JP2019016330A - Rfid tag label and rfid tag label continuous body - Google Patents

Abstract

To provide an RFID tag label having universality capable of coping with all merchandise marketed at a retail store, which does not require much labor of its attachment to the merchandise.SOLUTION: An RFID tag label 1 comprises: a surface layer sheet 10; an adhesive layer 11; an inlet sheet 12 on which at least an antenna 121 and an IC chip 120 connected thereto are mounted; an adhesive layer 13; and a peeling mount 14 for protecting the adhesive layer 13. A back split 140 as a boundary between a partial paste part 13b for exposing the adhesive layer 13 when the RFID label tag is attached to merchandise and a non-paste part 13a for preventing the adhesive layer 13 from being exposed when the RFID label tag is attached to the merchandise is processed to the peeling mount 14, and a size of a second radiation element 121b is larger than a size of a first radiation element 121a, and the first radiation element 121a and an inductance element 121c are arranged at a non-paste part 13a side, and the second radiation element 121b is arranged at a partial paste part 13b side.SELECTED DRAWING: Figure 1

Description

The present invention relates to an RFID tag label used for merchandise management of merchandise sold at a retail store.
This application claims the priority of the application number 2017-130913 for which it applied to Japan on July 4, 2017, The content of the said application is used for this specification.

  Among the products sold in retail stores, drinking water (eg, canned coffee) using metal cans and plastic bottles as containers, and household items (eg, kitchen detergent) using plastic bottles as containers. ), There are many and many products that have characteristics that obstruct wireless communication, such as foods (for example, potato chips) that use a bag with a vapor-deposited film as a container, and RFID is used for product management of products sold at retail stores. When using a tag label, the RFID tag label is required to be versatile enough to be compatible with all products sold in retail stores.

  As an RFID tag label corresponding to a product having a characteristic that inhibits wireless communication, for example, in Patent Document 1, an RFID configured to form a dipole antenna with a partial antenna composed of a radiating element and a matching circuit and a metal housing Although a tag label is disclosed, if an RFID tag label that functions as a part of an antenna is attached to a surface other than metal, the communication performance of the RFID tag label deteriorates.

  If the RFID tag label and the product are separated from each other, the RFID tag label is not affected by the product. Therefore, an attention seal (attached to PET bottled water, etc., rather than associating the RFID tag label with a product having a characteristic that inhibits wireless communication) If a part of the RFID tag label is affixed away from the product, such as an eye-catching sticker or POP sticker, it will be easy to achieve versatility that can be applied to all products sold in retail stores. It is done.

  As an RFID tag label that can be partly attached to a product in a separated state, for example, in Patent Document 2, a mounting portion for mounting on a mounted body such as a container and a protruding portion away from the mounted body when mounted An RFID tag label having a projecting portion and an IC tag mounted on the projecting portion is disclosed, but with the RFID tag label having this configuration, the size of the antenna is limited to the size of the projecting portion, and the product The communication distance required for management cannot be obtained.

  As an RFID tag label that can be partially pasted away from a product and that can increase the size of an antenna, for example, in Patent Document 3, a power supply region that supplies power to an IC chip and a radiation region that receives and transmits electromagnetic waves An RFID tag label is disclosed in which an antenna having at least an antenna is mounted and attached to an adherend (book) so that a part of the radiation area of the antenna protrudes from the adherend. In the disclosed RFID tag label, in order to make a portion with and without an adhesive layer, it is necessary to fold back the RFID tag label and perform paste killing.

JP 2012-104985 A JP 2006-3497 A JP, 2006-62576, A

  Therefore, an object of the present invention is to provide an RFID tag label that has the versatility that can be applied to all products sold in retail stores and that does not require time and effort to affix to the product.

  A first invention that solves the above-described problems includes an antenna having an inductance element that is connected to the first radiating element, the second radiating element, the first radiating element and the second radiating element, and adjusts a resonance frequency. An inlet sheet on which at least an IC chip to be connected is mounted, an adhesive layer formed on the back surface of the inlet sheet, and a release mount that protects the adhesive layer are provided. A spine that is a boundary between a partial glue portion that exposes the adhesive layer and a paste-killing portion that does not expose the adhesive layer when pasted on a product is processed, and the size of the second radiating element is larger than the size of the first radiating element The first radiating element and the inductance element are arranged on the side of the paste-killing portion, and the second radiating element is arranged on the side of the partial glue portion. An RFID tag label to. In order to make the piece protruding from the product more difficult to bend, the RFID tag label according to the first invention uses a base material having a bending elastic modulus of 1000 to 4000 MPa and a bending strength of 20 to 120 MPa according to the test conditions of JIS7171. It is preferable that the shape of the back split is set so that a part of the paste-killing part enters the partial glue part.

