JP4012937B1 - RFID card container and RFID communication auxiliary sheet - Google Patents

Abstract

A plurality of RFID tags can be stored, and when a magnetic field is applied from an RFID reader, only one desired RFID tag can be activated and read while other RFIDs cannot be read. An RFID card container and an RFID communication auxiliary sheet are provided.
An RFID card container and an RFID communication auxiliary sheet are produced using a plate-like member having a magnetic layer, a conductor layer, and a gap layer. In the RFID card container and the communication auxiliary sheet, the plate-like member is used so as to be disposed between the first RFID tag and the second RFID tag. Then, when a magnetic field is applied from the RFID reader located on the first RFID tag side, the first RFID tag is activated, and a reply to the RFID reader is performed. On the other hand, the second RFID tag is not activated because a demagnetizing field is generated by an eddy current generated in the conductor layer, and thus no reply is made.
[Selection] Figure 10

Description

  The present invention relates to an RFID card container and an RFID communication auxiliary sheet, and more specifically, a wallet that stores an RFID tag such as a plurality of non-contact IC cards and can read only one desired RFID tag. When holding together with a plurality of RFID tags such as a card holder, etc., stabilization of communication between one desired RFID tag and a reader and prevention of communication between another RFID tag and the reader It is related with the communication assistance sheet | seat which can perform simultaneously.

  In recent years, services using RFID (Radio Frequency Identification) technology such as contactless IC cards have been provided in various daily situations such as credit cards, cash cards, and public transport tickets. Hereinafter, the operation of the non-contact IC card will be briefly described with reference to FIGS. 1 (a) and 1 (b).

  When the non-contact IC card 10 is held over the reader 20, the reader 20 generates a magnetic field A with respect to the non-contact IC card 10. When the magnetic field A passes through a coil built in the non-contact IC card 10, the magnetic flux is converted into a current in the coil and used as a power source for the IC. Then, a magnetic field B opposite to the magnetic field from the reader 20 is generated, and a reply to the request command signal is performed. Thereby, the reader 20 can read the information recorded on the IC card 10.

  Since the non-contact IC card can be used simply by holding it over the reader, it is convenient and convenient. However, on the other hand, information recorded on the card is illegally read without the knowledge of the owner. Therefore, the present inventor has developed a card equipped with a non-contact IC card skimming prevention function described in Patent Document 1 for the purpose of preventing such illegal reading called skimming.

  A card having a skimming prevention function described in Patent Document 1 is a thin metal plate made of gold, silver, copper, or aluminum, and the thin metal plate is laminated with PET (polyethylene terephthalate) or PVC (polyvinyl chloride). It consists of a processed decorative board.

  As shown in FIGS. 2 (a) and 2 (b), the card having the skimming prevention function and the non-contact IC card 10 are arranged close to each other, so that when the magnetic field A from the reader 20 is received, skimming is performed. A demagnetizing field that cancels the magnetic field A from the reader 20 is generated by the eddy current generated in the metal thin plate of the card having the prevention function, and the non-contact IC card 10 is not activated. Therefore, the information recorded on the non-contact IC card is not read by the reader.

  However, according to the card described in Patent Document 1, skimming can be effectively prevented, but there is a problem that reading by a normal reader is also prevented. Therefore, when the card is carried together with the card described in Patent Document 1, the non-contact IC card must be taken out and held over the reader one by one, which greatly reduces the convenience.

  Recently, many consumers have a plurality of contactless IC cards, which are often stored together in a wallet or the like. However, if such a wallet is held over the reader as it is, not only the desired one but also each stored card replies to the reader, so that a reading error due to interference occurs. Therefore, also in this case, it is necessary to take out only one desired non-contact IC card and hold it over the reader.

  In order to solve such problems and use the non-contact IC card more conveniently, for example, the non-contact type IC card holder described in Patent Document 2 or the IC card holder described in Patent Document 3 is used. Can do.

