JP2009000908A - Anticounterfeit medium and anticounterfeit sheet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an anticounterfeit medium and an anticounterfeit sheet that make manufacturing of a forged article difficult and that facilitate efficient distinction of authenticity. <P>SOLUTION: The anticounterfeit medium (20) includes: a base material (21); a volume hologram layer (22) which is provided on one side of the base material (21) and which records, in the layer thickness direction, interference fringes caused by interference of light as fringes of different refractive index; and a ferromagnetic material layer (24) which is provided on the side opposite from the base material of the volume hologram layer (22) and which is formed in a pattern using a ferromagnetic material. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an anti-counterfeit medium and an anti-counterfeit sheet provided with a volume hologram layer and a ferromagnetic layer.

Gold vouchers such as gift certificates and gift vouchers require a counterfeit prevention function based on their value, and various measures are taken on a base material (cash voucher) (for example, see Patent Document 1).
Patent Document 1 discloses a cash voucher provided with a hologram layer on the surface so that authentication can be easily performed. Such gold vouchers use relief type holograms in which interference fringes are recorded by providing fine irregularities on the surface as the hologram layer. However, the spread of hologram technology in recent years and the advancement of counterfeit technology As a result, the relief hologram itself is forged, and the functions of the original forgery determination and anti-counterfeiting may not be effectively performed.
Japanese Patent Application Laid-Open No. 07-285286

  An object of the present invention is to provide an anti-counterfeit medium and an anti-counterfeit sheet that make it difficult to manufacture a counterfeit product and that can easily and efficiently determine authenticity.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated in a parenthesis, it is not limited to this.
According to the first aspect of the present invention, a base material (21) and one surface side of the base material (21) are provided, and interference fringes caused by light interference are recorded in the thickness direction of the layer as fringes having different refractive indexes. The volume hologram layer (22), and the ferromagnetic material layer (24) formed of a ferromagnetic material provided on the surface of the volume hologram layer (22) opposite to the base (21). And a forgery prevention medium (20).
The invention of claim 2 is the anti-counterfeit medium (20) of claim 1, wherein the ferromagnetic material layer (24) is formed of an amorphous ferromagnetic material having specific magnetization characteristics. Forgery prevention medium (20).
According to a third aspect of the present invention, in the anti-counterfeit medium (20) according to the first or second aspect, a colored layer (20) is provided between the ferromagnetic material layer (24) and the volume hologram layer (22). 23) a forgery prevention medium (20).
The invention of claim 4 is the anti-counterfeit medium (20) according to claim 3, wherein the colored layer (23) is formed in a pattern. .
The invention according to claim 5 is the forgery prevention medium (20) according to claim 3 or 4, wherein the colored layer (23) is formed of black ink. 20).
The invention according to claim 6 is the anti-counterfeit medium (20) according to any one of claims 1 to 5, wherein the volume hologram layer (22) of the ferromagnetic material layer (24) is An anti-counterfeit medium (20) characterized by comprising an adhesive layer (25) on the opposite surface side.
The invention of claim 7 is the forgery prevention medium (20-2) of claim 6, further comprising a release layer (26) between the substrate (21) and the volume hologram layer (22). The forgery prevention medium (20-2) characterized by the above.
The invention of claim 8 is the anti-counterfeit medium (20-2) according to claim 7, wherein the anti-counterfeit medium (20-2) is peeled off from the substrate (21) by the release layer (26). The anti-counterfeit medium (20-2) is characterized in that it is stuck to the sticking object (11) with the adhesive layer (27).

  The invention of claim 9 is formed in a state in which the anti-counterfeit medium (20-4) according to any one of claims 1 to 5 and the anti-counterfeit medium (20-4) are inserted. A forgery prevention sheet (10-4) comprising a sheet-like base material (11).