  A second invention that solves the above-described problem includes an antenna having an inductance element that is connected to the first radiating element, the second radiating element, the first radiating element and the second radiating element, and adjusts a resonance frequency. An inlet sheet on which at least an IC chip to be connected is mounted, an adhesive layer formed on the back surface of the inlet sheet, and a release mount that protects the adhesive layer are provided. A spine that is a boundary between a partial glue portion that exposes the adhesive layer and a paste-killing portion that does not expose the adhesive layer when pasted on a product is processed, and the size of the second radiating element is the size of the first radiating element RFI is arranged such that the first radiating element and the inductance element are arranged on the side of the paste part, and the second radiating element is arranged on the side of the partial glue part. Tag label, it is an RFID tag label continuum, characterized in being formed in a plurality articulated state to strip through the perforations. In order to make the piece protruding from the product more difficult to bend, in the RFID tag label continuum according to the second invention, a base material having a bending elastic modulus of 1000 to 4000 MPa and a bending strength of 20 to 120 MPa according to the test conditions of JIS7171. Is preferably used for the peeling mount of the RFID tag label, and the spine shape of the RFID tag label is set so that a part of the paste-killing portion enters the partial glue portion.

  According to the RFID tag label according to the present invention described above, the RFID tag label is used in a state in which the side of the paste-killing portion protrudes from the product by using the area of the adhesive layer exposed by peeling off the peeling mount on the side of the partial glue portion. By sticking to the product, you can achieve versatility that can handle all products sold at retail stores. In addition, when the RFID tag label according to the present invention is attached to a product, it is only an operation of peeling off the peeling mount on the side of the partial glue portion, so that it does not take time and effort to attach the product to the product.

The figure explaining the external appearance of the RFID tag label which concerns on embodiment. The figure explaining the layer structure of the RFID tag label which concerns on this embodiment. The figure explaining the RFID tag label of the state affixed on the goods. The figure explaining the inlet sheet which comprises an RFID tag label. The figure explaining the modification of spine splitting. The figure explaining a RFID tag label continuous body. 6A and 6B are diagrams illustrating an appearance of an RFID tag label according to Modification 1. 10A and 10B are diagrams illustrating a layer structure of an RFID tag label according to Modification 1. The figure explaining the RFID tag label which concerns on the modification 1 of the state affixed on the goods. The figure explaining the inlet sheet which concerns on the modification 1. FIG. The figure explaining the modification of the back split concerning the modification 1. FIG. The figure explaining the RFID tag label continuous body concerning the modification 1. FIG.

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

  1A and 1B are views for explaining the external appearance of an RFID tag label 1 according to the present embodiment. FIG. 1A is a view for explaining the surface of the RFID tag label 1, and FIG. FIG. 1C, which is a diagram for explanation, is a diagram for explaining the back side of the RFID tag label 1 when pasted on a product.

  The RFID tag label 1 according to the present embodiment is a seal label type RFID tag designed to have all-purpose compatibility with all products sold at large retail stores. As shown in FIG. 2, the RFID tag label 1 according to the present embodiment incorporates an IC chip 120 and an antenna 121 connected thereto as a circuit used for individual identification using radio.

  The surface of the RFID tag label 1 is covered with a surface layer sheet 10 as illustrated in FIG. Arbitrary characters and patterns (“product management tag” in FIG. 1A) can be printed on the surface layer sheet 10. As characters and patterns to be printed on the surface sheet 10, it is preferable to use advertisements for retail stores and products.

  As shown in FIG. 1B, an adhesive layer 13 for attaching the RFID tag label 1 to a product is formed on the entire back surface of the RFID tag label 1, and the adhesive layer 13 is substantially the same as the adhesive layer 13. It is protected by a release mount 14 of the same size.

  The release mount 14 that protects the adhesive layer 13 formed on the back surface of the RFID tag label 1 is processed with a straight spine 140 (cut) that divides the release mount 14 in the short direction. The pressure-sensitive adhesive layer 13 is divided into a partial glue portion 13b that exposes the pressure-sensitive adhesive layer 13 when affixed to a product and a paste-killing portion 13a that does not expose the pressure-sensitive adhesive layer 13 when affixed to a product. In FIG. 1B, the RFID tag label 1 is affixed to the product in the release mount 14 on the side of the partial glue portion 13b so that the release mount 14 on the side of the partial paste portion 13b is removed without mistake. A character indicating that it is sometimes peeled off (in FIG. 1B, “peeling off”) is printed, and the RFID tag label 1 is not peeled off when affixed to a product on the peeling mount 14 on the side of the paste killing portion 13a. Characters to be shown (“Leave” in FIG. 1B) are printed.

  As shown in FIG. 1C, when the RFID tag label 1 is affixed to a product, the peeling mount 14 on the side of the partial glue portion 13b is peeled off, so that the peeling mount 14 on the side of the partial glue portion 13b is used. The region of the pressure-sensitive adhesive layer 13 that has been protected is exposed. Further, when the RFID tag label 1 is affixed to the product, the adhesive layer 13 protected by the release mount 14 on the paste killing portion 13a side is prevented by not peeling off the release mount 14 on the paste killing portion 13a side. The region remains in a paste-killing state (a state where the adhesive does not function).

  The layer structure of the RFID tag label 1 according to this embodiment will be described. FIG. 2 is a view for explaining the layer structure of the RFID tag label 1 according to this embodiment, and is a cross-sectional view taken along the line A-A ′ in FIG.