  The non-contact type IC card holder described in Patent Document 2 includes a plurality of card storage portions that respectively store a plurality of IC cards, and by providing a partition portion composed of a magnetic body portion and a conductor portion, Data can be read and written only to a desired card among the IC cards stored in each card storage unit.

  In addition, the IC card holder described in Patent Document 3 includes an interference prevention body composed of a conductive sheet and a magnetic sheet between two non-contact IC cards. The communication function is ensured.

According to such a card holder, it is possible to use only a desired one of a plurality of non-contact IC cards while being stored in the card holder.
Japanese Patent No. 3836496 Japanese Patent No. 3630006 JP-A-2005-11044

  As can be seen from Patent Documents 2 and 3, using a conductor and a magnetic material, it is possible to activate only one desired non-contact IC card among a plurality of non-contact IC cards. This is known to those skilled in the art. Therefore, the present inventor has advanced research on a plate-like member composed of a conductor and a magnetic material in order to find out which conductor and magnetic material are most effective. It was. As a result, the following problems became clear.

  FIGS. 3A to 3C show a plate-like member configured by combining only a conductor and a conductor and a magnetic body. Here, a copper foil having a thickness of 35 μm is used as the conductor, and a ferrite piece having a thickness of 150 μm and a relative permeability of 20 is used as the magnetic body. Among the plate-like members, A is only the copper foil 30, B is a plate-like member obtained by combining the copper foil 30 and the ferrite piece 40, and C is between the first ferrite piece 401 and the second ferrite piece 402. A plate-like member with a copper foil 30 interposed therebetween.

  When the magnetic field strength attenuation rate of these plate-like members A to C was measured by the KEC method, results as shown in Table 1 were obtained.

  According to Table 1, the magnetic field strength attenuation rate decreases in the order of the plate-like members A, B, and C. That is, it was found that the shielding property of the plate-like member deteriorates in this order. This is because a plate-like member having a structure in which a conductor is interposed between two pieces of magnetic material cannot provide high reliability when trying to activate only one of a plurality of non-contact IC cards. I mean.

  In view of the above, an object of the present invention is to solve such a problem and reliably start only one desired RFID tag in the case of possessing a plurality of RFID tags.

In order to solve these problems, the present invention provides a first storage unit that stores a single first RFID tag and a second storage unit that stores a single second RFID tag. RFID card holder. In this RFID card holder, a first magnetic layer, a first gap layer, a first conductor layer, and a second gap are provided between the first storage portion and the second storage portion. A plate-like member formed by sequentially laminating a layer, a second conductor layer, a third gap layer, and a second magnetic layer is interposed. The plate-like member has a predetermined magnetic field strength attenuation rate when a magnetic field having a frequency of 13.56 MHz is applied to read information recorded in the first RFID tag stored in the first storage unit, While activating the first RFID tag, the activation of the second RFID tag stored in the second storage unit is blocked, or the activation of the first RFID tag is blocked while activating the second RFID tag. .

  The present invention further provides an RFID card including a first storage unit that stores a single first RFID tag and a second storage unit that stores a single second RFID tag. It is a container. In this RFID card holder, a first magnetic layer, a first conductor layer, a gap layer, and a second conductor layer are provided between the first storage portion and the second storage portion. In addition, a plate-like member configured by sequentially laminating the second magnetic layer is interposed. The plate-like member has a predetermined magnetic field strength attenuation rate when a magnetic field having a frequency of 13.56 MHz is applied to read information recorded in the first RFID tag stored in the first storage unit, While activating the first RFID tag, the activation of the second RFID tag stored in the second storage unit is blocked, or the activation of the first RFID tag is blocked while activating the second RFID tag. .

  In these RFID card holders, the conductor layer is copper having a thickness of 35 μm, the magnetic layer has a relative permeability higher than 1 when a magnetic field having a frequency of 13.56 MHz is applied, and the gap layer is It is made of paper or resin. A hole may be formed in the gap layer.