As described above, the present invention has the following effects.
(1) Since the forgery prevention medium is provided with a volume hologram layer and a ferromagnetic material layer in this order on one surface side of the substrate, confirmation by visual recognition of the volume hologram layer and the magnetic property of the ferromagnetic material layer It is possible to determine the authenticity of the anti-counterfeit medium by confirming with information, and it is possible to make it difficult to counterfeit the anti-counterfeit medium by adopting a volume hologram layer that is difficult to duplicate interference fringes.
(2) Since the ferromagnetic material layer is formed of an amorphous ferromagnetic material, by utilizing the magnetic properties (large Barkhausen effect) unique to amorphous ferromagnetic materials that are different from the magnetic properties exhibited by general magnetic materials In addition, it is possible to easily determine the authenticity of the anti-counterfeit medium and make it difficult to counterfeit the ferromagnetic material layer.

(3) Since the anti-counterfeit medium includes a colored layer between the ferromagnetic material layer and the volume hologram layer, the presence of the ferromagnetic material layer may be concealed by the colored layer from the appearance of the anti-counterfeit medium. The security function of the forgery prevention medium can be improved.
(4) Since the colored layer is formed in a pattern, the pattern printing can be visually recognized through the volume hologram layer, and the design of the forged printing medium can be improved.
(5) Since the colored layer is formed of black ink, the hologram image of the volume hologram layer can be made clear.
(6) Since the anti-counterfeit medium is provided with an adhesive layer on the surface opposite to the volume hologram layer of the ferromagnetic material layer, the anti-counterfeit medium can be used as a label and is attached to a product or the like. Thus, the counterfeit product can be identified.

(7) Since the anti-counterfeit medium includes a release layer between the base material and the volume hologram layer, the anti-counterfeit medium peeled from the base material through the release layer can be used in the form of a transfer foil. It can be affixed to a voucher in a non-peelable manner, enabling discrimination of merchandise and counterfeit goods, and also preventing fraud due to replacement.
(8) Since the anti-counterfeit sheet is formed in a state in which the anti-counterfeit medium is inserted into the sheet-like base material, it is possible to prevent unauthorized replacement of the anti-counterfeit medium from the sheet-like base material.

  An object of the present invention is to provide a forgery prevention medium and a forgery prevention sheet that make it difficult to produce a forgery product and that can easily and efficiently identify authenticity. This is realized by sequentially providing on one side.

(First embodiment)
Hereinafter, the present invention will be described in more detail with reference to the drawings and the like.
FIG. 1 is a schematic diagram showing an anti-counterfeit label affixed to a gift certificate as a first embodiment of the anti-counterfeit medium according to the present invention. FIG. 1 (a) is a plan view, and FIG. Sectional drawing of the AA cross section of (a) is shown. FIG. 2 is a diagram showing BH magnetization characteristic curves of an amorphous ferromagnetic material and a general magnetic material. Here, in order to clarify the explanation, the upper side of FIG. 1B is the front surface and the lower side is the back surface.
As shown in FIG. 1, the gift certificate 10 is a cash voucher used at a department store or the like, and includes a sheet-like base material 11 and a forgery prevention label 20.
The sheet-like base material 11 is a high-quality rectangular paper serving as a mount for the gift certificate 10, and as shown in FIG. 1A, the name of the gift certificate (department gift certificate) and the amount (¥ 1, 1) 000) is printed.

The forgery prevention label 20 is a label formed in the shape of a rectangular band affixed to the surface of the gift certificate 10 in order to prevent forgery of the gift certificate 10 and determine the authenticity. The dimension of the short side portion of the material 11 is used. As shown in FIG. 1B, the forgery prevention label 20 has a volume hologram layer 22, a colored layer 23, a ferromagnetic material layer 24, and an adhesive layer 25 laminated in this order on the back surface of a base material 21. 25 is affixed to the surface of the sheet-like substrate 11.
The base material 21 is a sheet made of a transparent resin (for example, PET: Polyethylene Terephthalate) having a thickness of 50 μm, which is the basis of the forgery prevention label 20. Moreover, since the base material 21 is located on the surface of the anti-counterfeit label 20, it also serves as a protective layer for protecting the volume hologram layer 22.