  The RFID tag label 1 according to the present embodiment includes, in order from the surface of the RFID tag label 1, a surface layer sheet 10 that becomes the surface of the RFID tag label 1, an adhesive layer 11 formed on the back surface of the surface layer sheet 10, and a protective film made of a cured resin. An inlet sheet 12 on which at least the covered IC chip 120 and the antenna 121 connected thereto are mounted, an adhesive layer 13 formed on the back surface of the inlet sheet 12, and a release mount 14 for protecting the adhesive layer 13 are laminated. The release mount 14 is processed with a spine 140 indicating the boundary between the partial paste portion 13b and the paste-killing portion 13a.

  The surface layer sheet 10 constituting the RFID tag label 1 is a sheet that protects the surface of the RFID tag label 1, and arbitrary characters and designs can be printed on the surface layer sheet 10. As the surface layer sheet 10 constituting the RFID tag label 1, for example, art paper or the like can be used in addition to a synthetic resin film such as polyethylene terephthalate (PET) or polypropylene (PP).

  The adhesive layer 11 constituting the RFID tag label 1 is a layer for adhering (attaching) the surface layer sheet 10 and the inlet sheet 12. As long as the required adhesive strength can be obtained, any adhesive may be used for forming the adhesive layer 11. For example, various adhesives such as rubber, vinyl acetate emulsion and acrylic can be used for forming the adhesive layer 11.

  As a base material of the inlet sheet 12 constituting the RFID tag label 1, for example, a synthetic resin film such as polyethylene terephthalate (PET) or polypropylene (PP) can be used. As will be described later, since the antenna 121 mounted on the inlet sheet 12 is a dipole antenna, as a method of forming the antenna 121 mounted on the inlet sheet 12, the shape of the antenna 121 is printed on a base material using conductive ink. A screen printing method that performs the etching, or an etching method that etches the metal foil provided on the base material into the shape of the antenna 121 can be used. The IC chip 120 mounted on the inlet sheet 12 includes a wireless communication interface, a memory for storing data used for merchandise management, and the like, and is mounted on the antenna 121 in a state of being covered with a cured resin.

  The pressure-sensitive adhesive layer 13 constituting the RFID tag label 1 is a layer for attaching the RFID tag label 1 to a product. Although the adhesive layer 11 constituting the RFID tag label 1 may be in a solidified state, the pressure-sensitive adhesive layer 13 constituting the RFID tag label 1 must maintain its adhesiveness, and the pressure-sensitive adhesive constituting the RFID tag label 1 An acrylic or rubber adhesive can be used for forming the layer 13.

  The peeling mount 14 constituting the RFID tag label 1 is a layer for protecting the adhesive layer 13 constituting the RFID tag label 1, and a spine 140 indicating the boundary between the partial glue portion 13b and the paste killing portion 13a is processed. As the release mount 14 constituting the RFID tag label 1, a synthetic resin film or paper in which a release agent such as silicone is applied on the surface in contact with the adhesive layer 13 can be used.

  FIG. 3 is a diagram for explaining the RFID tag label 1 in a state of being attached to a product. When the RFID tag label 1 according to the present embodiment is used for merchandise management in a retail store, as shown in FIG. 3, the RFID tag label 1 is exposed by peeling off the peeling mount 14 on the side of the partial glue portion 13b. The region of the pressure-sensitive adhesive layer 13 is used, and is pasted on the product 3 with the paste-killing portion 13a protruding from the product 3. As shown in FIG. 3, by attaching the RFID tag label 1 to the product 3, the partial glue portion 13 b is in close contact with the product 3, but the paste killing portion 13 a side is separated from the product 3.

  FIG. 4 is a view for explaining the inlet sheet 12 constituting the RFID tag label 1. Since the size of the inlet sheet 12 is the same as the size of the RFID tag label 1, FIG. 4 illustrates reference values for the size of the inlet sheet 12 and the size of the antenna 121.

  The inlet sheet 12 is a sheet on which at least an IC chip 120 covered with a protective film made of a cured resin and an antenna 121 connected thereto are mounted. The antenna 121 mounted on the inlet sheet 12 has a characteristic that inhibits wireless communication. Even if the RFID tag label 1 is affixed to the device, a measure is taken to prevent the communication characteristics of the RFID tag label 1 from being extremely deteriorated.

  Specifically, the antenna 121 according to the present embodiment is a small dipole antenna, and includes a first radiating element 121a, a second radiating element 121b, and an inductance element 121c. The first radiating element 121a and the second radiating element 121b of the antenna 121 are elements used for power supply and signal transmission / reception. In FIG. 4, the first radiating element 121a and the second radiating element 121b have a wide band shape. (Rectangular). The inductance element 121c of the antenna 121 is an element for adjusting the resonance frequency of the antenna 121 in a state where it is connected to the IC chip 120 to be close to a predetermined frequency. In FIG. 4, the inductance element 121c has a loop shape.

  In the RFID tag label 1 according to the present embodiment, as a device for preventing the communication characteristics of the RFID tag label 1 from being extremely deteriorated even if the RFID tag label 1 is attached to a product having a characteristic that inhibits wireless communication, the paste killing portion 13a The first radiating element 121a and the inductance element 121c are arranged in the region of the inlet sheet 12 on the side of the side, and the second radiating element 121b is arranged in the region of the inlet sheet 12 on the side of the partial glue portion 13b.

