Generally, carbon black is blended with respect to 100 parts by weight of rubber in an amount of 40 parts by weight or more and 60 parts by weight or less, particularly 45 parts by weight or more and 55 parts by weight or less.
The RFID tag 100 is attached to the inner peripheral surface of the tire 160 by using the first rubber sheet 120. The first rubber sheet 120 has adhesiveness, and the first rubber sheet 120 is mixed with the bleed component even when it comes into contact with the bleed component (oil and fat component, etc.) that bleeds from the inside of the tire 160. Can be done. As a result, the RFID tag 100 can be attached to the inner surface of the tire 160 for a long period of time.
The RFID tag 100 may be attached to the inner peripheral surface of the portion of the tire 160 where the tread pattern is arranged, or may be attached to the inner peripheral surface of the bead portion of the tire 160.

Next, refer to the equivalent circuit diagram of the RFID tag 100 of FIG. For example, at the time of reception, the radio waves received by the first element 50 and the second element 60 are transmitted to the RF chip 10 via the coupling transformer 20. In this case, the impedance of the RF chip 10 is about several kΩ to 10 kΩ, while the impedance between the first element 50 and the second element 60 is as small as about 100 Ω.

The small impedance between the first element 50 and the second element 60 is due to the influence of the resistance component of carbon black contained in the second rubber sheet 130 and the tire 160 around it, in addition to the impedance of the antenna itself. large. The vulcanized rubber tire 160 has a resistivity of about several tens of kΩ · cm depending on the type of tire. On the other hand, the RF chip 10 has an impedance of about several kΩ to 10 kΩ.
Therefore, when the RFID tag 100 of the present embodiment is embedded in the vulcanized rubber tire 160, if the terminals of the RF chip 10 are directly connected to the first element 50 and the second element 60, the received radio waves are efficiently transmitted to the RF chip 10. I can't guide you.

A coupling of a winding number ratio n between the RF chip 10 having an input impedance Z and the first element 50 and the second element 60, which is obtained by dividing the number of windings on the secondary side 40 by the number of windings on the primary side 30. When connected via the transformer 20, the impedance of the primary side 30 of the coupling transformer 20 is Z / n ² .
Therefore, in the RFID tag 100 of the first embodiment, the primary side of the coupling transformer 20 is adjusted by adjusting the ratio of the number of windings on the secondary side 40 of the coupling transformer 20 to the number of windings on the primary side 30. 30 is input with low impedance, and the secondary side 40 is converted to high impedance to match the input impedance of the RF chip 10.
However, increasing the number of windings on the secondary side 40 has restrictions such as the area of the coupling transformer 20, and the ratio of the number of windings on the secondary side 40 and the primary side 30 is the specification of the IC chip. , Or it is preferable to adjust according to the material of the tire, the content of carbon black, and the like.

In the case of the present embodiment, the first element 50 extends in one direction from the printed circuit board 90, and the antenna of the RFID tag 100 is a monopole antenna in which the second element 60 is the ground plane and the first element 50 is the antenna wire. The operation is similar.
Therefore, by setting the wavelength at the communication frequency of the RFID tag 100 to λ and the electrical length of the first element 50 to λ / 4 or λ / 2, the resonance frequency of the first element 50 is set to the communication frequency of the RFID tag 100. It is preferable because it can be matched.
Further, when the RFID tag 100 is attached to or embedded in the vulcanized rubber tire 160, the ground plane is further strengthened by electrically connecting the second element 60 to the vulcanized rubber tire 160.

Further, in the present embodiment, the vicinity of one end of the first element 50 formed by the braided wire of the conductor is arranged (for example, fitted) in the groove 65 formed in the printed circuit board 90, and the other end is arranged. The portion extends from the printed circuit board 90.
In the conventional dipole antenna type RFID tag, antenna elements having an electric length of λ / 4 are connected to both ends of a substrate on which an RF chip is mounted. However, in this configuration, if the tire expands and contracts and stress is applied to the two antenna elements in opposite directions, the connection between the antenna element and the substrate may be damaged.
On the other hand, when the vicinity of one end of the first element 50 is arranged on the printed circuit board 90 and the other end is opened as in the present embodiment, the end of the first element 50 and the printed circuit board There is an advantage that the connection with 90 is not easily damaged.