In order to solve the above-mentioned problems, the present invention further provides that the RFID reader and the first RFID tag are disposed between a single first RFID tag and a single second RFID tag. The communication between the RFID reader and the second RFID tag, or the communication between the RFID reader and the second RFID tag is stabilized, and the RFID It is an RFID communication auxiliary sheet for blocking communication between a reader and a first RFID tag. The RFID communication auxiliary sheet includes a first magnetic body, a first gap layer, a first conductor layer, a second gap layer, a second conductor layer, and a third gap layer. And a second magnetic layer are sequentially stacked, and a magnetic field with a frequency of 13.56 MHz is applied from the RFID reader to read information recorded on the first RFID tag or the second RFID tag. When the first RFID tag is activated, the first RFID tag is activated and the second RFID tag is inhibited from being activated, or the second RFID tag is activated and the first RFID tag is activated. Will stop.

  Further, the present invention further provides a communication between the RFID reader and the first RFID tag that is disposed between the single first RFID tag and the single second RFID tag. And preventing communication between the RFID reader and the second RFID tag, or stabilizing communication between the RFID reader and the second RFID tag, and the RFID reader and the first RFID. It is an RFID communication auxiliary sheet for blocking communication with a tag. This RFID communication auxiliary sheet is formed by sequentially laminating a first magnetic layer, a first conductor layer, a gap layer, a second conductor layer, and a second magnetic layer. When a magnetic field having a frequency of 13.56 MHz is applied to read information recorded on the first RFID tag or the second RFID tag from the RFID reader, the first RFID has a predetermined magnetic field strength attenuation rate. The activation of the second RFID tag is prevented while the tag is activated, or the activation of the first RFID tag is inhibited while the second RFID tag is activated.

  In these RFID communication auxiliary sheets, the conductor layer is copper having a thickness of 35 μm, the magnetic layer has a relative permeability higher than 1 when a magnetic field having a frequency of 13.56 MHz is applied, and the gap layer is It is made of paper or resin. A hole may be formed in the gap layer.

  According to the RFID card holder of the present invention, even if the RFID tag such as a plurality of non-contact IC cards is held in the reader, only one desired RFID tag can be obtained without causing a reading error. It can be activated and reading of other RFID tags can be prevented.

  Also, according to the RFID communication auxiliary sheet of the present invention, by holding together with two RFID tags such as non-contact IC cards, only one desired RFID tag is activated, and the other RFID tag Can be prevented from being read.

  Therefore, for example, it is possible to easily read a frequently used contactless IC card, and at the same time, it is possible to prevent skimming for other contactless IC cards.

  The present invention will be described below with reference to the drawings.

  In the following, “front side” means a position relatively close to the reader, and “back side” means a position relatively far from the reader. Therefore, for example, disposing a plate-like member made of a magnetic material and a conductor on the “front side” of a non-contact IC card means arranging a plate-like member between the reader and the non-contact IC card. In addition, arranging the plate-like member on the “back side” of the non-contact IC card means arranging the non-contact IC card between the reader and the plate-like member.

  Furthermore, even when the plate-like member is arranged on either the front side or the back side of the non-contact IC card, among the magnetic body and conductor constituting the plate-like member, the magnetic body is always arranged on the reader side And

  In the process of developing a card having a skimming prevention function described in Patent Document 1, the present inventor measured a ferrite that is a magnetic material and found that the ferrite has the following properties.

  First, when the ferrite piece is arranged on the front side of the non-contact IC card, the ferrite piece cancels the magnetic field from the reader and does not activate the non-contact IC card. Secondly, when the ferrite piece is disposed on the back side of the non-contact IC card, the ferrite piece amplifies the magnetic field from the reader and facilitates reading of information recorded on the non-contact IC card.

  Here, it is known that when a plate-like member made of a magnetic material and a conductor having such properties is arranged on the back side of a non-contact IC card, the non-contact IC card is activated. Details of the magnetic material and conductor that can be realized are not clear. Moreover, the following problems may occur if the plate-like member is not composed of an appropriate magnetic material and conductor.

