JPH03126596A - Concealable magnetic card and preparation thereof - Google Patents

Abstract

PURPOSE:To apply printing having a beautiful and sharp color to the surface of a magnetic card on the side of the magnetic layer thereof by forming a metal vapor deposition layer on the magnetic layer of the magnetic card directly or through an anchor coat layer and forming a color layer on the metal vapor deposition layer directly or through a top coat layer and specifying the thicknesses of both of the metal vapor deposition layer and the color layer. CONSTITUTION:A metal vapor deposition layer is formed on the magnetic layer of a magnetic card equipped with a base material and the magnetic layer formed to the single surface thereof directly or through an anchor coat layer and a color layer having a non-black type color is formed on the metal vapor deposition layer directly or through a top coat layer and the whole thickness of the metal vapor deposition layer and the color layer (thickness containing the anchor coat layer and the top coat layer when both layers are present) is 6mum or less. The magnetic layer can be formed by using a composition prepared by mixing an appropriate magnetic powder such as gamma-iron oxide with an appropriate resin such as an urethane resin. The metal vapor deposition layer is formed from Al, Ag, Zn or Sn and may be formed from Cu or Au according to the color layer. The color layer having the non-black type color can be formed from an appropriate resin mixed with pigment or a dye.

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to magnetic cards such as cash cards, commuter passes, highway cards, prepaid cards, telephone cards, etc., and a method for manufacturing the same, and the present invention relates to magnetic cards such as cash cards, commuter passes, highway cards, prepaid cards, telephone cards, etc., and a method for manufacturing the same. The present invention relates to a concealable magnetic card and a method for manufacturing the same, which can make the magnetic layer side of the card a beautiful and clear color without affecting the magnetic layer side, and also enable printing of a beautiful and clear color on the surface of the magnetic layer side.

(Prior art) A conventional magnetic card has a magnetic layer formed on one side of a base material.
On top of the magnetic layer, there is a thin, slippery protective layer that is colored black or coated with aluminum powder.
Formed to provide abrasion resistance.

(Problem to be solved by the invention) However, the protective layer of conventional magnetic cards is colored black, which is unsightly from an aesthetic point of view, and the protective layer mixed with aluminum powder is blackish gray, which is also aesthetically unsightly. It was unsightly, and the colors were far from beautiful and clear. This feeling was particularly strong because the side of the magnetic card opposite to the protective layer generally has beautiful, clear color printing.

To eliminate this drawback, the protective layer should be colored with a non-black pigment,
For example, white, Ipoly-1 pale pink, yellow, orange,
It is possible to make the protective layer a beautiful and clear color by using a bright colorful color such as red, but in this case, since these non-black colors do not have concealing properties, the protective layer should not be used. Unless it is considerably thicker than about 10 μm, the protective layer will be affected by the color of the underlying magnetic layer, which is black or brown, and will not have a beautiful and clear color.

However, when the A9 layer becomes more than lQ71m, it becomes too thick.
This adversely affects magnetic performance, resulting in inability to record and read magnetic fields, errors, malfunctions of input/output devices, etc.

In addition, the protective layer of conventional magnetic cards has good slippage and wear resistance, but it is too slippery and does not have sufficient printability.
It was not easy to print on top of the protective layer. In order to eliminate this drawback, the slippage of the protective layer should be made a little bit worse.
It may be possible to provide sufficient printability, but if the slippage becomes poor, the layer resistance will be poor, so the protective layer must be made thicker. No adverse effect on.

In addition, even if printing is possible on the protective layer, if it is printed with a bright colorful non-black color, the non-black color does not have lO masking properties, so the underlying black color or black color may appear. Under the influence of the gray color of the ff protection layer, the printing becomes dull and f:,r! G does not produce clear colors.

In order to eliminate the above-mentioned drawbacks, it has been proposed to transfer a transfer material onto the magnetic layer of a magnetic card (Japanese Patent Laid-Open No. 6
4-25318, Japanese Utility Model Application No. 64-11777, Japanese Utility Model Application No. 1-68872, etc.), in other words, a transfer material having a laminate of a colored layer or a printed layer and a metal vapor deposited layer is transferred to a magnetic layer. The colored layer and printed layer are transferred onto the magnetic layer side and the metal evaporated layer is placed on the surface side, and the metal evaporated layer provides hiding properties, resulting in beautiful and clear colors of the colored layer and printed layer. So that it becomes.