  The volume hologram layer 22 is a hologram layer having a thickness of 10 μm formed from a resin composition having at least one photopolymerizable compound and a photopolymerization initiator, and is also called a Lippmann hologram. The volume hologram layer 22 records the wavefront of the object light on the resin composition as a fringe interference by causing the object light having the same wavelength and the reference light to interfere with each other. Causes a diffraction phenomenon to reproduce the same wavefront as the object light. For example, when a specific design or the like is recorded on the resin composition as interference fringes, the specific design can be visually recognized from the surface of the forgery prevention label 20 when light having the same conditions as the reference light is applied. it can.

Further, unlike the relief hologram, the volume hologram layer 22 three-dimensionally records interference fringes caused by light interference as fringes having different refractive indexes in the layer thickness direction. The volume hologram layer 22 enables real three-dimensional image expression and full-color image expression by the three primary colors of red, blue, and green and their superposition, and has a different visual effect than the relief hologram. Make discrimination easier. In this embodiment, as shown in FIG. 1A, a three-dimensional star shape 22a (hologram image) is recorded as object light. As described above, the volume hologram layer 22 is difficult to grasp from the outside the characteristics of the interference fringes provided so that a complicated three-dimensional shape can be expressed. Becomes difficult.
Here, the photopolymerizable compound used for the volume hologram layer 22 is, for example, a photo radical polymerizable compound or a photo cationic polymerizable compound, and the photo polymerization initiator is, for example, a photo radical polymerization initiator or a photo A cationic polymerization initiator or the like is used. The volume hologram layer 22 of the present application also includes a volume type light diffraction structure other than the hologram obtained by the holography method.

The colored layer 23 is a printed layer having a thickness of 2 μm obtained by printing the back surface of the volume hologram layer 22 with a specific color ink. The colored layer 23 is printed in a striped pattern. The striped pattern can be seen from the surface of the anti-counterfeit label 20 through the base material 21 and the volume hologram layer 22. The design is improved.
Here, the hologram image of the volume hologram layer 22 can be visually recognized as shown in FIG. 1 (a) even if the colored layer 23 is provided on the back surface of the volume hologram layer 22. When the colored layer 23 is provided on the back surface of the relief type hologram layer that has been used, the hologram image cannot be viewed at the portion where the relief type hologram layer and the colored layer overlap. This is because the refractive index of the relief-type hologram layer and the colored layer are close to each other, so that the printing ink of the colored layer 23 enters the fine unevenness provided in the relief-type hologram layer, so that the light reflected by the unevenness is reflected. This is because it will disappear.

The ferromagnetic material layer 24 is a thin film layer having a thickness of 100 nm formed from an amorphous ferromagnetic material mainly composed of cobalt Co, iron Fe, and nickel Ni, and is formed by vacuum deposition such as vapor deposition, sputtering, and ion plating. It is formed on the back surface of the colored layer 23 by the method.
The amorphous ferromagnetic material of the ferromagnetic material layer 24 is a magnetic material having such a property that the magnetic permeability and the saturation magnetization characteristic are changed by heating, cutting, etc. Further, as shown in FIG. Has magnetic properties. 2A and 2B respectively show BH curves of an amorphous ferromagnetic material and a general magnetic material (for example, iron or ferrite), and the vertical axis represents the magnetic flux density (B), The horizontal axis indicates the magnetic field strength (H). Amorphous ferromagnetic materials exhibit unique characteristics in comparison with general magnetic materials in coercive force (Hc) and saturation magnetic flux density (Bm). As shown in FIG. Whereas the amorphous ferromagnetic material has a substantially S-shaped hysteresis curve, the amorphous ferromagnetic material has a hysteresis curve close to a rectangle as shown in FIG. 2A, and is abruptly magnetized by a low-intensity oscillating magnetic field. It has the property of repeating inversion (large Barkhausen phenomenon).

  The ferromagnetic material layer 24 records information used for authenticity determination using the unique properties of the amorphous ferromagnetic material, and reads out the recorded information, thereby facilitating discrimination of elaborate counterfeit products. In addition, the ferromagnetic material layer 24 can freely change its magnetic properties by changing the material blended with the amorphous ferromagnetic material, and further, a material that is difficult to obtain in the general market is used as the material. By using it, formation of the ferromagnetic material layer 24 itself can be made difficult, and the effect of preventing forgery is enhanced.