  For example, as shown in the schematic diagrams of FIGS. 4A and 4B, the first magnetic field A from the reader 20 is used to activate only the first non-contact IC card 101. Both the first non-contact IC card 101 and the second non-contact IC card 102 are activated to perform replies B1 and B2, respectively, and interference occurs.

  Alternatively, as shown in the schematic diagrams of FIGS. 5A and 5B, a strong demagnetizing field C is generated by the eddy current generated in the conductor 30 by receiving the magnetic field A from the reader 20, and the first non-contact. Neither the IC card 101 nor the second contactless IC card 102 is activated and no reply is made.

  In order to prevent such a problem from occurring, in consideration of the standard of a non-contact IC card, a plate-like member capable of obtaining a predetermined magnetic field strength attenuation rate when a magnetic field having a frequency of 13.56 MHz is applied from a reader. It is desirable to use Here, -9.54 dB is defined as the theoretical value of the predetermined magnetic field strength attenuation rate, and this value does not coincide with the value measured by the KEC method.

  That is, the theoretical value of −9.54 dB is not reached at −22 dB obtained by measurement by the KEC method, and at least −30 dB is required when measured by the KEC method. If such a plate-like member is formed using a magnetic material and a conductor and is interposed between two non-contact IC cards, as shown in FIGS. 6 (a) and 6 (b), the reader 20 When the magnetic field A is applied, the first non-contact IC card 101 on the front side of the magnetic body 40 and the conductor 30 is activated to perform a reply B, and the second non-contact IC card 102 located on the back side is It is not activated by the action of the demagnetizing field C, and it is considered that the problem of interference does not occur.

  Then, by applying such a plate-shaped member, a configuration in which a conductor is interposed between the magnetic body and the magnetic body, that is, a configuration in which two plate-shaped members composed of the magnetic body and the conductor are bonded together. According to the plate-like member, it is estimated that one of the two non-contact IC cards arranged on the front and back sides can be activated and the other can be used without being activated.

  However, as already mentioned, when a copper foil is used as the conductor and a ferrite piece is used as the magnetic body, in the plate-like member configured by interposing the copper foil between two ferrite pieces, only the copper foil and ferrite are used. A high magnetic field strength attenuation rate cannot be obtained as compared with a plate-like member composed of a piece and a copper foil.

  In order to clarify the cause of this phenomenon, the present inventor first focused on the thickness of the copper foil interposed between the ferrite pieces, and how the magnetic field strength attenuation rate changes by changing the thickness of the copper foil. Measurements were taken to investigate. Here, between the first and second ferrite pieces 401 and 402 having a thickness of 150 μm and a relative permeability of 20, as shown in FIGS. 7A and 7B, the thicknesses are 35 μm and 70 μm. The copper foil 30 was interposed, and the magnetic field strength attenuation rate was measured for each by the KEC method. Table 2 shows the measurement results.

  From Table 2, it was found that even when the thickness of the copper foil was doubled, the magnetic field strength attenuation rate hardly changed. Therefore, it is considered that even if the thickness of the copper foil interposed between the ferrite pieces is changed, there is no way to prevent the occurrence of errors.

  Next, the inventor paid attention to the configuration of the plate-like member. That is, when receiving a magnetic field from the reader, if the two ferrite pieces and the copper foil are in close contact with each other, an eddy current does not easily flow through the copper foil, so that a sufficient magnetic field strength attenuation rate cannot be obtained. I thought. In order to confirm this, the following plate-like member was prepared.

  FIG. 8 shows a plate-like member D formed by laminating a ferrite piece 40, a paper piece 701, a copper foil 30, and a paper piece 702 in this order. Here, the paper piece 701 is inserted in order to provide a gap between the ferrite piece 40 and the copper foil 30.

  Similarly, the plate member E shown in FIG. 9 was also measured as a configuration in which a gap was provided between the ferrite piece and the copper foil. Here, the plate-like member E is configured by sequentially laminating a first ferrite piece 401, a paper piece 701, a first copper foil 301, a paper piece 702, a second copper foil 302, a paper piece 703, and a second ferrite piece 402. It is a thing.