  The reason why the inductance element 121c is arranged in the region of the inlet sheet 12 on the paste killing portion 13a side is to reduce the influence of the inductance element 121c from the product to which the RFID tag label 1 is attached. When the inductance element 121c is greatly affected by the product with the RFID tag label 1 attached, the inductance when the RFID tag label 1 is attached to a product having a characteristic that obstructs wireless communication (for example, a product using a metal can as a container). The resonance frequency adjusted using the element 121c shifts in the low frequency direction, and the IC chip 120 that receives power supply from the antenna 121 becomes difficult to operate. However, in the RFID tag label 1 according to the present embodiment, the inductance element is changed from the product. This is prevented by separating 121c.

  In the case of the antenna 121 having the configuration shown in FIG. 4, if the area of the radiating elements (the first radiating element 121a and the second radiating element 121b) is large, the communication performance (for example, the communication distance) is improved, but the paste killing portion 13a. If the size of the portion of the RFID tag label 1 on the side is large, this portion becomes a hindrance when displaying the product, so the first radiating element disposed in the region of the inlet sheet 12 on the paste killing portion 13a side The area of 121a cannot be increased. Therefore, in the RFID tag label 1 according to the present embodiment, the area of the first radiating element 121a arranged in the region of the inlet sheet 12 on the paste killing portion 13a side is reduced to compensate for the area of the first radiating element 121a. In addition, the area of the second radiating element 121b disposed in the region of the inlet sheet 12 on the side of the partial glue portion 13b is increased.

  In FIG. 1 and the like, the shape of the spine 140 indicating the boundary between the partial paste portion 13b and the paste-killing portion 13a is linear, but the first radiating element 121a and the inductance element 121c are arranged on the paste-killing portion 13a side. As long as the second radiating element 121b is arranged on the side of the partial glue portion 13b, the shape of the spine 140 may be arbitrary. FIG. 5 is a diagram for explaining a modification of the spine 140. The spine 140 that divides the RFID tag label 1 into a partial glue portion 13b and a paste killing portion 13a is an arcuate spine 140a (FIG. 5 (a)) or a mountain shape. The spine 140b (FIG. 5B) may be used.

  The RFID tag label 1 described so far can be in the form of a strip as well as the rectangle shown in FIG. FIG. 6 is a view for explaining an RFID tag label continuous body 2 in which the RFID tag label 1 shown in FIG.

  The RFID tag label continuous body 2 illustrated in FIG. 6 is a belt-shaped medium in which a plurality of RFID tag labels 1 illustrated in FIG. 1 are connected, and the RFID tag label continuous body 2 illustrated in FIG. 6 can be wound in a reel shape. .

  FIG. 6A is a diagram for explaining the layer structure of the RFID tag label continuum 2 and is a cross-sectional view taken along line B-B ′ in FIG. The RFID tag label continuum 2 according to the present embodiment includes, in order from the surface of the RFID tag label continuum 2, a strip-shaped surface sheet 20 that becomes the surface of the RFID tag label continuum 2, and a strip-shaped surface layer 20 formed on the back surface of the strip-shaped surface layer sheet 20. Adhesive layer 21, strip-shaped inlet sheet 22 in which IC chip 220 covered with a protective film made of a cured resin and antenna 221 connected thereto are mounted at a predetermined interval, and strip-shaped inlet sheet 22 formed on the back surface of strip-shaped inlet sheet 22 The adhesive layer 23 and a strip-shaped release mount 24 that protects the strip-shaped adhesive layer 23 are laminated, and the strip-shaped release mount 24 is processed with a straight spine 240 in the longitudinal direction. . In addition, perforations 25 used when cutting the RFID tag label continuous body 2 in units of the RFID tag label 1 are processed in the RFID tag label continuous body 2 at intervals corresponding to the length of the RFID tag label 1 in the short direction. , The RFID tag label 1 is connected in a plurality of strips through the perforation 25.

  FIG. 6B is a view for explaining the surface of the RFID tag label continuous body 2. A predetermined character (here, “product management tag”) is printed on the RFID tag label continuum 2 for each unit of the RFID tag label 1.

  FIG. 6C is a view for explaining the back surface of the RFID tag label continuous body 2. On the strip-like release mount 24 on the back surface of the RFID tag label continuum 2, a spine 240 serving as a boundary between the partial glue portion 23 b and the paste-killing portion 23 a is processed along the longitudinal direction. A rectangular detection mark 241 that is detected when the tag label continuous body 2 is cut is printed in advance. The antenna 221 mounted on the strip-shaped inlet sheet 22 has the same configuration as that of the antenna 121 illustrated in FIG. 4, and the spine 240 processed on the strip-shaped peeling mount 24 corresponds to the gap between the inductance element 221c and the second radiation element 221b. It is processed to the position to do.