Further, in the present embodiment, when soldering is used by arranging the first element 50 formed of braided wire by sandwiching it in the groove 65 formed in the printed circuit board 90 and pressing it against the through hole 70 for conductive connection. In comparison with the above, the connection between the first element 50 and the printed circuit board 90 is strong against expansion and contraction of the tire 160, and the positional relationship between the first element 50 and the printed circuit board 90 is stable.

(Manufacturing of rubber-coated RFID tag 150)
Next, a manufacturing apparatus for the rubber-coated RFID tag 150 according to the present invention and a manufacturing method thereof will be described.
FIG. 12 is a schematic view showing a production line of the rubber-coated RFID tag 150.
In FIG. 12, the braided roll 200 is a roll that supplies the braided wire 205 that is the first element 50, and the butyl rubber roll 210 is a roll that supplies the first rubber sheet 120, which is a strip-shaped first rubber sheet 120. Is wrapped around. The braided wire 205 is arranged on the first rubber sheet 120 delivered from the butyl rubber roll 210. The braided wire 205 arranged on the first rubber sheet 120 adheres to the first rubber sheet 120.

An idler 220 and a tag stacker 230 are arranged on the supply side of the butyl rubber roll 210. The tag stacker 230 is configured such that a plurality of printed circuit boards 90 are arranged one above the other and one printed circuit board 90 can be sequentially attached onto the first rubber sheet 120. A concave groove 65 formed on the lower surface side of the printed circuit board 90 is arranged along the supply direction, and the printed circuit board 90 and the braided wire 205 are positioned so that the braided wire 205 is inserted into the concave groove 65. There is.

In the present embodiment, the printed circuit board 90 arranged in the tag stacker 230 is provided with a second element 60 on the first surface 91 of the printed circuit board 90, and the second surface 92 of the printed circuit board 90 is an RF chip 10. The one provided with the coupling transformer 20 is used.
That is, the printed circuit board 90 filled in the tag stacker 230 does not include the first element 50 of the above-mentioned RFID tag 100, and by using the method for manufacturing the rubber-coated RFID tag 150 described here, the first element 50 can be used. A rubber-coated RFID tag 150 also including one element 50 will be manufactured.
As a method of providing the second element 60, the coupling transformer 20, and the like on the printed circuit board 90, a known method such as etching can be used. Further, as a method of providing the RF chip 10 on the printed circuit board 90, a known method such as wire bonding can be used.

The second rubber roll 240 in FIG. 12 is a roll for supplying the vulcanized rubber sheet 130 onto the printed circuit board 90 arranged on the first rubber sheet 120, and the idler 250 and the idler 260 are the first rubbers. It is an idler that crimps a laminated body in which a sheet 120, a printed circuit board 90, and a vulcanized rubber sheet 130 are laminated.
The butyl rubber sheet 120, which is the first rubber sheet 120, is formed by crimping a laminate in which the first rubber sheet 120, the printed circuit board 90, and the vulcanized rubber sheet 130 are laminated in this order with the idler 250 and the idler 260. A part of the braided wire enters the concave groove 65, and the braided wire arranged in the concave groove 65 is surely held in the concave groove 65.

Since a part of the butyl rubber sheet 120 and the second rubber sheet 130 extends from the periphery of the printed circuit board 90 to the outside, the periphery of the butyl rubber sheet 120 and the second rubber sheet 130 comes into contact with each other and pressurizes. Glue.
Therefore, the printed circuit board 90, each element (RF chip 10, coupling transformer 20, second element 60) provided on the first surface 91 and the second surface 92 of the printed circuit board 90, and the first element 50 (braided wire 205). ) Is protected by the butyl rubber sheet 120 and the second rubber sheet 130.
In FIG. 12, the cutter 270 and the cutter 280 cut a laminate composed of a first rubber sheet 120, a braided wire 205, and a vulcanized rubber sheet 130 at a set position to obtain set dimensions.

