JP2007102513A - Non-contact ic tag label - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the pasting property onto a curved surface by performing flexibility granting processing to a magnetic material sheet in a metal body pasting non-contact IC tag label which uses the magnetic material sheet. <P>SOLUTION: In the non-contact IC tag label 1, an IC chip 3 with a storage function capable of reading information in a non-contact state and an antenna coil 2 for transmitting and receiving electromagnetic wave are electrically connected on an inlet base 11. The non-contact IC tag label 1 has the magnetic material sheet 10 between an adhesive agent layer 6 to be pasted to an object to be pasted and the inlet base 11, and the magnetic material sheet 10 has flexibility granting processing by a throughput hole of either a needle hole or a half-cut hole on the one hand or a perforation or half-cut line on the other so that the magnetic material sheet bends flexibly along the surface of the object to be pasted. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention relates to a non-contact IC tag label. Specifically, it is a non-contact IC tag label having a structure that suppresses communication inhibition due to metal, but has a characteristic that the magnetic material sheet used for suppressing communication inhibition has a flexibility imparting process.
The non-contact IC tag label of the present invention is also used as a normal non-contact IC tag, but particularly when it is attached to an object made of a metal material, a metal container or the like, it suppresses communication hindrance and has a curved surface. It has the characteristics that it is easy to stick to the body and is difficult to peel off naturally.
Therefore, the technical field of the present invention relates to the manufacture and use of non-contact IC tag labels, and the main fields of use are the fields of transportation, distribution, sales management, factory process management, product delivery and baggage handling. As a tag, a label.

Non-contact IC tags record and hold information and can exchange information by communicating with external devices in a non-contact manner, so they are widely used as a recognition medium in transportation and logistics, or for various purposes such as product quality control and inventory management. It has come to be.
However, when a non-contact IC tag is attached to a conductive member such as an object made of a metal material or a metal container, the AC magnetic field generated by the electromagnetic wave for non-contact IC tag transmission / reception is placed in the metal behind the object. Eddy current is generated. This eddy current often generates a magnetic flux in a direction that cancels the magnetic flux for transmission and reception, which attenuates the magnetic flux for transmission and reception and often makes communication difficult.
Therefore, when a non-contact IC tag is attached to a member made of a conductive material such as metal, a magnetically permeable magnetic sheet is disposed between the non-contact IC tag and the conductive member, and a transmission / reception magnetic flux is passed therethrough. There is known a method for suppressing generation of eddy current caused by magnetic flux entering a metal. The non-contact IC tag label of the present invention also uses this principle.

  As a prior art of a non-contact IC tag label for the purpose of suppressing communication inhibition by metal, there are Patent Documents 1 to 3, and the like. Patent Document 1 describes the use of a magnetic absorption plate, but does not describe the sheet bending process. Patent Document 2 differs from the present application in terms of a structure in which a magnetic core member is housed in an antenna coil. Patent Document 3 describes the use of a magnetic sheet for a non-contact IC tag label to be attached to a metal or the like, but does not describe the flexibility imparting process.

  Conventionally, magnetic material sheets and magnetic sheets have been used for non-contact IC tag labels in the past, but as a problem with these sheets, they were stuck to adherends, particularly to adherends having curved surfaces, without flexibility. In this case, it has been pointed out that the label starts to float from the end of the label and eventually the whole label peels off. Therefore, the present invention intends to perform needle hole processing, perforation processing, or the like on the sheet for the purpose of imparting flexibility to the magnetic material sheet to make it flexible. Such a prior patent document cannot be found in particular, but there is Patent Document 4 in which a flexibility is given to a film carrier substrate.

JP 2000-113142 A JP 2001-56847 A JP 2003-85501 A JP-A-63-58848

An example of using a magnetic sheet for the purpose of suppressing communication inhibition when a non-contact IC tag label is attached to a metal body already exists as described above. However, since the magnetic sheet is a relatively thick hard material in which a magnetic material is dispersed in a rubber material or a polymer, it is not flexible and is difficult to be processed for labeling. Even if it is worn, if the product has a curved surface, it is difficult to stick along the curved surface, and even if it is dared to stick, there is a problem in that the edge subsequently rises and peels off naturally.
The present invention has been made in consideration of the above points, and has been researched to provide a non-contact IC tag label that can be freely attached regardless of the material or curved surface of the product or the like to which the non-contact IC tag label is attached. It has been completed.