  Such an RFID tag label continuum 2 uses a step of forming a strip-shaped adhesive layer 21 on the back surface of the strip-shaped surface layer sheet 20, a strip-shaped adhesive layer 21 formed on the back surface of the strip-shaped surface layer sheet 20, A step of bonding the strip-shaped inlet sheet 12 and the strip-shaped surface layer sheet 20 in which the IC chip 220 covered with a protective film made of a cured resin and the antenna 221 connected to the IC chip 220 are mounted at predetermined intervals, and a strip-shaped strip on the back surface of the strip-shaped inlet sheet 22 Forming the adhesive layer 23, laminating the strip-like release mount 24 on the strip-like adhesive layer 23, and processing the spine 240 on the strip-like release mount 24 laminated on the strip-like adhesive layer 23. It can be manufactured by executing.

  From here, the modification which made the piece which protrudes from goods harder to bend is demonstrated. FIG. 7 is a diagram for explaining the external appearance of the RFID tag label 4 according to the first modification. FIG. 7A is a diagram for explaining the surface of the RFID tag label 4 according to the first modification, and FIG. FIG. 7C is a diagram for explaining the back surface of the RFID tag label 4 according to Modification Example 1 when being attached to a product.

  The RFID tag label 4 according to the first modification is a seal label type RFID tag designed to have all-purpose compatibility with all products sold at large retail stores. ), The RFID tag label 4 according to the first modification incorporates an IC chip 420 and an antenna 421 connected thereto as a circuit used for individual identification using radio.

  As illustrated in FIG. 7A, the surface of the RFID tag label 4 according to Modification 1 is covered with a surface layer sheet 40. Arbitrary characters and patterns (“product management tag” in FIG. 7A) can be printed on the surface layer sheet 40. As characters and patterns to be printed on the surface layer sheet 40, it is preferable to use advertisements for retail stores and products.

  As illustrated in FIG. 7B, an adhesive layer 43 for attaching the RFID tag label 4 according to the modified example 1 to a product is formed on the entire back surface of the RFID tag label 4 according to the modified example 1. The layer 43 is protected by a release mount 44 having almost the same size as the pressure-sensitive adhesive layer 43.

  The release mount 44 that protects the adhesive layer 43 formed on the back surface of the RFID tag label 4 according to the modified example 1 has a back split 440 (cut) that divides the release mount 44 in the short direction. The adhesive layer 43 is divided into a partial glue portion 43b that exposes the adhesive layer 43 when affixed to a product and a paste-killing portion 43a that does not expose the adhesive layer 43 when affixed to a product. In FIG. 7B, the RFID tag label 4 according to Modification 1 is placed in the peeling mount 44 on the side of the partial glue portion 43b so that the peeling mount 44 on the side of the partial paste portion 43b is removed without mistake. Is printed on the release mount 44 on the side of the paste-killing portion 43a, and the RFID tag label 4 according to the first modification is printed on the release paste 44 on the side of the paste-killing portion 43a. Characters (in FIG. 7B, “Leave”) indicating that they will not be peeled off are printed when pasting on a product.

  As shown in FIG. 7C, when the RFID tag label 4 according to the modified example 1 is attached to the product, the peeling mount 44 on the side of the partial glue portion 43b is peeled off, so that the partial paste portion 43b side. The area of the pressure-sensitive adhesive layer 43 protected by the peeling mount 44 is exposed. In addition, when the RFID tag label 4 according to Modification 1 is attached to the product, the peeling mount 44 on the side of the paste killing portion 43a is not peeled off, so that the RFID tag label 4 according to Modification 1 is attached to the product. The area of the pressure-sensitive adhesive layer 43 protected by the release mount 44 on the side of the killing portion 43a remains in a paste-killing state (a state where the pressure-sensitive adhesive does not function).

  The RFID tag label 4 according to the modified example 1 is attached to the product using the partial paste portion 43b of the adhesive layer 43, with one piece projecting from the paste killing portion 43a protruding from the product. The RFID tag label 4 according to the modified example 1 is one of the devices that makes it difficult for the piece of the paste-killing portion 43a to bend because a piece of the paste-killing portion 43a that protrudes from the product is easily bent when the piece is bent. As shown in FIG. 7, the back split 440 is processed so that a part of the paste-killing portion 43a enters the partial paste portion 43b.

  A layer configuration of the RFID tag label 4 according to Modification 1 will be described. FIG. 8 is a diagram for explaining the layer structure of the RFID tag label 4 according to Modification 1, and is a cross-sectional view taken along the line C-C ′ in FIG.

  The RFID tag label 4 according to Modification 1 includes a surface layer sheet 40 that becomes the surface of the RFID tag label 4 according to Modification 1 and an adhesive formed on the back surface of the surface layer sheet 40 in order from the surface of the RFID tag label 4 according to Modification 1. Layer 41, an IC chip 420 covered with a protective film made of a cured resin, an inlet sheet 42 on which at least an antenna 421 connected thereto is mounted, an adhesive layer 43 formed on the back surface of the inlet sheet 42, and an adhesive layer 43. The protective backing sheet 44 is laminated, and the release backing 44 is processed with a spine 440 having a shape set so that the boundary between the partial paste portion 43b and the paste-killing portion 43a enters. Yes.

