JP2019209502A - Non-contact type ic card and manufacturing method of the same - Google Patents

Abstract

To have brilliance, but to secure a sufficient light shielding property in a portion which should not exhibit brilliance.SOLUTION: A partially metallic card 10 includes a glossy print layer 2 on one surface or on both surfaces, and it includes a shield print layer 5 partially at an upper layer of the glossy print layer 2. The glossy print layer 2 may exhibit brilliance like metallic gloss. The shield print layer 5 has white color, has thickness for shielding brilliance emitted by the glossy print layer 2 on the lower layer, and may be laid out partially in a range which does not require brilliance to form a brilliance shield range 6a. The layer thickness of the shield print layer 5 may be equal to or greater than 3.5 μm so as to shield brilliance of the glossy print layer 2 on the lower layer.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a non-contact type IC card partially having metallic glitter that is difficult to reproduce by normal printing and a method for manufacturing the same.

  In recent years, contactless IC cards have been introduced in a wide range of industries, such as bank cash cards, credit cards, automatic rail fare clearing cards, and retailer membership cards, and are used in a variety of fields from everyday life to business. Yes.

  Non-contact IC cards provided to customers are printed with design expressions that emphasize the image of the issuer and the concept of the service to be provided, improving the image of the issuer and spreading the services provided Contributing to In particular, for high brands and high-value customers that require a high-class feeling, non-contact type IC cards called metallic cards having metallic radiance are provided in order to enhance their speciality.

  In the conventional metallic card, a base card having a gloss printed layer on the inner layer of the card is prepared in advance, and the design desired by the customer is processed by offset printing on the card surface after ordering (for example, patents). Reference 1).

JP 2012-56113 A

  According to the above-described metallic card manufacturing method, when it is not desired to partially bring out the glitter, the offset property alone is insufficient in shielding, and the glitter of the lower layer can be seen through.

  The present invention is proposed in view of the above-described circumstances, and has a glittering property, but a non-contact IC card capable of ensuring a sufficient light shielding property in a portion where the glittering property is not desired. And it aims at providing the manufacturing method.

  In order to solve the above-described problems, the invention of the non-contact type IC card according to the present application includes a glossy printing layer on one side or both sides, and partially includes a shielding printing layer on an upper layer of the glossy printing layer. The shielding printing layer may be white.

  The glossy printed layer may exhibit metallic luster-like glitter. The shielding printing layer may have a thickness that shields the glitter emitted by the lower glossy printing layer, and may be partially laid out in a range that does not require the glitter. The thickness of the shielding printing layer may be 3.5 μm or more so as to shield the glitter of the lower glossy printing layer.

  A transparent printing layer having light transmittance may be included in the upper layer of the glossy printing layer. A transparent printing layer having light transmittance may be included in the upper layer of the shielding printing layer. The transmissive printing layer may be processed by offset printing to transmit the glitter of the lower glossy printing layer.

  The layer thickness including the magnetic stripe and including the shielding printing layer and the transmission printing layer may be 18.8 μm or less.

  A non-contact IC card manufacturing method according to the present application includes a step of providing a base card including a glossy print layer on one or both sides, a step of partially printing a shielding print layer on the glossy print layer, and gloss printing. And a step of printing a transparent printing layer having light transmittance on the upper layer of the layer. The shielding printing layer may be white. A transparent printing layer having light transmittance may be included in the upper layer of the shielding printing layer.

  According to the present invention, it is possible to provide a non-contact type IC card that has a brilliant property but can ensure a sufficient light-shielding property for a portion where the brilliant property is not desired.

It is sectional drawing which shows the structure of the non-contact-type IC card of this Embodiment. It is the figure which showed the evaluation result of the glittering shielding condition with respect to the printing layer thickness of a shielding printing layer. It is a graph showing the relationship of the magnetic output of a magnetic stripe with respect to printing layer thickness. It is sectional drawing which shows the structure of the conventional non-contact-type IC card as a comparative example.

  Hereinafter, a non-contact type IC card and a manufacturing method thereof according to the present embodiment will be described in detail with reference to the drawings. The non-contact type IC card of the present embodiment is a realization of a metallic card partially having a glittering property by providing a shielding printing layer in a range not requiring a glittering property in the upper layer of the glossy printed layer. In this embodiment, such a non-contact IC card is referred to as a partial metallic card.