As described above, since the ferromagnetic material layer 24 is formed on the lower surface of the colored layer 23 by vapor deposition or the like, the ferromagnetic material layer 24 is also formed on a portion of the colored layer 23 where there is no striped ink, as shown in FIG. Thus, the thickness of the ferromagnetic material layer 24 becomes thick only at that portion. Therefore, the magnetic properties of the ferromagnetic material layer 24 change only at the portion where the thickness changes (becomes thicker), improving the ease of authenticating the ferromagnetic material layer 24 and the difficulty of counterfeiting.
The adhesive layer 25 is an adhesive that affixes the forgery prevention label 20 to the gift certificate 10 so as not to be peeled off.

  With the above configuration, a salesperson such as a retail store handling the gift certificate 10 is informed of the genuine hologram image recorded in the volume hologram layer 22 in advance, and the gift certificate 10 delivered from the customer at the time of product accounting is provided. By confirming the hologram image, the authenticity of the gift certificate 10 can be immediately determined. Further, even if the hologram image is imitated finely, by detecting the inherent magnetic characteristics of the ferromagnetic material layer 24 made of an amorphous ferromagnetic material with a magnetic head described later, the imitation product can be found reliably. Can do.

Next, a magnetic head that detects the ferromagnetic material layer 24 of the forgery prevention label 20 of this embodiment will be described. FIG. 3 is a schematic view of a magnetic head for reading the magnetic characteristics of the ferromagnetic material layer.
As shown in FIG. 3, the magnetic head 100 includes a detection coil unit 101, an excitation coil unit 102, a control unit 103, and a display unit 104, and is a detector that reads magnetic information of the ferromagnetic material layer 24 in a non-contact manner. is there.
The detection coil unit 101 includes a solenoid coil 101-A that detects a change in magnetic flux generated from the ferromagnetic material layer 24, and an amplifier 101-B that amplifies and outputs the detection data.
The exciting coil unit 102 includes a solenoid coil 102-A that applies an alternating excitation magnetic field to the ferromagnetic material layer 24, and an amplifier 102-B that passes an alternating excitation current that causes the solenoid coil 102-A to generate an alternating excitation magnetic field. Yes.

The control unit 103 outputs a command signal for causing a predetermined alternating excitation current to flow through the solenoid coil 102-A of the excitation coil unit 102 to the amplifier 102-B, and detects a change in magnetic flux generated from the ferromagnetic material layer 24. This is a control circuit that performs overall control of each part of the magnetic head 100 that inputs the detection result of the solenoid coil 101-A of the detection coil part 101 via the amplifier 101-B.
The display unit 104 is a liquid crystal display that displays the result detected by the detection coil unit 101 via the control unit 103.

Next, a method for detecting the ferromagnetic material layer 24 of the anti-counterfeit label 20 by the magnetic head 100 of this embodiment will be described.
When the power is turned on, the control unit 103 of the magnetic head 100 supplies a harmonic alternating excitation current to the solenoid coil 102-A of the excitation coil unit 102 via the amplifier 102-B, and keeps the solenoid coil 102-A in the solenoid coil 102-A. An alternating excitation magnetic field greater than the magnetic force Hc is generated. Subsequently, when the magnetic head 100 is brought close to the ferromagnetic material layer 24 of the anti-counterfeit label 20 affixed to the surface of the gift certificate 10, a large Barkhausen phenomenon is caused by an alternating excitation magnetic field greater than the coercive force Hc, and the control unit 103 Then, the change of the magnetic flux generated from the ferromagnetic material layer 24 is detected by the solenoid coil 101-A of the detection coil unit 101. The control unit 103 inputs the detected result via the amplifier 101 -B and displays it on the display unit 104.