  The surface layer sheet 40 constituting the RFID tag label 4 according to the first modification is a sheet for protecting the surface of the RFID tag label 4 according to the first modification, and arbitrary characters and designs can be printed on the surface layer sheet 40. As the surface layer sheet 40 constituting the RFID tag label 4 according to Modification 1, for example, art paper or the like can be used in addition to a synthetic resin film such as polyethylene terephthalate (PET) or polypropylene (PP).

  The adhesive layer 41 constituting the RFID tag label 4 according to Modification 1 is a layer for adhering (attaching) the surface layer sheet 40 and the inlet sheet 42. Any adhesive may be used for forming the adhesive layer 41 as long as the necessary adhesive strength can be obtained. For example, various adhesives such as rubber, vinyl acetate emulsion, and acrylic can be used for forming the adhesive layer 41.

  As a base material of the inlet sheet 42 constituting the RFID tag label 4 according to the modification 1, for example, a synthetic resin film such as polyethylene terephthalate (PET) or polypropylene (PP) can be used. As will be described later, since the antenna 421 mounted on the inlet sheet 42 is a dipole antenna, as a method of forming the antenna 421 mounted on the inlet sheet 42, the shape of the antenna 421 is printed on a base material using conductive ink. A screen printing method that performs the etching, or an etching method that etches the metal foil provided on the substrate into the shape of the antenna 421 can be used. The IC chip 420 to be mounted on the inlet sheet 42 includes a wireless communication interface, a memory for storing data used for merchandise management, and the like, and is mounted on the antenna 421 while being covered with a cured resin.

  The adhesive layer 43 constituting the RFID tag label 4 according to the first modification is a layer for attaching the RFID tag label 4 according to the first modification to a product. The adhesive layer 41 constituting the RFID tag label 4 according to the first modification may be in a solidified state, but the adhesive layer 43 constituting the RFID tag label 4 according to the first modification must maintain the adhesiveness. First, for the formation of the pressure-sensitive adhesive layer 43 constituting the RFID tag label 4 according to the first modification, an acrylic or rubber-based pressure-sensitive adhesive can be used.

The peeling mount 44 constituting the RFID tag label 4 according to the modification 1 is a layer for protecting the adhesive layer 43 constituting the RFID tag label 4 according to the modification 1, and is a boundary between the partial glue portion 43b and the paste killing portion 43a. A back split 440 is processed. As the release mount 44 constituting the RFID tag label 4 according to the first modification, a synthetic resin film or paper in which a release agent such as silicone is applied to the surface in contact with the adhesive layer 43 can be used. In the present embodiment, a plastic base material that satisfies the following bending characteristics is used for the peeling mount 44 as one of the devices that make it difficult for the piece on the side of the paste-killing portion 43a protruding from the product to be bent.
<Bending characteristics according to JIS 7171 test conditions>
Flexural modulus 1000 to 4000 MPa
Bending strength 20-120MPa

  FIG. 9 is a diagram for explaining the RFID tag label 4 according to Modification 1 in a state of being attached to a product. When the RFID tag label 4 according to the modified example 1 is used for merchandise management in a retail store, as shown in FIG. 9, the RFID tag label 4 according to the modified example 1 has a peeling mount 44 on the side of the partial glue portion 43b. The area of the pressure-sensitive adhesive layer 43 exposed by peeling off is used, and is pasted on the product 6 in a state where the paste-killing portion 43 a side protrudes from the product 6.

  As illustrated in FIG. 9, the RFID according to the first modification is used so that a piece of the paste-killing portion 43 a on which the peeling mount 44 is left protrudes from the product 6 using the partial paste portion 43 b of the adhesive layer 43. When the tag label 4 is affixed to the product 6, the part of the peeling mount 44 corresponding to a part of the paste-killing portion 43a that has entered the partial glue portion 43b is similar to that between the books 6 and the adhesive layer 43. A piece on the side of the paste-killing portion 43a protrudes from the product 6 while being sandwiched between them.

  FIG. 10 is a view for explaining the inlet sheet 42 constituting the RFID tag label 4 according to the first modification. Since the size of the inlet sheet 42 is the same as the size of the RFID tag label 4 according to the first modification, FIG. 10 illustrates reference values for the size of the inlet sheet 42 and the size of the antenna 421.

  The inlet sheet 42 is a sheet on which at least an IC chip 420 covered with a protective film made of a cured resin and an antenna 421 connected thereto are mounted. The antenna 421 mounted on the inlet sheet 42 has a characteristic that obstructs wireless communication. Even if the RFID tag label 4 according to the modification 1 is attached, the device is designed so that the communication characteristics of the RFID tag label 4 according to the modification 1 are not extremely deteriorated.

  Specifically, the antenna 421 according to the present embodiment is a small dipole antenna, and includes a first radiating element 421a, a second radiating element 421b, and an inductance element 421c. The first radiating element 421a and the second radiating element 421b of the antenna 421 are elements used for power supply and signal transmission / reception. In FIG. 10, the first radiating element 421a and the second radiating element 421b have a wide band shape. (Rectangular). The inductance element 421c of the antenna 421 is an element for adjusting the resonance frequency of the antenna 421 in a state where it is connected to the IC chip 420 to the vicinity of a predetermined frequency. In FIG. 10, the inductance element 421c has a loop shape.