  FIG. 1 is a cross-sectional view showing the configuration of the partial metallic card 10. In the partial metallic card 10, the gloss printing layer 2, the transparent skin material 3, the shielding printing layer 5, and the transmission printing layer 4 are sequentially laminated on the upper surface of the intermediate support material 1. The intermediate support 1 includes circuits such as an IC chip and an antenna inside, and supports the partial metallic card 10 with rigidity. The shielding printing layer 5 is partially laid out on the upper surface of the transparent skin material 3 to form a glittering shielding range 6a and a glittering opening range 6b. On the lower surface of the intermediate support material 1, a transparent skin material 3 and a transmissive printing layer 4 are laminated in order.

  The partial metallic card 10 of the present embodiment is manufactured by a series of steps as follows. The gloss printing layer 2 is formed by printing the ink which mix | blended metal powder on the whole upper surface of the intermediate support material 1 by silk screen printing.

  A transparent skin material 3 is formed on the upper surface of the glossy printing layer 2 by hot pressing a transparent thermoplastic film, PVC, or PET-G, which is transparent and allows the glossy printing layer 2 of the lower glossy layer 2 to pass therethrough sufficiently. . In order to allow the lower layer to permeate well during hot pressing, the surface of the transparent skin 3 is finished to a mirror surface by sanding with a mirror-finished decorative board.

  On the other hand, the transparent skin material 3 is also formed on the lower surface of the intermediate support material 1 in the same manner as the upper surface of the glossy printed layer 2. Here, the base card can also be configured by laminating the glossy printed layer 2 and the transparent skin material 3 on the upper surface of the intermediate support material 1 and the transparent skin material 3 on the lower surface. The following process is the same as the process of manufacturing the partial metallic card 10 from the base card.

  On the upper surface of the transparent skin material 3, the gloss printing layer 2 does not require the glitter property of the glitter shielding area 6a, and is printed with white ink containing a titanium oxide pigment having a high light shielding property by offset printing. Form. The shielding printing layer 5 is partially laid out so that the glitter shielding area 6a is formed not at the entire upper surface of the transparent skin material 3 but at a place where the glitter is not required. A glittering opening range 6b is formed on the upper surface of the transparent skin material 3 where the shielding printing layer 5 is not formed.

  The shielding printing layer 5 needs to completely shield the glitter, and depending on the particle size and blending ratio of the metal powder contained in the glossy printing layer 2, the above-described titanium oxide pigment having a high light shielding property is used. When white ink is used, the printed layer thickness is at least 3.5 μm or more, as will be described later.

  The transparent printing layer 4 having an arbitrary design is printed on the upper surface of the shielding printing layer 5 by offset printing. The ink of the transmissive printing layer 4 may or may not be present on the upper surface of the shielding printing layer 5. Further, although the glossy printing layer 2 is silver due to the influence of the metal powder, white can be expressed by using white ink for the shielding printing layer 5.

  The transparent printing layer 4 of any design may be printed on the lower surface of the transparent skin material 3 laminated on the lower surface of the intermediate support material 1 by offset printing.

  The partial metallic card 10 according to the present embodiment can also provide a function of installing a magnetic stripe 7 in the vicinity of the long side of the card and reading information recorded by a magnetic field with a magnetic reader. Here, when printing the shielding printing layer 5 and the transmissive printing layer 4 on the magnetic stripe 7 side, the shielding printing layer 5 and the transmissive printing layer 4 are arranged so as to ensure reading of recorded information while maintaining a distance from the magnetic reader. The print layer thickness 8 including the thickness of 1 is 18.8 μm or less as will be described later.

  According to the partial metallic card 10 of the present embodiment, a sufficient light-shielding property can be ensured in a portion having a glitter property but not desired to exhibit the glitter property. For example, if you do not want to bring out glitter, for example, if the background of the name of a store or important catch phrase has glitter, the visual legibility deteriorates and the advertising effect is lost, or the trademark glitter In order to make the image stand out, there are cases where it is necessary to completely shield the glitter of the range other than the mark. By using the partial metallic card 10 of the present embodiment, it is possible to provide partial glitter with high designability that is difficult with normal printing.

  The shielding printing layer 5 is not limited to white but may be other colors such as cream as long as it can shield the glitter. The shielding printing layer 5 may be, for example, red, yellow, green, blue, purple, cyan, or magenta.