  In the data detected by the magnetic head 100, the unique characteristics of the amorphous ferromagnetic material mixed with a specific material are displayed on the display unit 104, so that a counterfeit product of the gift certificate 10 has a ferromagnetic material layer 24. Even if it is provided, the detected magnetic property data cannot be made the same, and an elaborate counterfeit product can be discriminated.

From the above, the forgery prevention label of the present embodiment has the following effects.
(1) Since the volume hologram layer 22, the colored layer 23, and the ferromagnetic material layer 24 are provided in this order on the back surface of the base material 21, the anti-counterfeit label 20 is confirmed by visual confirmation of the volume hologram layer 22 and strong. The anti-counterfeit label 20 can be identified by checking the magnetic information of the magnetic material layer 24 based on the magnetic information, and the anti-counterfeit label 20 can be obtained by adopting the volume hologram layer 22 in which the interference fringes are difficult to duplicate. Forgery can be made difficult.
(2) Since the anti-counterfeit label 20 is provided with the adhesive layer 25 on the back surface of the ferromagnetic material layer 24, the counterfeit prevention label 20 is attached to the sheet-like base material 11 used for the gift certificate 10. Discrimination can be facilitated.

(3) Since the ferromagnetic material layer 24 is formed of an amorphous ferromagnetic material, the magnetic property (large Barkhausen effect) unique to the amorphous ferromagnetic material, which is different from the magnetic property exhibited by a general magnetic material, should be used. Accordingly, it is possible to easily determine the authenticity of the ferromagnetic material layer 24 and make it difficult to forge the ferromagnetic material layer 24.
(4) Since the colored layer 23 is formed in a striped shape, the striped pattern of the colored layer 23 can be visually recognized through the transparent base material 21 and the volume hologram layer 22, and the forgery prevention label 20. The design property of can be improved. Further, since the ferromagnetic material layer 24 is formed by vapor deposition or the like in the portion of the colored layer 23 where the striped printing ink is not present, the thickness of the ferromagnetic material layer 24 can be changed only in that portion. By changing the magnetic characteristics by changing the thickness, it is possible to easily determine the authenticity of the ferromagnetic material layer 24 and to make it difficult to forge the ferromagnetic material layer 24.

(Second Embodiment)
FIG. 4 is a schematic view showing an anti-counterfeit transfer foil transferred to a gift certificate as a second embodiment of the anti-counterfeit medium according to the present invention. FIG. 4 (a) is a plan view, and FIGS. The figure explaining the flow until it transfers a forgery prevention transfer foil to the gift certificate in CC sectional drawing of Fig.4 (a) to d) is shown. Here, in the description of the following embodiment, the same function as that of the first embodiment described above is denoted by the same reference symbol or a unified reference symbol at the end, and repeated description and drawings are appropriately omitted. .

As shown in FIG. 4A, the anti-counterfeit transfer foil 20-2 of the second embodiment is similar to the anti-counterfeit label 20 of the first embodiment in the basic layer configuration. Mainly, the peeling layer 26 is provided between the base material 21 and the volume hologram layer 22, the form of the colored layer 23-2 is changed, and the adhesive layer 25 is the heat-sensitive adhesive layer 27. It is a point that has been changed to.
The anti-counterfeit transfer foil 20-2 is a transfer foil that is thermally transferred to the surface of the gift certificate 10 in order to prevent forgery and determine the authenticity of the gift certificate 10, and has a release layer 26 and a volume hologram layer on the back surface of the base material 21. 22, the coloring layer 23-2, the ferromagnetic material layer 24, and the heat-sensitive adhesive layer 27 are laminated in this order.

  The release layer 26 is provided to release the base material 21 that becomes unnecessary after the forgery prevention transfer foil 20-2 is transferred to the sheet-like base material 11 from the surface of the volume hologram layer 22. The release layer 26 remains on the surface of the volume hologram layer 22 after the substrate 21 is peeled off, and can protect the surface of the volume hologram layer 22 that is exposed. Therefore, the release layer 26 is formed of a resin that has not only easy peelability but also transparency, friction resistance, contamination resistance, solvent resistance, and the like, for example, an acrylic ester resin and a vinyl chloride resin. The Here, the peeling layer 26 is pasted to the base material 21 and the volume hologram layer 22 by a specific pasting force so as not to be pasted again. The pasting force is obtained by melting a heat-sensitive adhesive layer 27 described later. It is set to be weaker than the adhesive strength.