  In the RFID tag label 4 according to the first modification, even if the RFID tag label 4 according to the first modification is attached to a product having a characteristic that inhibits wireless communication, the communication characteristics of the RFID tag label 4 according to the first modification are not extremely deteriorated. As a contrivance, the first radiating element 421a and the inductance element 421c are arranged in the region of the inlet sheet 42 on the side of the paste-killing portion 43a, and the first radiating element 421c is disposed in the region of the inlet sheet 42 on the side of the partial paste portion 43b. Two radiating elements 421b are arranged.

  The reason why the inductance element 421c is disposed in the region of the inlet sheet 42 on the side of the paste killing portion 43a is to reduce the influence of the inductance element 421c from the product on which the RFID tag label 4 according to the modified example 1 is attached. It is. When the inductance element 421c is greatly affected by the product to which the RFID tag label 4 according to the modified example 1 is attached, the product according to the modified example 1 has a characteristic that inhibits wireless communication (for example, a product using a metal can as a container). When the RFID tag label 4 is attached, the resonance frequency adjusted by using the inductance element 421c shifts in the low frequency direction, and the IC chip 420 that receives power supply from the antenna 421 becomes difficult to operate. This RFID tag label 4 prevents this by separating the inductance element 421c from the product.

  In the case of the antenna 421 having the configuration shown in FIG. 10, if the area of the radiating elements (the first radiating element 421a and the second radiating element 421b) is large, the communication performance (for example, the communication distance) is improved. If the size of the RFID tag label 4 according to the modified example 1 on the side is large, this portion becomes an obstacle when displaying the product, so it is arranged in the region of the inlet sheet 42 on the paste killing portion 43a side. The area of the first radiating element 421a cannot be increased. Therefore, in the RFID tag label 4 according to the modified example 1, the area of the first radiating element 421a disposed in the region of the inlet sheet 42 on the paste killing portion 43a side is reduced to compensate for the area of the first radiating element 421a. In addition, the area of the second radiating element 421b disposed in the region of the inlet sheet 42 on the side of the partial glue portion 43b is increased.

  If the part of the paste killing part 43a enters the partial glue part 43b, that is, the state where the boundary between the part paste part 43b and the paste killing part 43a enters, the shape of the spine 440 becomes the shape of FIG. It is not limited. FIG. 11 is a diagram for explaining a modified example of the spine split 440. The spine split 440 for dividing the RFID tag label 4 according to the modified example 1 into a partial glue portion 43b and a paste killing portion 43a is an arc-shaped spine split 440a (FIG. 11 (a)). ) Or a mountain-shaped spine 440b (FIG. 11B).

  According to the RFID tag label 4 according to the modified example 1 described above, the area of the adhesive layer 43 exposed by peeling off the peeling mount 44 on the side of the partial glue part 43b is used to remove the adhesive part 43a from the product. By sticking the RFID tag label 4 according to the modified example 1 to the product in a protruding state, it is possible to realize versatility that can correspond to all the products sold in retail stores. Further, when the RFID tag label 4 according to the modified example 1 is attached to the product, only the peeling mount 44 on the side of the partial glue portion 43b is peeled off. Furthermore, in the RFID tag label 4 according to the modified example 1, the base material having a bending elastic modulus of 1000 to 4000 MPa and a bending strength of 20 to 120 MPa is used as the release mount 44 according to the test conditions of JIS7171, so that it protrudes from the product. The one piece is difficult to bend. Further, when the RFID tag label 4 according to the modified example 1 is attached to the product, the part of the peeling mount 44 corresponding to a part of the paste-killing portion 43a entering the partial glue portion 43b is like a bag sandwiched between books. And the pressure-sensitive adhesive layer 43, the piece protruding from the product is difficult to bend.

  The form of the RFID tag label 4 according to the modified example 1 described so far can be not only the rectangular (rectangular) form illustrated in FIG. 7 but also a belt-like form. FIG. 12 is a diagram for explaining the RFID tag label continuum 5 according to the first modification.

  The RFID tag label continuum 5 according to Modification 1 is a belt-like medium in which a plurality of RFID tag labels 4 according to Modification 1 are connected, and the RFID tag label continuum 5 according to Modification 1 can be wound in a reel shape. .

  FIG. 12A is a diagram for explaining the layer structure of the RFID tag label continuum 5 according to Modification 1, and is a cross-sectional view taken along the line D-D ′ in FIG. The RFID tag label continuum 5 according to Modification 1 includes, in order from the surface of the RFID tag label continuum 5 according to Modification 1, a belt-shaped surface sheet 50 that becomes the surface of the RFID tag label continuum 5 according to Modification 1, A strip-shaped adhesive sheet 51 formed on the back surface of the surface layer sheet 50, a strip-shaped inlet sheet 52 in which an IC chip 520 covered with a protective film made of a cured resin and an antenna 521 connected thereto are mounted at a predetermined interval; A strip-shaped adhesive layer 53 formed on the back surface of the inlet sheet 52 and a strip-shaped release mount 54 that protects the strip-shaped adhesive layer 53 are laminated. A spine split 540 that divides the band-shaped adhesive layer 53 into 53a and a partial glue portion 53b is continuously processed, and the shape of the spine split 540 is such that a part of the paste-killing portion 53a is partially glued portion 5 It is set to be in a state that has entered the b. In addition, the RFID tag label continuum 5 according to the first modification includes a perforation 55 used when cutting the RFID tag label continuum 5 according to the first modification in units of the RFID tag label 4 according to the first modification. The RFID tag label 4 according to the first modification is processed at intervals corresponding to the length in the short direction, and a plurality of RFID tag labels 4 according to the first modification are connected in a band shape via the perforation 55.