  FIG. 2 shows the relationship of the glittering shielding condition to the printing layer thickness of the shielding printing layer 5. For the shielding printing layer 5, white ink containing the above-described titanium oxide pigment having high light shielding properties was used. As can be seen in the enlarged photograph of the shielding printing layer 5 in the figure, the glossiness of the glossy printing layer 2 was completely visible when the printing layer thickness was 1.3 μm or less. When the printing layer thickness was 2.4 μm, the glossiness of the glossy printing layer 2 was slightly visible. When the printed layer thickness was 3.5 μm or more, the glossy printed layer 2 was able to completely shield the glitter. As described above, in the partial metallic card 10 of the present embodiment, the glossiness of the glossy printing layer 2 is completely shielded by setting the printing layer thickness of the shielding printing layer 5 to at least 3.5 μm.

  FIG. 3 is a graph showing the relationship between the printed layer thickness 8 including the thicknesses of the shielding printed layer 5 and the transmissive printed layer 4 and the magnetic output. By extending the magnetic output data for the print layer thickness 8 shown in the graph, if the print layer thickness is 18.8 μm or less, the standard is established by, for example, JISX6302-2: 2005 magnetic stripe-low coercive force. It has become clear that the output characteristics of the magnetic stripe 7 are satisfied. As described above, in this embodiment, the output characteristics of the magnetic stripe 7 are ensured by setting the print layer thickness 8 to 18.8 μm or less.

(Comparative example)
FIG. 4 is a cross-sectional view showing a configuration of a conventional non-contact IC card as a comparative example. The non-contact type IC card of the comparative example is referred to as a metallic card and has glossiness on the entire surface. In this metallic card 100, a glossy printed layer 2, a transparent skin material 3 and a transmissive printed layer 4 are sequentially laminated on the upper surface of the intermediate support material 1, and a magnetic stripe 7 is installed in the vicinity of the long side of the card. On the lower surface of the intermediate support material 1, a transparent skin material 3 and a transmissive printing layer 4 are laminated in order. In addition, in order to clarify the correspondence with the partial metallic card 10 of the present embodiment, the same reference numerals are assigned to the corresponding members.

  In the metallic card 100 of the comparative example, the shielding printing layer 5 like the partial metallic card 10 of the present embodiment does not exist. Therefore, the entire upper surface of the metallic card 100 of the comparative example has a glitter property due to the glossy printed layer 2.

DESCRIPTION OF SYMBOLS 1 Intermediate support material 2 Glossy printing layer 3 Transparent skin material 4 Transparent printing layer 5 Shielding printing layer 6a Glossy shielding range 6b Glossy opening range 7 Magnetic stripe 8 Printing layer thickness (shielding printing layer 5 + transmission printing layer 4)
10 Partial metallic card

Claims (12)

  A non-contact type IC card comprising a glossy printed layer on one side or both sides and partially including a shielding printed layer on the glossy printed layer.   The non-contact type IC card according to claim 1, wherein the shielding printing layer is white.   The non-contact type IC card according to claim 1, wherein the glossy printed layer exhibits a metallic luster-like glitter.   The said shielding printing layer has the thickness which shields the glitter which a lower glossy printing layer emits, and is partially laid out in the range which does not require the glitter. Non-contact IC card.   5. The non-contact type according to claim 1, wherein the thickness of the shielding printing layer is 3.5 μm or more so as to shield the glitter of the lower glossy printing layer. IC card.   The non-contact type IC card according to any one of claims 1 to 5, further comprising a light-transmitting transmissive printing layer as an upper layer of the glossy printing layer.   The non-contact type IC card according to claim 6, wherein the transparent printed layer is processed by offset printing to transmit the glitter of the lower glossy printed layer.   The non-contact type IC card according to claim 6 or 7, wherein a transparent printing layer having light transmittance is included in an upper layer of the shielding printing layer.   9. The non-contact type IC card according to claim 6, wherein the non-contact type IC card includes a magnetic stripe and has a total thickness of 18.8 μm or less including the shielding printing layer and the transmission printing layer. A method of manufacturing a non-contact IC card,
Providing a base card including a glossy printed layer on one or both sides;
Printing a shielding printing layer partially on the glossy printing layer;
A non-contact type IC card manufacturing method comprising: printing a light-transmitting transmissive printing layer on the glossy printing layer.   The method of manufacturing a non-contact type IC card according to claim 10, wherein the shielding printing layer is white. The method for producing a non-contact type IC card according to claim 10, wherein a transparent printing layer having light transmittance is included in an upper layer of the shielding printing layer.