Unlike the first embodiment, the colored layer 23-2 is formed of black ink on the entire back surface of the volume hologram layer 22, and makes the visible hologram image of the volume hologram layer 22 visible. Can do.
The heat-sensitive adhesive layer 27 is an adhesive that is provided on the back surface of the ferromagnetic material layer 24 and generates an adhesive force when heated, and is formed of, for example, an ethylene-vinyl acetate copolymer resin.

Next, a method for transferring the anti-counterfeit transfer foil 20-2 to the sheet-like substrate 11 will be described.
Since the anti-counterfeit transfer foil 20-2 includes the heat-sensitive adhesive layer 27, it can be transferred to the sheet-like substrate 11 by pressing the hot plate 200.
As shown in FIG. 4 (b), the hot plate 200 has barcode-like irregularities formed on the surface in contact with the forgery prevention transfer foil 20-2. Due to the uneven shape, the forgery prevention transfer foil 20-2 pressed by the hot plate 200 is transferred to the sheet-like substrate 11 only at the portion pressed by the convex portion 200a of the hot plate 200.

Specifically, the operator raises the temperature of the hot plate 200 to a temperature necessary for melting the heat-sensitive adhesive layer 27, and when the hot plate 200 reaches a specified temperature, as shown in FIG. Then, the sheet is pressed against the forgery-preventing transfer foil 20-2 superimposed on the sheet-like substrate 11 (arrow D). When the heat plate 200 is pressed and a predetermined time elapses, the heat-sensitive adhesive layer 27 of the anti-counterfeit transfer foil 20-2 is melted by the heat of the hot plate 200, and the anti-counterfeit transfer foil 20-2 is applied to the sheet-like substrate 11. Glued.
Since only the site | part corresponding to the convex part 200a formed in the heat plate 200 is adhere | attached on the sheet-like base material 11 by the heat sensitive adhesive layer 27, the forgery prevention transfer foil 20-2 is shown in FIG.4 (c). When the base material 21 is peeled from the anti-counterfeit transfer foil 22 at the interface with the release layer 26 (arrow E), only the portion corresponding to the concave portion 200b of the hot plate 200 of the anti-counterfeit transfer foil 22 is prevented together with the base material 21. The transfer foil 22 is peeled off.

By peeling the base material 21 from the anti-counterfeit transfer foil 20-2, the anti-counterfeit transfer foil 20-2 is formed on the surface of the sheet-like base material 11 as shown in FIGS. 4 (d) and 4 (a). Only the portion corresponding to the convex portion 200a of the hot plate 200 remains, and the gift certificate 10 having the bar code-shaped forgery prevention transfer foil 20-2 is completed.
Here, when peeling the base material 21 at the interface with the peeling layer 26, the forgery prevention transfer foil 20-2 is between the position corresponding to the convex part 200a of the hot plate 200 and the position corresponding to the concave part 200b. Disconnected. In order to facilitate the cutting of the anti-counterfeit transfer foil 20-2 between the concave and convex portions (easy to cut the foil), the anti-counterfeit transfer foil 20-2 is composed of the volume hologram layer 22 and the ferromagnetic material layer 24. Fine particles may be added to the material.

From the above, the forgery prevention transfer foil 20-2 of the present embodiment has the following effects.
(1) In the forgery prevention transfer foil 20-2, the volume hologram layer 22, the colored layer 23-2, the ferromagnetic material layer 24, and the heat-sensitive adhesive layer 27 are arranged in this order on the back surface of the base material 21 through the release layer 26. Therefore, the transfer foil having the volume hologram layer 22, the colored layer 23-2, and the ferromagnetic material layer 24 can be transferred to the gift certificate 10 without being peeled off by the heat-sensitive adhesive layer 27. It is possible to discriminate the counterfeit product and to prevent fraud due to pasting.