  A first aspect of the present invention is a non-contact IC tag label having a structure in which an IC chip with a storage function capable of reading information in a non-contact manner and an antenna coil for transmitting and receiving electromagnetic waves are electrically connected on an inlet base. The non-contact IC tag label has a magnetic material sheet between the adhesive layer to be adhered to the adherend and the inlet base, and the magnetic material sheet is flexibly bent along the adherend surface. A non-contact IC tag label, which is provided with a flexibility by drilling a hole or a half-cut hole.

  The second of the gist of the present invention is a non-contact IC tag label having a structure in which an IC chip with a memory function capable of reading information in a non-contact manner and an antenna coil for transmitting and receiving electromagnetic waves are electrically connected on an inlet base. The non-contact IC tag label has a magnetic material sheet between the pressure-sensitive adhesive layer to be attached to the adherend and the inlet base, and the magnetic material sheet is flexibly bent along the adherend surface. A non-contact IC tag label, which is subjected to flexibility imparting processing by forming a line of sight or a half cut line.

In the above, the magnetic material sheet may be a material in which a magnetically permeable material is dispersed in a polymer, or may be a material obtained by coating a plastic sheet with a permeable magnetic material.
In the case of the non-contact IC tag label according to claim 2, the perforation line or the half cut line may be formed so that two parallel line groups intersect. In this case, a further softening effect can be obtained.

Since the non-contact IC tag label of the present invention has a magnetic material sheet between the inlet base and the adherend, even if it is attached to an object made of a metal material or a metal container, it is caused by a demagnetizing field caused by the metal. The influence of communication obstruction can be reduced.
Since the magnetic material sheet is subjected to a flexibility imparting process, the non-contact IC tag label is flexible and can be easily attached to an adherend having a curved surface. Furthermore, there is little possibility that the label will float and peel off spontaneously after application.

The present invention will be described below with reference to the drawings.
FIG. 1 is a schematic plan view showing an example of the non-contact IC tag label of the present invention, FIG. 2 is a schematic cross-sectional structure of the non-contact IC tag label, and FIG. FIG. 4 is a plan view for explaining the influence of the metal body received by the non-contact IC tag.

The non-contact IC tag label 1 of the present invention has a planar antenna coil 2 formed on an inlet base 11 as shown in FIG. 1 and IC chips 3 are mounted on both end portions 2 a and 2 b of the antenna coil 2. Since the mounting is performed by an anisotropic conductive adhesive sheet or the like, electrical connection is ensured.
The antenna coil 2 is designed to transmit and receive electromagnetic wave signals having a frequency of 13.56 MHz. The IC chip 3 is an integrated circuit having a processing function, a storage function, and an input / output function, and can store information in the storage unit. The processing function unit stores or stores information in the storage unit. Information can be read from the section. The IC chip 3 stores information in a storage unit in response to a command represented by an electromagnetic wave signal received by the antenna coil 2, or reads information stored in the storage unit, and transmits a signal representing the information to the antenna coil. Give to 2.

The conducting member 7 is a member for guiding one end of the antenna coil to the end 2a of the antenna coil via the lower surface of the inlet base 11 in order to prevent a short circuit of the coil. The above planar configuration is the same as that of a normal non-contact IC tag label, and there is no particular difference.
The inlet base 11 is a film in which the antenna coil 2 is formed on the base film and the IC chip 3 is mounted as described above. Generally, the inlet base 11 may be simply referred to as “base film” or “antenna sheet”. .

  As shown in FIG. 2, the schematic cross-sectional structure of the non-contact IC tag label 1 of the present invention is obtained by laminating a surface base material 4 made of paper or plastic on the surface of the antenna coil 2 of the inlet base 11, and the antenna coil 2 of the inlet base 11. On the opposite side, a magnetic material sheet 10 made of a highly permeable magnetic material is laminated, and a pressure-sensitive adhesive layer 6 and a release paper 8 for adhering to an adherend are laminated. As the magnetic material sheet 10, a material obtained by dispersing a magnetically permeable material in a polymer, a material obtained by coating a plastic sheet with a permeable magnetic material, or the like is used. However, the material is not particularly limited as long as it has an effect of suppressing the generation of a demagnetizing field by reducing the magnetic flux loop flowing through the metal body as the adherend, and can bend and impart.