However, the use of a transfer material is time-consuming and complicated because the transfer material is manufactured in advance and this transfer material is transferred to the magnetic layer of the magnetic card. Furthermore, since heat of 180 to 200° C. is applied during transfer of the transfer material, there is also the drawback that the base material of the magnetic card is deformed by the heat. For example, in roll transfer, the base material becomes wavy or warped. There is a multi-stage press to prevent deformation, but this is not a continuous transfer method, as it involves repeatedly cutting the object to be transferred and the transfer material, stacking them, and pressing them. , the efficiency is extremely low compared to roll transfer.

In addition to the above-mentioned technique ((, i), a magnetic pasting recording body is also known for appropriately pasting onto bank passbook paper, etc. (!l? Publication No. 15657 of 1983).

However, this is because the pasted recording material is in use! If gl
There is a drawback that it comes with

This invention eliminates the various drawbacks mentioned above, provides a beautiful and clear color to the magnetic layer side of the card without adversely affecting the magnetic performance of the magnetic card, and also provides a beautiful and clear color to the surface of the magnetic layer 0111. A concealable magnetic card and a manufacturing method thereof, which enable printing, can be efficiently manufactured without deforming the base material unlike roll transfer, and do not peel off during use. This is what we provide.

(Means for Solving the Problems) The present invention provides the following concealable magnetic card and method for manufacturing the same.

(1) A metal vapor-deposited layer is formed directly or via an anchor coat layer on the magnetic layer of a magnetic card comprising a base material and a magnetic layer formed on one side of the magnetic card, and the metal vapor-deposited layer is formed on the magnetic layer of the magnetic card. - A colored layer with a non-black color is formed directly or through a 1-7 coat layer, and metal vapor deposition J? 1. A concealable magnetic card characterized in that the total thickness of the color layer and the coloring layer (the thickness of the anchor coat layer and the top coat including these) is 6 μm or less.

(2) The concealable magnetic card according to claim 1, wherein the metal vapor deposition layer is an insulating metal vapor deposition layer.

(3) A metal vapor deposition layer is formed directly or via an anchor coat layer on the magnetic layer of a magnetic card comprising a base material and a magnetic layer formed on one side of the magnetic card, and a metal vapor deposition layer is formed on the metal vapor deposition layer. , if a colored layer with a non-black color is formed directly or via a top coat layer, and the thickness of the metal vapor deposited layer and the colored layer is 1+X (anchor layer, top coat) - JjM, A method for producing a concealable magnetic card, characterized in that the total thickness (including these) is 6 μm or less.

(4) The method for manufacturing a concealable magnetic card according to claim 3, wherein the metal vapor deposition layer is an insulating metal vapor deposition layer.

As the base material, those conventionally used as base materials for magnetic cards, such as vinyl chloride sheets and polyester sheets, can be used.

For the magnetic layer, a suitable material such as urethane resin (A resin with γ
- Those mixed with appropriate magnetic powder such as iron oxide, etc., which are conventionally used for magnetic cards (1) can be used. The magnetic layer may be formed by vapor deposition. The layer is formed completely or partially on one side of the substrate.

Directly or via an anchor yaw layer on the magnetic layer,
Form a metal vapor deposition layer.

The metal vapor deposition layer is A1. Ag. Zn. Depending on the color of the non-black colored layer to be formed later, a metal vapor deposition layer such as Cu or Au may be used. The metal vapor deposition layer should be 11 to give a metallic luster, or 100 to 100.
Preferably 0 people. The metal vapor deposition layer may be formed partially depending on the case.

Metal evaporation (J) can also be made of insulating metal.

In this case, the metal vapor deposited layer has a metallic luster and also has insulating properties.

In order to make the metal vapor deposited layer insulative, the metal vapor deposited layer may be made into an island-like horizontal path, as described in, for example, Japanese Patent Application Laid-Open No. 174189/1983.

When a normal metal vapor deposition layer that has a metallic luster and is conductive is used, static electricity tends to accumulate because the conductive metal vapor deposition layer is sandwiched between insulating resin layers on both sides. When static electricity accumulates, it adversely affects magnetic performance.

Unreadable magnetic records, misreading, reader malfunctions, etc. occur. In this regard, if the metal vapor deposited layer is made insulating from the beginning, static electricity will be more difficult and will not adversely affect the magnetic performance.

The metal vapor deposited layer can provide hiding properties to the non-black colored layer that will be formed later. In other words, if a colored Jfi with a non-black color is formed directly on the magnetic layer, since the non-black color does not have hiding properties, the influence of the color of the magnetic layer, which is a black color such as brown, which is the base, will be reduced. As a result, the colored layer becomes dull in color, but if there is a metal vapor deposited layer under the colored layer with a non-black color, the light rays are reflected by the metal vapor deposited layer, resulting in a beautiful and vivid colored layer. It is something that can be formed.