(2) Since the colored layer 23-2 of the anti-counterfeit label 20-2 is printed so as to fill the entire back surface of the volume hologram layer 22 with black ink, it is provided on the back surface of the colored layer 23-2. The ferromagnetic material layer 24 can be prevented from being visually recognized from the surface of the anti-counterfeit transfer foil 20-2, and the ferromagnetic material layer 24 can be concealed. Moreover, since the black ink is used for the colored layer 23-2, the hologram image recorded on the volume hologram layer 22 visually recognized from the forgery prevention transfer foil 20-2 can be made clear.

(Third embodiment)
FIG. 5 is a schematic diagram showing a forgery prevention transfer foil transferred to a gift certificate as a third embodiment of the forgery prevention medium according to the present invention.
The anti-counterfeit label 20-3 of the third embodiment is different from the anti-counterfeit label 20 of the first embodiment as shown in FIG. 5 in that there are two colored layers, that is, the first colored layer 23a. And it exists as the 2nd colored layer 23b.
The first and second colored layers 23a and 23b are printed with striped patterns having the same pitch and different thicknesses. Specifically, the stripes of the first colored layer 23a are set to be thicker than the stripes of the second colored layer 23b, and the second colored layer 23b is formed so as not to be visually recognized from the surface of the substrate 21. Has been.

The ferromagnetic material layer 24 is a thin film layer formed of an amorphous ferromagnetic material, and is formed on the back surface of the second colored layer 23b by a vacuum film forming method such as vapor deposition. Further, since the ferromagnetic material layer 24 is formed by vapor deposition on a portion of the first colored layer 23a and the second colored layer 23b where there is no ink in the striped pattern, the ferromagnetic material layer 24 only at that portion. Can be made thicker than other parts.
Specifically, as shown in FIG. 5B, the thickness of the ferromagnetic material layer 24 is the smallest at the G portion formed on the back surface of the second colored layer 23b, and the first colored layer 23a. In addition to the thickness of the ferromagnetic material layer 24 in the G portion, the thickness of the second colored layer 23b is added to the H portion on the back surface of the G portion, so that it is thicker than the G portion. Since the thickness of the first colored layer 23a is added to the thickness of the ferromagnetic material layer 24 of the H portion, the portion becomes the thickest.

  As described above, the anti-counterfeit transfer foil 20-3 of the present embodiment includes the first colored layer 23a and the second colored layer 23b, so that the ferromagnetic material layer 24 is disposed on the lower surface of the second colored layer 23b. In addition, the first colored layer 23a and the second colored layer 23b are also formed in a portion where there is no ink in a striped pattern, and the thickness of the ferromagnetic material layer 24 is changed to change the magnetic characteristics. Authentication can be performed by specific magnetic properties. Further, since the second colored layer 23b is concealed from the surface of the base material 21, the change in the thickness of the ferromagnetic material layer 24 cannot be determined from the appearance of the forgery prevention label 20-3. Forgery of the layer 24 can be made more difficult.

(Fourth embodiment)
FIG. 6 is a schematic diagram showing a forgery prevention thread inserted into a gift certificate as a fourth embodiment of the forgery prevention medium according to the present invention. FIG. 6A shows the forgery prevention thread inserted into a sheet-like substrate. FIG. 6B shows an enlarged view of the JJ cross section of FIG.
As shown in FIG. 6, the anti-counterfeit thread 20-4 of the fourth embodiment is similar in basic layer configuration to the anti-counterfeit label 20 of the first embodiment, and the difference is that the anti-counterfeit thread 20-4. The adhesive layer 25 is not provided on the back surface of the -4 ferromagnetic material layer 24, and the sheet-like base material 11 is wound as a thread.