Using the above manufacturing apparatus, the rubber-coated RFID tag 150 according to the present invention can be manufactured as follows.
The braided wire 205 sent out from the braided roll 200 was superposed on the first rubber sheet 120 sent out from the butyl rubber roll 210, and the tag stacker 230 defined the first rubber sheet 120 and the braided wire 205. The printed circuit board 90 is arranged at the position, and the braided wire 205 is arranged in the groove 65 of the printed circuit board 90. At that time, by pressurizing the printed circuit board 90 toward the idler 220, the braided wire is press-fitted into the groove 65.

Next, the second rubber sheet 130 sent out from the second rubber roll 240 is arranged on the printed circuit board 90 adhering to the first rubber sheet 120.
Next, the laminated body in which the first rubber sheet 120, the printed circuit board 90, and the second rubber sheet 130 are laminated is passed between the idler 250 and the idler 260 to crimp the laminated body.
Next, the crimped laminate is cut to a predetermined size.

(Manufacturing method of another rubber-coated RFID tag 150)
In the manufacturing method shown in FIG. 12, the printed circuit board 90 supplied from the tag stacker 230 is supplied onto the butyl rubber sheet 120, but the printed circuit board 90 is supplied onto the butyl rubber sheet 120 by the following method. May be good.
In the manufacturing apparatus shown in FIG. 13, a plurality of printed circuit boards 90 are placed on a non-stretchable tape-shaped base material at regular intervals and adhered to the base material, and a tag supply roll 290 wound with this base material and a first idler are used. A second idler 310 arranged to face the 220 and the first idler 220, and a take-up roll 300 are provided.

The printed circuit board 90 is sent out from the tag supply roll 290 at regular intervals and passed between the first idler 220 and the second idler 310 so that the printed circuit board 90 is transferred onto the butyl rubber sheet 120. It is configured.
Also in this manufacturing apparatus, the braided wire 205 on the first rubber sheet 120 is fitted into the groove 65 of the printed circuit board 90, and the braided wire 205 is arranged in the groove 65.

Next, FIG. 8 is a plan view showing a state in which the RFID tag 100 is adhesively arranged on the first rubber sheet 120 in the rubber-coated RFID tag 150 manufactured by the above manufacturing method. Further, FIG. 9 shows that the RFID tag 100 adhesively arranged on the first rubber sheet 120 shown in FIG. 8 is further coated with the second rubber sheet 130 and crimped, and the RFID tag 100 is attached to the first rubber sheet. It is sectional drawing which shows the rubber-coated RFID tag 150 in the state which is sandwiched between 120 and the 2nd rubber sheet 130.

Note that FIG. 8 also shows a cut surface 110 that cuts the first rubber sheet 120, the braided wire 205 (first element 50), and the second rubber sheet 130 (see FIG. 9) at the time of manufacture.
The cut surface 110 is slightly separated from the end of the printed circuit board 90, and as a result, the end of the first element 50 slightly protrudes from the end of the printed circuit board 90. Therefore, even after cutting, the entire printed circuit board 90 is surely covered with the first rubber sheet 120 and the second rubber sheet 130, and it is possible to prevent the printed circuit board 90 from being exposed. In the case of this embodiment, the distance between the end surface of the printed circuit board 90 and the cut surface 110 is about 5 mm. The distance between the end face of the printed circuit board 90 and the cut surface 110 is preferably 5 mm or more.

By sandwiching the RFID tag 100 between the first rubber sheet 120 and the second rubber sheet 130, even when the tire 160 expands and contracts when the vehicle is running, the first element 50 is arranged in the groove 65 and the first element 50 is arranged in the groove 65. The conductive connection with the through hole 70 can be ensured, and the positional relationship between the first element 50 and the printed circuit board 90 can be stabilized.

FIG. 11 is a schematic cross-sectional view showing a state in which the rubber-coated RFID tag 150 is attached to the inside of the tire 160.
In FIG. 11, the tire 160 includes a wheel rim 161, a sidewall 166 and a tread 165, with a bead wire 162, a carcass 163 and a breaker cord 164 embedded therein.
The rubber-coated RFID tag 150 is attached to the inner surface of the tire 160 so that the first element 50 is centered on the rotation axis of the tire and follows the radial direction. The rubber-coated RFID tag 150 is attached to the inner surface of the tire 160 so that the first rubber sheet 120 side of the rubber-coated RFID tag 150 is in contact with the inner surface of the tire.