  The release paper 8 is a material having a releasable surface generally called a separate paper and is a material for protecting the pressure-sensitive adhesive layer 6. When sticking on the adherend, the release paper 8 is removed and sticking is performed with the adhesive layer 6. In many cases, the pressure-sensitive adhesive layer 6 is applied to the release paper 8 in advance, and this is adhered to the magnetic material sheet 10 of the IC tag label 1.

  Adhesive layers 9a and 9b are illustrated between the surface base material 4 and the inlet base 11, and between the inlet base 11 and the magnetic material sheet 10, but are not limited to adhesives and may be adhesives. Alternatively, it may be bonded with melted polyethylene or the like, or may be formed by melt coating (extrusion coating) of a resin such as polyethylene and simply having a close contact structure, regardless of the bonding means.

  The above shows a typical form of the non-contact IC tag label 1, and various modifications can be arbitrarily adopted. For example, two layers of the surface base material 4 may be used to enhance protection, or the surface base material 4 may be omitted. Further, the magnetic material sheet 10 does not have to be disposed on the entire lower surface of the inlet base 11 and may be partially provided on the lower surface of the antenna coil as long as it has the effect of suppressing the generation of the demagnetizing field. .

The non-contact IC tag label 1 of the present invention is characterized in that when the label is attached to an adherend, the magnetic material sheet 10 is flexibly bent so as to bend flexibly along the surface (particularly a curved surface) of the adherend. There is a processing. Although it is considered that the flexibility imparting process can be performed by various methods, in the present invention, the magnetic material sheet 10 is mechanically perforated or half-cut by a method.
The 1st form is performing a flexibility provision process to the magnetic material sheet 10 by piercing | punching a needle hole or a half cut hole. Moreover, the 2nd form is forming a perforation line or a half cut line in the magnetic material sheet 10, and performing a flexibility provision process.

  There are various methods for mechanically performing drilling and half-cut processing, but a rotary die apparatus is usually used. When making the die die blade the most durable die-cut cylinder, use a strong and wear-resistant material such as carbon steel or special steel for blades (for example, high-speed steel) on the surface. Formed by embossing the mold blade. The mold blade is hardened to the surface or an appropriate depth and polished so as to have an appropriate cutting angle. However, the manufacturing cost of this cylinder is expensive, and it is difficult to remanufacture it every time it is worn out.

  As a method for easily forming perforation lines and half-cut lines, there is a method of incorporating a disk-shaped die blade into a die-cut cylinder. A disc-shaped blade plate made of stainless steel or the like having a constant thickness is used with a sharp tip. Only the cutting edge is incorporated so that it protrudes slightly from the die-cut cylinder. In order to make parallel lines of perforated lines, they are incorporated in a plurality of rows. As the roller (anvil roller) facing the die-cut cylinder, a steel cylinder is often used because of durability requirements. As a simpler method, there is a case in which a perforated blade type is formed in a tape shape on a metal material of a blade plate and adhered to a die-cut cylinder surface for use. However, this method is suitable for soft materials such as paper, and the durability is insufficient with a hard magnetic material sheet.

  FIG. 3 is a plan view of a magnetic material sheet that has been subjected to a flexibility imparting process. FIG. 3 (A) shows an example in which a needle hole is drilled, and the perforations p are relatively scattered in the form of dots by a sewing needle having a diameter of about 0.1 mm to 0.5 mm, a sharp punching blade that penetrates the sheet, and the like. It is densely formed. The perforations p are not limited to a circular shape, and may be provided with a cut by a die blade. In the case of a mold blade, the maximum cutting length of one perforation p occurs on the blade plate side of the cutting blade. In this case, the maximum cutting length is suitably about 0.1 mm to 2.0 mm. In the case of a half cut hole or a hoof cut line, the cutting edge is prepared so as not to penetrate the sheet in consideration of the thickness of the sheet to be processed.