  Furthermore, the measurement was also performed on the plate-like member F shown in FIG. The plate-like member F is obtained by sequentially laminating a first ferrite piece 401, a first copper foil 301, a paper piece 70, a second copper foil 302, and a second ferrite piece 402. There is no gap between the first ferrite piece 401 and the first copper foil 301, and between the second ferrite piece 402 and the second copper foil 302, but the first copper foil corresponding to the center of the stack A gap is provided by sandwiching a piece of paper 70 between 301 and the second copper foil 302.

  In each of the plate members D to F shown in FIGS. 8 to 10, a copper foil having a thickness of 35 μm was used, and a ferrite piece having a thickness of 150 μm and a relative permeability of 20 was used. The paper piece has a thickness of 150 μm and a relative dielectric constant of 2.6. Table 3 shows the results of measuring the magnetic field strength attenuation rate by the KEC method using these plate-like members.

  Here, as shown in Table 1, the magnetic field strength attenuation rate in the plate member C in which the copper foil was interposed between the ferrite pieces was −22 dB, whereas the plate members D and E shown in Table 3 were used. , F show a higher magnetic field strength attenuation rate than the plate member C. It has been found that even the plate member F having the lowest magnetic field strength attenuation rate among the plate members D to F can obtain a shielding effect about 10 dB higher than the plate member C.

  Thus, by providing a gap between the ferrite piece and the copper foil, that is, between the magnetic body and the conductor, or by providing a gap between the two copper foils interposed between the two ferrite pieces. It is considered that the generation of eddy current in the conductor is not hindered. Therefore, if the plate-like member D is used, it is possible to activate only the non-contact IC card arranged on the front side and not activate the non-contact IC card arranged on the back side. Further, if the plate-like member E or F is used, only one of the non-contact IC cards among the non-contact IC cards arranged on the front side and the back side is activated, and the other non-contact IC card is not activated. Can be.

  Therefore, for example, the following card container can be manufactured using plate-like members such as D, E, and F.

  Shown in FIGS. 11, 12 and 13 is a wallet according to one embodiment of the present invention. As shown in FIG. 11, the wallet 50 includes an inner pocket for storing a plurality of cards and banknotes. The plurality of cards 102a to 102f stored in the inner pockets are non-contact IC cards, magnetic or paper cards, and the like.

  The wallet 50 is carried in a folded state along the broken line X. 12A and 12B show the wallet 50 in a folded state. In the figure, the fold line X corresponds to the upper side. As shown in the figure, the wallet 50 has one outer pocket 601 in which only one non-contact IC card 101 is stored. The outer pocket 601 is provided in a position overlapping the inner pocket 602 for storing the card 102f, for example, among the inner pockets of the wallet 50.

  Such a wallet 50 is made of leather such as cowhide as a whole. The plate-like member D described above is sandwiched between the outer leather 501 and the inner leather 502 at least in a portion where the outer pocket 601 and the inner pocket 602 are disposed. This is shown in FIG.

  The plate-like member D is arranged so that the ferrite layer 40, the paper piece 701, the copper foil 30, and the paper piece 702 are located in this order from the outer pocket 601 and the outer leather 501 side to the inner leather 502 and the inner pocket 602 side. , Built in the wallet 50. The plate-like member may have a size that extends over the entire surface between the outer leather 501 and the inner leather 502. For example, the ferrite layer 40 is provided only in a portion overlapping the outer pocket 601, and a paper piece 701 is provided in the other portion. It is also possible to laminate only the copper foil 30 and the paper piece 702.

  By incorporating the plate-like member D, when a plurality of non-contact IC cards are stored in the wallet 50, only the non-contact IC card 101 stored in the outer pocket 601 is activated when receiving a magnetic field from the reader. The At this time, the non-contact IC card stored inside the wallet, that is, in the inner pocket 602 or the like is not activated.