Therefore, the RFID tag 100 is attached to the inner surface of the tire due to the adhesiveness of the butyl rubber sheet 120. Further, even when the butyl rubber sheet 120 comes into contact with the bleed component that bleeds from the inside of the tire, the butyl rubber sheet 120 can be mixed with the bleed component, so that the RFID tag 100 can be attached to the inner peripheral surface of the tire for a long period of time. it can.
The method of fixing the rubber-coated RFID tag 150 to the tire 160 is not limited to the above, and the rubber-coated RFID tag 150 can be attached or embedded at any position on the tire 160. For example, the rubber-coated RFID tag 150 may be attached to the inner peripheral surface of the portion where the tread pattern of the tire is arranged, or may be attached to the inner peripheral surface of the bead portion of the tire.

FIG. 10 is a diagram showing the frequency characteristics of the communicable distance of the RFID tag 100 measured by attaching the rubber-coated RFID tag 150 to the inside of the tire 160.
In the RFID tag embedded in the tire 160, a steep resonance characteristic may be provided in the path from the RF chip to the antenna in order to avoid fluctuation of the frequency characteristic of the antenna due to the carbon black contained in the tire 160. However, in general, RFID tags have different communication frequencies between the EU (communication frequency 860 MHz) and Japan (communication frequency 920 MHz). Therefore, for RFID tags having a steep resonance characteristic in the path from the RF chip to the antenna, it is necessary to prepare different RFID tags for the EU and Japan.

On the other hand, in the rubber-coated RFID tag 150 of the present invention, a coupling transformer 20 having a different number of windings is provided between the RF chip 10 and the first element 50 and the second element 60 to adjust the impedance of the primary side 30. It was lowered to eliminate the effect of carbon black contained in the tire rubber. As a result, the RFID tag 100 capable of communicating in a wide range of frequencies including EU and Japan has been realized as shown in FIG.

Further, in the rubber-coated RFID tag 150 of the present invention, the RFID tag 100 is attached to the tire 160 by measuring the RFID tag 100 in a state of being sandwiched between the first rubber sheet 120 and the second rubber sheet 130. There is also an advantage that the communication characteristics of the RFID tag 100 can be confirmed in this case or when embedded in the tire.

(Second embodiment)
Next, FIGS. 6 and 7 show two examples of the connection between the secondary side 40 of the coupling transformer 20 and the RF chip 10 in the second embodiment.
The RFID tag 100 of the second embodiment is different from the first embodiment only in the method of mounting the RF chip 10 on the printed circuit board 90 and the method of connecting the RF chip 10 and the secondary side 40 of the coupling transformer 20. The other is the same as that of the first embodiment.

The RF chip 10 of the second embodiment uses a so-called BGA package, and includes two bumps 87 as terminals for electrical connection. (Usually, it also has an additional bump 87 with no electrical connection for fixing the package.) One end of the secondary side 40 of the coupling transformer 20 is directly on the first bump 87 of the RF chip 10, and the other end is two. It is connected to the second bump 87 of the RF chip 10 via the through hole 85 and the wiring 86 on the first surface 91 side.
The shape of the secondary side 40 of the coupling transformer 20 is the same in FIGS. 6 and 7. However, in the RF chip 10, two bumps 87 are arranged in the horizontal direction in FIG. 6 in FIG. 6 and in the vertical direction in FIG. 7, and as a result, the number of windings on the secondary side 40 in FIG. 7 is shown in FIG. It is 1/4 larger than the number of windings on the secondary side 40.

That is, by making the RF chip 10 into a BGA package and making the shape of the secondary side 40 of the coupling transformer 20 the shape shown in FIG. 6 or FIG. 7, the same printed circuit board 90 is used and the same RF chip 10 is arranged. The winding number ratio of the coupling transformer 20 can be changed only by changing the angle. Therefore, in the RFID tag 100 of the second embodiment, when it is desired to change the impedance of the primary side 30 of the coupling transformer 20 depending on, for example, the rubber material of the tire 160 to be attached or embedded, the RF chip 10 By changing the arrangement angle of, the impedance of the primary side 30 of the coupling transformer 20 can be changed with respect to the RF chip 10 having the same input impedance.
In the above example, the difference in the number of windings on the secondary side 40 of the coupling transformer 20 is 1/4, but the difference in the number of windings can be increased by devising the shape of the secondary side 40 of the coupling transformer 20. Those skilled in the art will easily understand that it can be made larger.