FIG. 3B is an example in which a half cut hole q is formed, and no opening is formed on the side surface opposite to the illustrated side. The maximum cutting length of the half-cut hole q is suitably about 0.1 mm to 3.0 mm. The half cut holes q are also formed relatively densely in the form of dots. In this case as well, it is appropriate to use a die-cut roll when processing continuously. The formation surface of the half-cut hole q may be a surface to which the adhesive layer 6 is applied later when used for a non-contact IC tag label, or the opposite surface.
In the example of FIGS. 3A and 3B, even if it is formed relatively densely in the form of dots, the sheet is supported if it is perforated so tightly that it destroys the structure of the magnetic material sheet. The function as a body is lost. The standard of the number of perforations is about 0.5 to 20 holes / cm ² , more preferably about 1 to 10 holes / cm ² . Further, it is necessary to uniformly perforate the entire magnetic material sheet 10.

  FIG. 3C shows an example in which the perforation line m is formed, and a perforation line that penetrates the sheet is formed by a sharp die blade or the like. The case of FIG. 3C is an example in which the perforation line m is formed by a parallel line group. It is appropriate that the length of the perforated line cut part is about 1 mm to 5 mm, the distance between the cut parts is about 0.5 mm to 4 mm, and the distance between adjacent perforated lines is about 3 mm to 20 mm. Even if it is a half cut line which does not penetrate the magnetic material sheet 10 as well as the perforation line, the flexibility imparting effect can be obtained.

FIG. 3D shows an example in which the perforation line m is formed orthogonally. In this case, the length of the cut portion of the perforation line m and the interval between the cut portions are the same as those in FIG. An appropriate distance between adjacent perforation lines is about 5 mm to 20 mm. In the case of FIG. 3D, the perforation line is formed by two parallel line groups orthogonal to each other, but the crossing angle of the parallel line groups may be adjusted within a range of 45 to 90 degrees. Moreover, a half cut line may be used similarly to the above.
Even when the magnetic material sheet 10 is a magnetic material coated sheet, the surface on which the perforation line or the half cut line is formed may be the surface on which the adhesive layer 6 is applied or the opposite surface. .

Various types of magnetic material sheets are commercially available, and materials that can be processed such as perforation and perforation lines are sheets obtained by dispersing a magnetically permeable material in a polymer, and magnetic material coated sheets.
It is considered that a sintered material such as a ferritic material and a metal is difficult to perforate and does not cause bending even when perforated. As the polymer dispersion sheet material, magnetically permeable materials such as sendust, ferrite, carbonyl iron, and iron-permalloy are made of rubber polymers such as nitrile rubber, chloroprene rubber, silicone rubber, polyurethane rubber, and cyclized rubber, chlorosulfonated polyethylene, epoxy Many are dispersed in polymers such as resin and chlorinated polyethylene.
Examples of such commercially available magnetic sheets include product series such as “IRL” and “IRJ” manufactured by TDK Corporation, and “RFID magnetic sheet” manufactured by Nitta Corporation.
Further, although not generally used, a material obtained by coating a permeable magnetic material on a polyethylene terephthalate (PET) sheet or the like may be used.

  The thickness of the magnetic material sheet 10 can be used in the range of 50 μm to 3000 μm (3 mm). However, it is preferably 50 μm to 1000 μm. This is because a material in this range provides flexibility as a label, flexibility imparting processing and subsequent processing suitability, and good adhesion. When the total thickness of the magnetic material sheet 10 is less than 50 μm, it is considered that the flexibility imparting process is not required. Moreover, when it exceeds 3000 micrometers, it is because the thickness of the non-contact IC tag label 1 will become too thick, and a flexibility provision process will also become difficult.

In general, when the antenna coil 2 of the non-contact IC tag receives a magnetic flux loop from the reader / writer, when there is no metal body in the vicinity or when it is attached to the non-metal body N, the antenna as shown in FIG. A magnetic flux loop R is generated around the line 2s. On the other hand, when the metal body K is near the antenna coil 2, an eddy current is generated in the metal body K as shown in FIG. 4B, and the demagnetizing field generated by the generated eddy current cancels the magnetic flux loop. (In FIG. 4B, the broken line indicates the disappeared magnetic flux loop H). As a result, only a slight magnetic flux loop R remains only in the portion around the antenna wire 2s, and the communication distance is remarkably shortened.
On the other hand, as shown in FIG. 4C, when a magnetic material (magnetic material sheet or magnetic material coating sheet) Z is inserted between the metal body K and the antenna wire 2s, the magnetic material Z has high magnetic permeability. Therefore, since the magnetic flux is concentrated on the magnetic material Z and does not flow through the metal body K, a demagnetizing field is not generated and the magnetic flux is not lost, so that the magnetic flux loop R is formed and the communication distance is improved.
In the non-contact IC tag label 1 of the present invention, the magnetic material sheet 10 is inserted between the antenna coil 2 and the metal body that is the adherend, and thus the above-described effect is produced.