As shown in FIG. 6A, the gift certificate 10-4 includes a sheet-like base material 11 formed of rectangular high-quality paper, and a forgery prevention thread 20-4 squeezed into the sheet-like base material 11. It is a cash voucher that can be used at department stores and retail stores.
As shown in FIG. 6B, the forgery prevention thread 20-4 is a belt-like thread that is inserted when the sheet-like base material 11 is made, and the length of the belt-like long side portion is set to be shorter than that of the sheet-like base material 11. It is the size of the side. The anti-counterfeit thread 20-4 has a volume hologram layer 22, a colored layer 23, and a ferromagnetic material layer 24 laminated in order on the back surface of the base material 21.

  As mentioned above, since the gift certificate 10-4 of this embodiment is formed in a state where the anti-counterfeit thread 20-4 is inserted into the sheet-like base material 11, the anti-counterfeit thread 20-4 is combined with the sheet-like base material 11. By integrating, it is possible to prevent unauthorized replacement of the forgery prevention part of the gift certificate 10-4, and to make it difficult to forge the gift certificate 10-4.

(Deformation)
The present invention is not limited to the embodiment described above, and various modifications and changes are possible, and these are also within the scope of the present invention.
(1) In each embodiment, the forgery prevention measure of the gift certificate 10 has been described as an example. However, for example, a counterfeit prevention label 20 or a forgery prevention transfer foil 20- 2 may be used.
(2) In the second embodiment, the surface of the hot plate 200 that comes into contact with the forgery-preventing transfer foil 20-2 has a barcode-like unevenness, but forms a flat surface or a pattern that does not have any unevenness. An uneven surface may be provided.
Each embodiment and modification may be used in appropriate combination, but detailed description is omitted. Further, the present invention is not limited by the embodiments described above.

It is a schematic diagram which shows the forgery prevention label affixed on the gift certificate as 1st Embodiment of the forgery prevention medium by this invention. It is a figure which shows the BH magnetization characteristic curve of an amorphous ferromagnetic material and a general magnetic material. It is the schematic of the magnetic head which reads the magnetic characteristic of a ferromagnetic material layer. It is a schematic diagram which shows the forgery prevention transfer foil transcribe | transferred to the gift certificate as 2nd Embodiment of the forgery prevention medium by this invention. It is a schematic diagram which shows the forgery prevention label affixed on the gift certificate as 3rd Embodiment of the forgery prevention medium by this invention. It is a schematic diagram which shows the forgery prevention rolling thread inserted into the gift certificate as 4th Embodiment of the forgery prevention medium by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Gift certificate 11 Sheet-like base material 20, 20-3 Anti-counterfeit label 20-2 Anti-counterfeit transfer foil 20-4 Anti-counterfeit thread 21 Base material 22 Volume type hologram layer 23 Colored layer 24 Ferromagnetic material layer 25 Adhesive layer 26 Peeling Layer 27 Heat-sensitive adhesive layer

Claims (9)

A substrate;
A volume hologram layer that is provided on one surface side of the substrate and records interference fringes generated by light interference as fringes having different refractive indexes in the thickness direction of the layer;
A ferromagnetic material layer provided on a surface opposite to the base of the volume hologram layer and formed of a ferromagnetic material;
An anti-counterfeit medium comprising: In the anti-counterfeit medium according to claim 1,
The ferromagnetic material layer is formed of an amorphous ferromagnetic material having specific magnetization characteristics;
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to claim 1 or 2,
A colored layer is provided between the ferromagnetic material layer and the volume hologram layer;
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to claim 3,
The colored layer is formed in a pattern,
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to claim 3 or claim 4,
The colored layer is formed of black ink;
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to any one of claims 1 to 5,
An adhesive layer is provided on the side of the ferromagnetic material layer opposite to the volume hologram layer;
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to claim 6,
Providing a release layer between the substrate and the volume hologram layer;
An anti-counterfeit medium characterized by. In the anti-counterfeit medium according to claim 7,
The anti-counterfeit medium is pasted to the object to be pasted by the adhesive layer in a state of being peeled from the base material by the release layer;
An anti-counterfeit medium characterized by. The forgery prevention medium according to any one of claims 1 to 5,
A sheet-like base material formed in a state in which the anti-counterfeit medium is swallowed,
Anti-counterfeit sheet comprising

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