Next, FIG. 14 is a schematic view showing another example of FIG. In the RFID tag 100 of FIG. 14, instead of the groove 65 of FIG. 4, a convex portion (guide portion) 65 is formed around the through hole 70 and on the first surface 91. As a result, the first element 50 can be arranged at a predetermined position.
The convex portion 65 may be partial or may be formed linearly.

Next, FIG. 15 is a schematic view showing another example of the production line of the rubber-coated RFID tag 150.
The difference between the production line shown in FIG. 15 and the production line shown in FIG. 12 is that in the production line of FIG. 12, the first element 50 is first placed on the first rubber sheet 120 and the butyl rubber sheet 120. However, in the production line of FIG. 15, the printed circuit board 90 is arranged on the opposite surface of FIG. 12 so that the so-called groove 65 faces the upper surface, and then the first element 50 is placed in the groove 65. It is a method of arranging in.

Finally, FIG. 16 is a schematic diagram of the frequency and the communication distance when the RFID tag 100 is attached to the tire 160.
As shown in FIG. 16, two types of tires 160 (A and B) were prepared. Further, the frequency and the communication distance were measured in two types: the case where the through hole 70 of the RFID tag 100 and the first element 50 were directly coupled (A1, B1) and the case where the first element 50 was capacitively coupled (A2, B2).

Here, the capacitive coupling is mainly that the braided wire of the first element 50 and the through hole 70 are directly joined, but at the manufacturing site, the braided wire of the first element 50 and the through hole are tentatively joined. When the holes 70 are separated from each other by a slight distance, the first element 50 and the through holes 70 are coupled to each other via a capacitance. In this example, this state is a capacitive coupling.

As shown in FIG. 16, as a result of comparing Graph A1 and Graph B1 due to the different types of tires 160, it was found that a slight difference occurs. Similarly, as a result of comparing Graph A2 and Graph B2, it was found that a slight difference occurred.
Further, when the graphs A1 and A2 shown in FIG. 16 are compared, the communication distance is longer in the direct coupling, but the capacitively coupled graph A2 shows a communication distance of 5 m or more at both 860 Hz and 920 Hz. Therefore, it was found that it was sufficient for practical use.
Similarly, when graph B1 and graph B2 shown in FIG. 16 are compared, although the communication distance is longer in the direct coupling, the capacitively coupled graph B2 shows a communication distance of 5 m or more at both 860 Hz and 920 Hz. Therefore, it was found that it was sufficient for practical use.

In the present invention, the RF chip 10 corresponds to the "RF chip", the first element 50 corresponds to the "first element", the second element 60 corresponds to the "second element", and the coupling transformer 20 "couples". The printed circuit board 90 corresponds to the "printed circuit board", the primary side 30 of the coupling transformer corresponds to the "primary side of the coupling transformer", and the secondary side 40 of the coupling transformer corresponds to the "coupled transformer". The RFID tag 100 and the rubber-coated RFID tag 150 correspond to the "RFID tag", the first surface 91 of the printed circuit board corresponds to the "first surface of the printed circuit board", and the first surface of the printed circuit board corresponds to the "secondary side". The two surfaces 92 correspond to the "second surface of the printed circuit board", the convex portion 65, the concave groove 65 or the groove 65 correspond to the "guide portion, the groove", and the through hole 70 corresponds to the "through hole". The first rubber sheet 120 and the butyl rubber sheet 120 correspond to the "first rubber sheet", the second rubber sheet 130 and the vulgarized rubber sheet 130 correspond to the "second rubber sheet", and the knitting roll 200 Corresponds to the "braided wire roll", the butyl rubber roll 210 corresponds to the "butyl rubber roll", the idlers 220, 250, 260 and 310 correspond to the "idler", and the tag stacker 230 corresponds to the "tag stacker". The second rubber roll 240 corresponds to the "second rubber roll", the cutters 270 and 280 correspond to the "cutter", the tag supply roll 290 corresponds to the "tag supply roll", and the take-up roll 300 corresponds to the "wind-up roll". The "roll" corresponds to the RFID tag built-in tire 500, and the RFID tag built-in tire 500 corresponds to the "RFID tag built-in tire".