Generally, in a proximity IC card with an operating range of 70 cm or less, the minimum operating magnetic field strength (H _min ) is 150 mA / m rms, the maximum operating magnetic field strength (H _max ) is 5 A / m rms, and H _min and H _max (JISX6323-2). This standard is considered to be applicable to non-contact IC tags as well.
However, in general, when the magnetic material sheet 10 is used for the non-contact IC tag label 1, even if the communication distance when it is attached to a metal surface is increased, the communication distance when it is attached to a non-metal surface does not use a magnetic material. It becomes shorter than a general non-contact IC tag label, and the minimum operating magnetic field strength (H _min ) becomes large.

Therefore, when the adherend is a metal surface, the minimum operating magnetic field strength (H _min ) of the non-contact IC tag label 1 is about 1.0 A / m to 3.5 A / m at a communication frequency of 13.56 MHz. When the adherend is a non-metallic surface, the minimum operating magnetic field strength (H _min ) is in the range of about 0.5 A / m to 3.0 A / m at the same communication frequency. It is recognized that it is preferable to ensure stable communication on both a metal surface and a non-metal surface.

  The metal surface is a very thin metal layer. Since a metal layer deposited on a plastic substrate with a thickness of several nanometers also blocks non-contact communication, a metal surface with a thickness greater than this level is also targeted. On the other hand, the non-metallic surface refers to the surface of a composition made of a material other than metal. Even if there is a metal on the lower surface of the non-metallic body, it is affected, so it is necessary that there is no metal within 10 mm from the surface of the antenna coil 2 when the non-contact IC tag label 1 is attached.

<Embodiments related to other materials>
(1) Substrate for inlet base A wide variety of plastic films can be used, and the following single films or composite films thereof can be used.
Polyethylene terephthalate (PET), PET-G (terephthalic acid-cyclohexanedimethanol-ethylene glycol copolymer), polyvinyl chloride, vinyl chloride-vinyl acetate copolymer, polycarbonate, polyamide, polyimide, cellulose diacetate, cellulose triacetate, Polystyrene, ABS, polyacrylate, polypropylene, polyethylene, polyurethane, and the like.

(2) Surface substrate A wide variety of plastic films and paper substrates can be used. As the plastic film, those listed above can be used, and as the paper substrate, high-quality paper, coated paper, craft paper, glassine paper, synthetic paper, latex, melamine-impregnated paper, or the like can be used. When performing printer printing on the surface, paper substrates such as fine paper and coated paper are particularly preferable.

(3) Adhesive, pressure-sensitive adhesive In the present specification, the term adhesive refers to various types such as a solvent type, a polymerization type, an ultraviolet curable type, an emulsion type, and a heat-melt type. Shall be included. It may be in the form of a sheet instead of being liquid. In either case, the purpose can be achieved by bonding the two materials. Further, in the present specification, the term “adhesive” refers to an adhesive that keeps an intermediate tack state indefinitely without a significant increase in viscosity.
Various resin compositions such as natural rubber, nitrile rubber, epoxy resin, vinyl acetate emulsion, acrylic, acrylate copolymer, polyvinyl alcohol, phenol resin, etc. Material can be used.

Next, the manufacturing method of the non-contact IC tag label of this invention is demonstrated.
<Flexibility imparting process of magnetic material sheet>
Since the magnetic material sheet is composed of a relatively large elastic sheet material, a cutting blade is mounted on a rotary die for drilling and perforation processing, and the magnetic material sheet is placed between the anvil roller on the opposite side. It is appropriate to insert and insert a pressure between the rotating rollers. In particular, when the magnetic material sheet has a thickness of about 1 mm or more, a considerable strong pressure is required. The blade plate of the cutting blade has a thickness of 1 mm or less, usually 0.8 mm or less.
As described above, in the case of a perforation line or a half-cut line, a large number of mold blades are arranged in a row at a predetermined interval in parallel with the circumferential direction of the roller and used as a parallel line group. In general, since it is difficult to form a horizontal perforation in a direction perpendicular to the rotation direction of the roller, when forming a perforation line perpendicular to the magnetic material sheet 10, the vertical perforation is once put in the column. Usually, the direction of the sheet is rotated 90 degrees and the perforation is made again.
When the cutting blade is easily damaged by the magnetic material, nitriding treatment or carburizing treatment may be performed, and the vicinity of the tip of the cutting blade may be covered with a diamond-like carbon layer.