  FIG. 12B is a view for explaining the surface of the RFID tag label continuum 5 according to the first modification. A predetermined character (here, “product management tag”) is printed on the RFID tag label continuum 5 according to the first modification for each unit of the RFID tag label 4 according to the first modification.

  FIG. 12C is a diagram for explaining the back surface of the RFID tag label continuum 5 according to the first modification. In the strip-shaped peeling mount 54 which is the back surface of the RFID tag label continuous body 5 according to the modification 1, a back split 540 which is a boundary between the partial paste portion 53b and the paste killing portion 53a is processed along the longitudinal direction. A rectangular detection mark 541 that is detected when the RFID tag label continuous body 5 according to the modification 1 is cut in units of the RFID tag label 4 according to 1 is printed in advance. The antenna 521 mounted on the strip-shaped inlet sheet 52 has the same configuration as the antenna 521 shown in FIG. 10, and the spine 540 processed into the strip-shaped peeling mount 54 is equivalent to between the inductance element 521c and the second radiating element 521b. The shape is set so that the boundary between the partial paste portion 53b and the paste-killing portion 53a enters.

  The RFID tag label continuum 5 according to Modification 1 uses the step of forming a strip-shaped adhesive layer 51 on the back surface of the strip-shaped surface layer sheet 50, and the strip-shaped adhesive layer 51 formed on the back surface of the strip-shaped surface layer sheet 50. The step of bonding the strip-shaped inlet sheet 52 in which the IC chip 520 covered with a protective film made of a cured resin and the antenna 521 connected to the IC chip 520 are mounted at a predetermined interval and the strip-shaped surface layer sheet 50 are bonded, and the back surface of the strip-shaped inlet sheet 52 The step of forming the strip-shaped adhesive layer 53, the step of stacking the strip-shaped release mount 54 on the strip-shaped adhesive layer 53, and the back split 540 are processed into the strip-shaped release mount 54 stacked on the strip-shaped adhesive layer 53. It can be manufactured by executing a process.

1, 4 RFID tag label 10, 40 Surface sheet 11, 41 Adhesive layer 12, 42 Inlet sheet 120, 420 IC chip 121, 421 Antenna 121a, 421a First radiating element 121b, 421b Second radiating element 121c, 421c Inductive element 13 , 43 Adhesive layer 13a, 43a Paste kill part 13b, 43b Partial glue part 14, 44 Stripping mount 140, 440 Back split 2, 5 RFID tag label continuous body

Claims (4)

  A first radiating element, a second radiating element, an antenna having an inductance element connected to the first radiating element and the second radiating element to adjust a resonance frequency, and an inlet sheet on which at least an IC chip connected thereto is mounted; , A pressure-sensitive adhesive layer formed on the back surface of the inlet sheet, and a release mount for protecting the pressure-sensitive adhesive layer, and the release mount has a partial glue portion and a product for exposing the pressure-sensitive adhesive layer when affixed to the product A spine that is a boundary of the paste-killing portion that does not expose the adhesive layer when being attached to the substrate is processed, and the size of the second radiating element is larger than the size of the first radiating element, and the first radiating element and the inductance An RFID tag label, wherein an element is disposed on the side of the paste-killing portion, and the second radiating element is disposed on the side of the partial paste portion.   A base material having a bending elastic modulus of 1000 to 4000 MPa and a bending strength of 20 to 120 MPa is used for the release mount, and the shape of the spine is divided, and a part of the paste-killing part is the partial glue part. The RFID tag label according to claim 1, wherein the RFID tag label is set so as to be in an intrusive state.   A first radiating element, a second radiating element, an antenna having an inductance element connected to the first radiating element and the second radiating element to adjust a resonance frequency, and an inlet sheet on which at least an IC chip connected thereto is mounted; , A pressure-sensitive adhesive layer formed on the back surface of the inlet sheet, and a release mount for protecting the pressure-sensitive adhesive layer, and the release mount has a partial glue portion and a product for exposing the pressure-sensitive adhesive layer when affixed to the product The spine that forms the boundary of the paste-killing portion that does not expose the adhesive layer when being attached to the substrate is processed, and the size of the second radiating element is larger than the size of the first radiating element, and the first radiating element and the The inductance element is disposed on the paste part side, and the second radiating element is disposed on the partial glue part side. RFID label continuum, characterized in that it is formed in a plurality articulated state to. A base material having a bending elastic modulus of 1000 to 4000 MPa and a bending strength of 20 to 120 MPa is used for the peeling mount of the RFID tag label, and the shape of the split of the RFID tag label is used as the paste-killing portion. The RFID tag label continuous body according to claim 3, wherein a part of the RFID tag label is set so as to be in a state of entering the partial glue portion.