  In another embodiment of the present invention, it is possible to produce a card case or the like (not shown) that can activate two non-contact IC cards by using the plate-like member E or F described above. FIG. 14 schematically illustrates the configuration and function thereof.

  In FIG. 14, the first non-contact IC card 101 and the second non-contact IC card 102 are arranged on the front and back of the plate-like member E, respectively. Here, when the magnetic field A1 is applied from the reader 201 to the first non-contact IC card 101, the first non-contact IC card 101 is caused by the action of the demagnetizing field C1 generated by the eddy current generated in the conductor layer 301. Only reply B1, and the second non-contact IC card 102 is not activated.

  Conversely, when the magnetic field A2 is applied from the reader 202 to the second non-contact IC card 102, the second non-contact IC card 102 is caused by the action of the demagnetizing field C2 generated by the eddy current generated in the conductor layer 302. Only reply B2, and the first non-contact IC card 101 is not activated.

  In this embodiment, the plate member E is used. However, even if the plate member F is used, the same function can be provided.

  In addition, the plate-like members D, E, and F are simply held together with a plurality of non-contact IC cards, so that the desired non-contact IC card can be read, and other non-contact IC cards can be read. It is also possible to use it as a communication assistance sheet that prevents it. However, in that case, the positional relationship between the non-contact IC card and the plate-like members D, E, and F must be the same as in the above-described two embodiments.

  Further, as for the plate-like members D, E, and F, it is obvious that a conductor other than copper foil can be used, and that a magnetic substance other than ferrite can be used. In the embodiment described above, a piece of paper is used to provide a gap between the two layers. However, instead of the piece of paper, a resin such as polyethylene terephthalate (PET) or vinyl chloride may be used. By making holes or slits in such a piece of paper or resin, it is possible to make the relative permittivity of the gap layer close to 1 and increase the generation of eddy currents.

  As mentioned above, although the Example of this invention was described, this invention is not limited to these Examples, In addition, it is possible to implement various things, such as a regular ticket holder and a bag.

(A) And (b) is a schematic diagram explaining operation | movement of a non-contact IC card. (A) And (b) is a schematic diagram explaining operation | movement of a non-contact IC card at the time of using the card | curd provided with the skimming prevention function. (A) is only a copper foil, (b) is a ferrite piece and copper foil, (c) is a figure which shows the plate-shaped member comprised from two ferrite pieces and copper foil. (A) And (b) is a figure which shows an example of the communication error at the time of interposing a plate-shaped member between the 1st non-contact IC card and the 2nd non-contact IC card. (A) And (b) is a figure which shows an example of the communication error at the time of interposing a plate-shaped member between the 1st non-contact IC card and the 2nd non-contact IC card. (A) And (b) is a figure which shows an example of an ideal communication when a plate-shaped member is interposed between the 1st non-contact IC card and the 2nd non-contact IC card. (A) And (b) is a figure which shows the case where the magnetic body and the conductor from which thickness differs are interposed between the 1st non-contact IC card and the 2nd non-contact IC card. The figure which shows an example of a structure of the plate-shaped member interposed between a 1st non-contact IC card and a 2nd non-contact IC card. The figure which shows an example of a structure of the plate-shaped member interposed between a 1st non-contact IC card and a 2nd non-contact IC card. The figure which shows an example of a structure of the plate-shaped member interposed between a 1st non-contact IC card and a 2nd non-contact IC card. The figure explaining the wallet by one Example of this invention. The figure explaining the wallet by one Example of this invention. The figure explaining the wallet by one Example of this invention. The figure explaining communication at the time of interposing the communication auxiliary sheet by one Example of this invention between the 1st non-contact IC card and the 2nd non-contact IC card.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Non-contact IC card 101 1st non-contact IC card 102,102a-102f 2nd non-contact IC card 20,201,202 Reader 30 Conductor / copper foil 40,401,402 Magnetic body / ferrite piece 50 Purse 501 Outer leather 502 Inner leather 601 Outer pocket 602 Inner pocket 701, 702, 703

Claims (8)