The preferred embodiment of the present invention is as described above, but the present invention is not limited thereto. It will be appreciated that various embodiments are made that do not deviate from the spirit and scope of the invention. Further, in the present embodiment, the actions and effects according to the constitution of the present invention are described, but these actions and effects are examples and do not limit the present invention.

10 RF chip 20 Coupling transformer 30 Primary side of coupling transformer 40 Secondary side of coupling transformer 50 1st element 60 2nd element 65 Grooves, convex parts (guide parts), concave grooves 70, 80, 85 Through holes 87 bumps 90 Printed circuit board 91 First side of printed circuit board 92 Second side of printed circuit board 100 RFID tag 120 Butyl rubber sheet, first rubber sheet 130 Second rubber sheet, vulcanized rubber sheet 150 Rubber-coated RFID tag 160 Tire 200 Braided wire Roll 210 Butyl rubber roll 220, 250, 260, 310 Idler 230 Tag stacker 240 Second rubber roll 270, 280 Cutter 290 Tag supply roll 300 Take-up roll 500 RFID tag built-in tire

Claims (18)

1. RF chip and
   The first element formed by the braided wire of the conductor and
   The second element and
   With a binding transformer
   Including printed circuit board
   A guide portion is provided on the printed circuit board, the first element is arranged on the guide portion, and extends from the printed circuit board.
   The first element is connected to one end of the primary side of the coupling transformer, the second element is connected to the other end of the primary side of the coupling transformer, and the RF chip is connected to the secondary side of the coupling transformer. Being done
   An RFID tag in which the number of windings on the primary side of the coupling transformer is smaller than the number of windings on the secondary side.
2. The guide portion is provided on the first surface of the printed circuit board.
   The second element is provided on the first surface of the printed circuit board.
   The RF chip and the coupling transformer are provided on the second surface of the printed circuit board.
   The guide portion is provided with a plurality of through holes for connecting the first surface and the second surface of the printed circuit board, and the first element is one end of the primary side of the coupling transformer via the through holes. Connected to
   One side end portion and the other side end portion of the first element extend outward from the end face of the printed circuit board, and the extension length of the other side end portion is 1/10 of the total length of the first element. The RFID tag according to claim 1, which is as follows.
3. The second element is formed of a rectangular conductor, the surface of which is exposed to the surface of the printed circuit board, and the secondary side of the coupling transformer and the RF chip are sealed with a resin layer. Or the RFID tag according to 2.
4. Claim 1 that the electrical length of the first element is λ / 4, λ / 2, (3/4) λ or (5/8) λ, where λ is the wavelength of the radio wave at the communication frequency of the RFID tag. The RFID tag according to any one of 3 to 3.
5. The RFID tag according to any one of claims 1 to 4, wherein the guide portion for arranging the first element at a fixed position is provided with a rail-shaped groove on the printed circuit board.
6. Four terminals are provided on the secondary side of the coupling transformer, the RF chip is sealed in a BGA package and arranged on the surface of the secondary side of the coupling transformer, and the RF chip is arranged according to the arrangement angle of the RF chip. The terminal of the RF chip and one of the two terminals of the four terminals or the other two terminals are connected to each other.
   The number of windings on the secondary side of the coupling transformer differs depending on whether the RF chip is connected to the one two terminals and the other two terminals. , The RFID tag according to any one of claims 1 to 5.
7. A first insulator and a second insulator laminated on the printed circuit board are further provided.
   The first insulator, the printed circuit board, and the second insulator are laminated in this order.
   The RFID tag according to any one of claims 1 to 6, wherein the second element is electrically connected to the tire via the second insulator.
8. The RFID tag according to claim 7, wherein the second insulator is a butyl rubber sheet.
9. The RFID tag according to claim 7, wherein the material of the first insulator and the second insulator is the same material as the tire.
10. The RFID tag according to any one of claims 1 to 9, which is used for sticking to the inside of the tire or embedding it in the rubber of the tire.
11. A tire with a built-in RFID tag, wherein the RFID tag according to any one of claims 1 to 10 is attached to the inside of the tire or embedded in the rubber of the tire.