Before forming the metal vapor deposition layer on the magnetic layer, an anchor coat layer may be formed on the magnetic layer in advance, and a metal vapor deposition layer may be formed on the anchor coat layer. The anchor coat layer can be formed of an appropriate resin depending on the magnetic powder used for the magnetic layer, the resin mixed with the magnetic powder, the metal used for the metal deposited layer, etc. The anchor coat layer is 0. ]~2μm
A thickness of .

A colored layer having a non-black color is formed directly or via a top layer on the second layer of the metal vapor deposited layer.

Non-black colors are bright, colorful colors such as white, eyelid, pale pink, yellow, orange, red, etc., which either have no concealing properties or have weak concealing properties. Colors such as black, brown, and rH III have hiding properties and are blackish colors.

Furthermore, in this book, non-black colors include colorless and transparent layers, and non-black colored JMs include colorless and transparent layers. When a colored layer with a non-black color is made into a transparent layer, the color of the metal vapor deposited layer, which has a beautiful and clear metallic luster, appears as is.

The colored layer having a non-black color can be formed from an appropriate resin mixed with a pigment or dye.

The face f4 may be a fluorescent pigment, and if a fluorescent pigment is used, it should be formed of an appropriate resin that does not contain pigments or dye f-1 in the case of a colorless and transparent layer that is easy to see at night. The colored layer having a non-black color may be formed in a negative color, or may be formed in multiple colors on a pattern.
Furthermore, a colored layer having a non-black color may be partially formed depending on the case.

When the top layers 1 to 1 are formed in advance, they may be formed on the metal vapor deposited layer 2 using an appropriate resin.

The metal vapor deposited layer and the non-black colored layer are entirely O.
The thickness shall be Bm or less. Also, Anchor Court ItJ! -The total thickness, including the tube coat, shall be 6 μm or less. When the total thickness is 6 μm or less, good magnetic performance is maintained. If the overall thickness is thicker than 6 μn1, it will have a negative impact on the magnetic performance, making it more likely that magnetic recording and reading will not be possible, errors, errors in turnout, etc., and the overall J+ '
X is 10] J'J. from tm. Otherwise, the magnetic performance will be extremely poor.

In addition, in this invention, it is of course possible to perform appropriate processing on the side opposite to the magnetic layer side of the base material, such as by appropriately printing, coating with an appropriate resin, or combining these. Therefore, such a device is naturally included in the present invention.

Further, in this invention, as long as the magnetic performance is not adversely affected, appropriate printing may be performed on a colored layer having a non-black color, and such printing is naturally included in this invention.
Even if the printing on the colored layer is a bright colorful non-black color that does not have hiding properties, the underlying colored layer is a non-black color that provides hiding properties, so it is possible to print beautiful and clear colors. It will be printed.

For example, when printing barcodes, coloring, lf
Because fl has a bright and colorful non-black color,
There is no particular need to perform rectangular light reflection printing, for example white printing, on the area where the barcode is printed, and the black barcode may be printed directly on the colored layer.

(Example) Example 13111 A magnetic layer was formed on a vinyl chloride sheet of approximately 190 μm.
On the magnetic layer of the magnetic card, an anchor coat layer with a thickness of 0.5 mm is formed using an acrylic vinyl chloride resin, and on top of the anchor coat layer, a metal vapor deposition layer with a thickness of 450 mm is formed using AI. is formed by vacuum evaporation, and on top of the metal evaporation layer, a layer with a thickness of 0.5 μm is formed using acrylic resin.
A top coat layer was formed, and a colored layer having a non-black color made of vinyl chloride-vinyl acetate resin mixed with a white pigment was formed on the L-tub coat layer to a thickness of 3.0 μm. , a concealable magnetic card of this invention was obtained.

Example 2 Magnetic layer formed on a polyester sheet of about 200μ
An anchor coat layer with a thickness of 0.5 μm is formed using an acrylic vinyl chloride resin on the magnetic layer of a magnetic card of
On top of the anchor coat layer, Sn vapor deposition 344? An insulating gold FF vapor deposited layer having an island-like structure with a thickness of 300 people and having a light transmittance of 8% in the case of iL alone was formed by vacuum deposition, and on the insulating metal vapor deposited layer, A top coat layer with a thickness of 0.5 μm is formed using acrylic resin, and a non-black colored layer made of vinyl chloride-vinyl acetate resin mixed with yellow dye is applied on top of the top coat J1. A concealable magnetic card of the present invention was obtained by forming it to a thickness of 2 μm.