<Manufacture of non-contact IC tag labels>
Since the magnetic material sheet 10 has a considerable thickness in the manufacture of the non-contact IC tag label 1, the magnetic material sheet 10 is attached to the multi-faced body of the inlet base 11 in the case of mass production. It is considered appropriate that the surface base material 4, the adhesive sheet, etc. are temporarily stacked and then manufactured in the press laminating process. However, when manufacturing a small amount easily, it can be as follows.

  First, the antenna coil 2 is manufactured on a base material to be the inlet base 11 by a process such as photoetching or printing. Next, the IC chip 3 is attached to both end portions 2a and 2b of the antenna coil 2 by an anisotropic conductive adhesive sheet or the like to make electrical connection. The surface base 4 is laminated on the antenna coil 2 surface side of the inlet base 11, the magnetic material sheet 10 is adhered to the surface of the inlet base 11 on the adherend side, and then the magnetic material sheet 10 is adhered to the release paper 8. The agent layer 6 is processed and pasted.

Hereinafter, actual embodiments will be described using examples.
As the magnetic material sheet 10, a magnetic material sheet having a thickness of 1.0 mm (manufactured by TDK Corporation (IRL02)) is used, and a perforation line penetrating the sheet is inserted so as to intersect the vertical and horizontal directions of the sheet to impart flexibility. In the bending property imparting process, a rotary die cutter device was used, and disk-shaped cutting blades for perforation lines were incorporated into columns at intervals of 10 mm in the die cut cylinder of the device. The length of the cut portion was 3 mm, and the distance between the cut portions was 2 mm First, after the vertical perforation of the magnetic sheet 10 was taken out, the direction of the magnetic sheet 10 was rotated 90 degrees again. Then, the perforation in the horizontal direction was performed through the same die-cut cylinder.
After the bending process, the magnetic material sheet 10 was cut into the same size (54 mm × 86 mm) as the inlet base 11 of the non-contact IC tag label 1.

  As a base material for the inlet base 11 of the non-contact IC tag label 1, a material obtained by dry laminating a 25 μm thick aluminum foil on a transparent biaxially stretched PET film having a thickness of 38 μm, and applying a photosensitive resist thereto, an antenna coil A photomask having a pattern was exposed and exposed. After exposure and development, photoetching was performed to complete the inlet base 11 having the antenna coil 2 as shown in FIG. The antenna coil 2 has an outer shape of approximately 45 mm × 76 mm.

The IC chip 3 having a planar size of 1.0 mm square and a thickness of 150 μm was mounted on both ends 2a and 2b of the inlet base 11 with heat pressure applied in a face-down state. Since an anisotropic conductive adhesive sheet is used for mounting, electrical connection is ensured.
Next, after the surface base material (coated paper) 4 having a thickness of 40 μm was adhered to the antenna coil 2 surface side of the inlet base 11 via the adhesive layer 9a on the antenna coil 2 surface (see FIG. 2), it was prepared in advance. The magnetic material sheet 10 is laminated on the surface of the inlet base 11 on the adherend side via an adhesive layer 9b, and then an adhesive (acrylic ester copolymer system) is adhered to the surface side of the magnetic material sheet 10 with a thickness of 16 μm. The non-contact IC tag label 1 was completed by sticking the release paper 8 applied as the agent layer 6.