12. The method for manufacturing an RFID tag according to claim 8, further comprising a braided wire roll, a butyl rubber roll, a tag stacker, a second rubber roll, an idler, and a cutter.
    The braided wire delivered from the braided roll is superposed on the butyl rubber sheet delivered from the butyl rubber roll, and the braided wire is arranged on a guide portion of the printed circuit board by the tag stacker, and the braided wire is arranged. With the step of making the first element,
    A step of arranging the second rubber sheet delivered from the second rubber roll on the printed circuit board on which the braided wire is arranged on the butyl rubber sheet, and a step of arranging the second rubber sheet.
    A step of crimping the butyl rubber sheet, the printed circuit board, the first element, and the second rubber sheet through an idler.
    A method for manufacturing an RFID tag, which comprises a step of cutting and individualizing an RFID tag that has been crimped and integrated with the butyl rubber sheet and the second rubber sheet.
13. Instead of the tag stacker, a tag supply roll, the idler, and a take-up roll are provided.
    On the butyl rubber sheet delivered from the butyl rubber roll, the braided wire delivered from the braided roll and the printed circuit board in the taping state delivered from the tag supply roll are superposed.
    The method for manufacturing an RFID tag according to claim 12, further comprising a step of arranging the braided wire on a guide portion of the printed circuit board with the idler and using the braided wire as a first element.
14. A step of delivering the first rubber sheet from a roll around which a first rubber sheet made of a butyl rubber sheet is wound, and superimposing the braided wire sent from the knitting roll on the first rubber sheet.
    A step of stacking the printed circuit board on the first rubber sheet so that the braided wire is arranged on the guide portion formed on the first surface of the printed circuit board.
    A step of stacking a second rubber sheet sent from the second rubber sheet roll on the second surface of the printed circuit board.
    A step of pressurizing a laminate in which the first rubber sheet, the printed circuit board, the braided wire, and the second rubber sheet are laminated in this order.
    A method for manufacturing an RFID tag, which comprises a step of cutting the laminate.
15. The step of stacking the printed circuit board on the first rubber sheet is
    The method for manufacturing an RFID tag according to claim 14, further comprising a step of sequentially supplying the printed circuit boards onto the butyl rubber sheet from a stacker in which a plurality of the printed circuit boards are laminated.
16. The step of stacking the printed circuit board on the first rubber sheet is
    The method for manufacturing an RFID tag according to claim 14 or 15, further comprising a step of transferring the printed circuit board to the butyl rubber sheet by stacking a tape on which the printed circuit board is intermittently attached on the butyl rubber sheet and crimping the tape. ..
17. The method for manufacturing an RFID tag according to claim 8, further comprising a braided wire roll, a butyl rubber roll, a tag stacker, a second rubber roll, an idler, and a cutter.
    A step of stacking the printed circuit board from the tag stacker on the butyl rubber sheet delivered from the butyl rubber roll, disposing the braided wire on a guide portion of the printed circuit board, and using the braided wire as the first element. When,
    A step of arranging a second rubber sheet delivered from the second rubber roll on the printed circuit board on which the braid is arranged on the butyl rubber sheet and the braid, and a step of arranging the second rubber sheet.
    A step of crimping the butyl rubber sheet, the printed circuit board, the first element, and the second rubber sheet through the idler.
    A method for manufacturing an RFID tag, which comprises a step of cutting and individualizing an RFID tag that has been crimped and integrated with the butyl rubber sheet and the second rubber sheet.
18. A step of delivering the first rubber sheet from a roll around which a first rubber sheet made of a butyl rubber sheet is wound and placing a second surface of a printed circuit board on the first rubber sheet.
    A step of arranging the braided wire sent from the braided wire roll so that the braided wire is arranged on a guide portion formed on the first surface of the printed circuit board.
    A step of superimposing a second rubber sheet sent out from a second rubber sheet roll on the first surface of the braided wire and the printed circuit board.
    A step of pressurizing a laminate in which the first rubber sheet, the printed circuit board, the braided wire, and the second rubber sheet are laminated in this order.
    A method for manufacturing an RFID tag, which comprises a step of cutting the laminate.
    
    
    

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