(Effects of the Invention) Since this invention is constructed as described above, it has the following effects.

(1) Since a metal evaporation layer and a non-black colored layer are sequentially formed on the magnetic layer, the non-black colored layer is hidden by the metal evaporation layer, making it beautiful and clear. It has a beautiful color.

(2) Furthermore, the I'J of the metal vapor deposited layer and the colored layer. Saga (
Since the total thickness (including the anchor coat layer and the 1-tube coat layer when they are formed) is less than 6 μm, the magnetic performance is maintained at a good level without adversely affecting the magnetic performance. It will be done.

3) When printing a barcode, since the colored layer is a bright and colorful non-black color, 5) Special rectangular light-reflecting printing, such as white printing, should be done on the area where the barcode will be printed. There is no need for this, and a black barcode can be printed directly on the colored layer.

(4) Since the metal vapor deposited layer and the non-black color R4 were formed on the magnetic layer, a transfer material was manufactured as in the case of using a transfer material. It is not necessary to transfer the image to the magnetic layer of the magnetic card, which is time-consuming and complicated, and there is no need to deform the base material due to the heat applied during transfer. The production efficiency is very high because it can be produced continuously in large quantities.

(5) Since a metal vapor deposition layer and a colored layer with a non-black color are formed on the magnetic layer, the surface becomes a bright and colorful colored layer with a non-black color, and at the same time,
The metal vapor-deposited layer reflects the light, so even if it is hit by the light, it absorbs the heat and is not deformed by the heat of the light. In this regard, the protective layer of the magnetic cards from LRJ absorbs a lot of heat when exposed to light, and the famous color JJ4, which has a blackish color, absorbs heat very badly, for example, if it is left in a car under the hot sun. It is fundamentally different from the one that threatened to transform.

(6) The colored layer has a bright and colorful non-black color, and the color is beautiful and clear, but the surrounding area is 11
, 1) It is easy to see even when it is dark, and when a fluorescent dye is used in a colored layer with a non-black color, the U
1.Easy to see when standing.In this respect, the colored layer of conventional magnetic cards is not noticeable in dark places and is difficult to see. This is fundamentally different from the time when he was having trouble locating his magnetic card.

(7) Since it is not a magnetic recording material that is used by laminating, jl,
There is no need for a li bonding step, the card can be used as a magnetic card as is, and the bonded recording bodies will not be separated by 7.11 degrees.

(8) When the gold rX vapor deposited layer is made insulating, does it have a negative effect on magnetic performance because it is difficult for static electricity to accumulate? In this point, if the metal vapor deposition layer is a normal metal vapor deposition M that has a metallic luster and is conductive, then the conductive metal vapor tj
Since the layer is sandwiched between insulating resin layers on both sides, static electricity is likely to accumulate, which adversely affects magnetic performance, resulting in the inability to record and read magnetic data, m1 differences, and input/output device malfunctions. , etc. may occur.

Claims (4)

[Claims] (1) A metal vapor-deposited layer is formed directly or via an anchor coat layer on the magnetic layer of a magnetic card comprising a base material and a magnetic layer formed on one side of the magnetic card, and the metal vapor-deposited layer is formed on the magnetic layer of the magnetic card. A colored layer with a non-black color is formed directly or via a top coat layer on top, and the thickness of the metal vapor deposited layer and the colored layer is (if there is an anchor coat layer or a top coat layer) A concealable magnetic card characterized in that the total thickness (including these) is 6 μm or less. (2) The concealable magnetic card according to claim 1, wherein the metal vapor deposition layer is an insulating metal vapor deposition layer. (3) A metal vapor deposition layer is formed directly or via an anchor coat layer on the magnetic layer of a magnetic card comprising a base material and a magnetic layer formed on one side of the magnetic card, and a metal vapor deposition layer is formed on the metal vapor deposition layer. , a non-black colored layer is formed directly or via a top coat layer, and the thickness of the metal vapor deposited layer and the colored layer is (
A method for manufacturing a concealable magnetic card, characterized in that the total thickness (including an anchor coat layer and a top coat layer, if any) is 6 μm or less. (4) The method for manufacturing a concealable magnetic card according to claim 3, wherein the metal vapor deposition layer is an insulating metal vapor deposition layer.