As the magnetic material sheet 10, a magnetic material sheet made of a ferrite material on a polyethylene terephthalate (PET) sheet having a thickness of 100 μm and coated so that the thickness after drying becomes 300 μm (prototype). It was used. In the same manner as in Example 1, the magnetic material coated sheet 10 was subjected to a flexibility imparting process by inserting a perforation line penetrating the sheet. However, the perforation line was formed only in the longitudinal direction of the magnetic material sheet 10.
That is, the same rotary die cutter apparatus as in Example 1 was used, and the same disk-shaped cutting blade for perforation was used, but the processing with the die cut cylinder was performed only once. Therefore, the length of the cut portion of the perforation line is 3 mm, and the interval between the cut portions is 2 mm.
After the flexibility imparting process, the magnetic material coated sheet 10 was cut into the same size (54 mm × 86 mm) as the inlet base 11 of the non-contact IC tag label 1.

  As a base material for the inlet base 11 of the non-contact IC tag label 1, a material obtained by dry laminating a 25 μm thick aluminum foil on a transparent biaxially stretched PET film having a thickness of 38 μm is used. And the same IC chip 3 was mounted. Subsequent processing was also performed under the same conditions as in Example 1, but the pressure-sensitive adhesive layer 6 was placed on the PET sheet side of the magnetic material coating sheet 10.

Non-contact IC tag label 1 of Example 1 and Example 2 and a conventional product using a magnetic material sheet that is manufactured under the same conditions using the same material as in Example 1 (Comparison) The non-contact IC tag label 1j in Example) was tested for use under the same conditions.
As a result, the non-contact IC tag labels 1 of Example 1 and Example 2 can be easily attached even when they are attached to the side of a curved metal container (a tin can with a diameter of 90 mm), and one month has elapsed at room temperature. There was no spontaneous peeling afterwards. On the other hand, when the non-contact IC tag label 1j of the conventional product (comparative example) was attached to the side surface of the same metal container (a tin can with a diameter of 90 mm), a part of the non-contact IC tag label 1j was peeled off in a few minutes at room temperature.
In the case of deposition on a non-metal surface, the minimum operating magnetic field strength (H _min ) at a frequency of 13.56 MHz is in the range of 0.5 A / m to 3.0 A / m. In the communication frequency of 13.56 MHz, it is recognized that the minimum operating magnetic field strength (H _min ) of the non-contact IC tag label 1 is in the range of about 1.0 A / m to 3.5 A / m. It was confirmed that both the non-contact IC tag label 1 of Example 2 and the conventional non-contact IC tag label 1j (comparative example) can communicate with the reader / writer without any trouble.

It is a schematic plan view which shows the example of the non-contact IC tag label of this invention. It is a figure which shows schematic sectional structure of a non-contact IC tag label. It is a top view of the magnetic material sheet which performed the flexibility provision process. It is a figure explaining the influence of the metal body which a non-contact IC tag receives.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Non-contact IC tag label 2 Antenna coil 3 IC chip 4 Surface base material 6 Adhesive layer 7 Conductive member 8 Release paper 9a, 9b Adhesive layer 10 Magnetic material sheet, magnetic material coating sheet 11 Inlet base

Claims (5)

A non-contact IC tag label having a structure in which an IC chip with a memory function capable of reading information in a non-contact manner and an antenna coil for transmitting and receiving electromagnetic waves are electrically connected on an inlet base. The non-contact IC tag label is an adherend. There is a magnetic material sheet between the pressure-sensitive adhesive layer and the inlet base that is attached to the substrate, and the magnetic material sheet is bent by drilling a needle hole or a half-cut hole so that it is flexibly bent along the adherend surface. A non-contact IC tag label characterized by being subjected to a property imparting process. A non-contact IC tag label having a structure in which an IC chip with a memory function capable of reading information in a non-contact manner and an antenna coil for transmitting and receiving electromagnetic waves are electrically connected on an inlet base. The non-contact IC tag label is an adherend. It has a magnetic material sheet between the pressure-sensitive adhesive layer to be attached to the inlet base and the inlet base, and the magnetic material sheet is bent by forming a perforation line or a half cut line so as to be bent flexibly along the surface of the adherend. A non-contact IC tag label characterized by being subjected to a property imparting process. 3. The non-contact IC tag label according to claim 1, wherein the magnetic material sheet is a material in which a magnetically permeable material is dispersed in a polymer. The non-contact IC tag label according to claim 1 or 2, wherein the magnetic material sheet is a material obtained by coating a plastic sheet with a permeable magnetic material. The non-contact IC tag label according to claim 2, wherein the perforation line or the half cut line is formed in a state where two parallel line groups intersect.

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