An RFID card container including a first storage unit that stores a single first RFID tag and a second storage unit that stores a single second RFID tag,
Between the first storage portion and the second storage portion, a first magnetic layer, a first gap layer, a first conductor layer, a second gap layer, and a second gap A plate-like member configured by sequentially laminating a conductor layer, a third gap layer, and a second magnetic layer is interposed,
The plate-like member has a predetermined magnetic field strength attenuation rate when a magnetic field having a frequency of 13.56 MHz is applied to read information recorded in the first RFID tag stored in the first storage unit. The activation of the second RFID tag stored in the second storage unit while activating the first RFID tag is prevented, or the first RFID tag is activated while the second RFID tag is activated. An RFID card container, wherein activation of the RFID tag is prevented. An RFID card container including a first storage unit that stores a single first RFID tag and a second storage unit that stores a single second RFID tag,
Between the first storage portion and the second storage portion, a first magnetic layer, a first conductor layer, a gap layer, a second conductor layer, and a second magnetic body are provided. A plate-like member constituted by sequentially laminating layers is interposed,
The plate-like member has a predetermined magnetic field strength attenuation rate when a magnetic field having a frequency of 13.56 MHz is applied to read information recorded in the first RFID tag stored in the first storage unit. The activation of the second RFID tag stored in the second storage unit while activating the first RFID tag is prevented, or the first RFID tag is activated while the second RFID tag is activated. An RFID card container, wherein activation of the RFID tag is prevented. The RFID card container according to claim 1 or 2 ,
The conductor layer is copper having a thickness of 35 μm,
The magnetic layer has a relative permeability higher than 1 when a magnetic field having a frequency of 13.56 MHz is applied;
The RFID card container, wherein the gap layer is made of paper or resin. The RFID card container according to any one of claims 1 to 3 ,
An RFID card container, wherein a hole is formed in the gap layer. Arranged between a single first RFID tag and a single second RFID tag to stabilize communication between the RFID reader and the first RFID tag, and the RFID reader and the first RFID tag The communication between the RFID reader and the second RFID tag, and between the RFID reader and the first RFID tag. A communication auxiliary sheet for RFID that prevents communication in
The first magnetic layer, the first gap layer, the first conductor layer, the second gap layer, the second conductor layer, the third gap layer, and the second magnetic body When a magnetic field having a frequency of 13.56 MHz is applied from the RFID reader to read information recorded on the first RFID tag or the second RFID tag, a predetermined frequency is applied. The first RFID tag has a magnetic field strength attenuation rate, and the activation of the second RFID tag is prevented while the first RFID tag is activated, or the activation of the first RFID tag is activated while the second RFID tag is activated. Is a communication auxiliary sheet for RFID characterized by blocking. Arranged between a single first RFID tag and a single second RFID tag to stabilize communication between the RFID reader and the first RFID tag, and the RFID reader and the first RFID tag The communication between the RFID reader and the second RFID tag, and between the RFID reader and the first RFID tag. A communication auxiliary sheet for RFID that prevents communication in
The first magnetic layer, the first conductive layer, the gap layer, the second conductive layer, and the second magnetic layer are sequentially stacked, and the first RFID layer is formed from the RFID reader. When a magnetic field having a frequency of 13.56 MHz is applied to read information recorded on the RFID tag or the second RFID tag, the magnetic field has a predetermined magnetic field strength attenuation rate and activates the first RFID tag. An RFID communication auxiliary sheet, wherein the activation of the second RFID tag is prevented or the activation of the first RFID tag is inhibited while the second RFID tag is activated. In the communication auxiliary seat for RFID according to claim 5 or 6 ,
The conductor layer is copper having a thickness of 35 μm,
The magnetic layer has a relative permeability higher than 1 when a magnetic field having a frequency of 13.56 MHz is applied;
The RFID communication auxiliary sheet, wherein the gap layer is made of paper or resin. In the RFID communication auxiliary sheet according to any one of claims 5 to 7 ,
A communication auxiliary sheet, wherein a hole is formed in the gap layer.

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