JP2021154596A - Color image laminate and method for manufacturing the same - Google Patents

Abstract

To provide a color image laminate which can be formed with a small-sized facility in a short time.SOLUTION: A color image laminate includes at least a first base material layer having a first hue layer formed by a laser beam of a first wavelength or first ink, and a second base material layer having a second hue layer that is laminated on the first base material layer and is formed by a laser beam of a second wavelength or second ink, and has a combined color image layer formed by overlapping the first hue layer and the second hue layer, in which either one of the first hue layer and the second hue layer is a black image, and the other is a reddish-brown image.SELECTED DRAWING: Figure 1

Description

The present invention relates to cards having a color image formed on a laminate having a laser color-developing sheet and a method for manufacturing the cards.

With the advent of the full-scale card era, various types of cards are used in daily life. For example, a card with specific information printed on the surface of a plastic base material, a magnetic card such as a telephone card, an IC card represented by a credit card with a built-in IC memory, or a data page with personal information printed on a plastic base material. Some of them have images such as facial photographs printed on them for the purpose of identification, such as passports using.

As a method of preventing such falsification of various cards, a method of laminating a transparent protective film on the surface of a sheet on which personal information is printed, a method of laminating a transparent overprint layer, or a face image by a laser on the sheet in the laminated body. There is a method of forming personal information such as.

As an example of forming personal information such as a face image by a laser, red is obtained by using a laser having a different wavelength of RGB for a drawing area made of polycarbonate containing a photosensitive black ink composed of a CMY pigment. A technique for selectively bleaching cyan for a laser, magenta for a green laser, and yellow for a blue laser to create an arbitrary color image is disclosed (see, for example, Patent Document 1).

Japanese Patent No. 5911803

However, the technique of Patent Document 1 requires three types of lasers that selectively bleach an image decomposed into each color component, so that it takes time to form a color image and the equipment becomes large, so that it is short. Time and small equipment was required.

The present invention solves the above problems and provides a color image laminate that can be formed in a short time by a small facility.

The present invention relates to a first substrate layer having a first color layer formed by a laser beam of a first wavelength or a first ink, and a second substrate layer laminated on the first substrate layer. A synthetic color image layer having at least a second base material layer having a second color layer formed by laser light or a second ink, and formed by superimposing the first color layer and the second color layer. The first color layer and the second color layer are color image laminates, characterized in that one of them is a blackish image and the other is a reddish brownish image.

Further, the present invention is a color image laminate characterized in that either one of the laser light having the first wavelength and the laser light having the second wavelength is in the ultraviolet region and the other is in the infrared region.

Further, the present invention is a method for producing a color image laminate, in which image data which is the basis of a synthetic color image layer is decomposed into a black component and a reddish brown component by an image processing device, and the black component is the first. Based on the process of creating one color data and the second color data of the reddish brown component, and the first color data or the second color data, the first ink or the first wavelength is applied to the first base material layer. A step of producing a first color layer by the laser beam of the above, and a second base material layer that is superimposed on the first color layer of the second base material layer by the second color data or the first color data. It is a method for producing a color image laminate, which comprises at least a step of producing a second color layer and producing a synthetic color image layer at a position.

Since the present invention only needs to decompose the color component into two types, black and reddish brown, it is possible to provide a color image laminate that can be formed in a short time by a small facility.

FIG. 6 is an example diagram showing a color image laminate of the present invention. FIG. 3 is an example diagram showing a first color layer of the color image laminate of the present invention. FIG. 6 is an example diagram showing a second color layer of the color image laminate of the present invention. FIG. 6 is an example diagram showing a composite color image layer of the color image laminate of the present invention. FIG. 3 is an example diagram showing the creation of a composite color image layer of the color image laminate of the present invention. FIG. 3 is an example diagram showing the creation of a composite color image layer of the color image laminate of the present invention. The flow chart of the manufacturing method of the color image laminate of this invention. FIG. 6 is an example diagram showing another form of the color image laminate of the present invention. FIG. 6 is an example diagram showing another form of the color image laminate of the present invention.

A mode for carrying out the present invention will be described with reference to the drawings. However, the present invention is not limited to the embodiments described below, and includes various other embodiments as long as it is within the scope of the technical idea in the claims.

(First Embodiment)
(Color image laminate)
FIG. 1 shows a color image laminate (A1) of the present invention. The first embodiment is an example in which the color image laminate (A1) is formed as a card. FIG. 1A is a plan view of a color image laminate (A1) provided with a composite color image layer (1), and FIG. 1B is a cross-sectional view taken along the line AA'of the color image laminate (A1). be. As shown in FIG. 1 (b), the color image laminate (A1) has a first color layer (3) formed on the first base material layer (2) and a first base material layer (2). ) Has a second color layer (5) formed on a second base material layer (4) that is welded and laminated by thermocompression bonding, and has a first color layer (3) and a second color. The layer (5) is superposed.

The method of welding the second base material layer (4) onto the first base material layer (2) by thermocompression bonding is the same as that in the production of a known thermosetting resin plate or the like. Specifically, a smooth metal plate made of metal such as duralmin or stainless steel is used, and the temperature of the metal plate is equal to or higher than the softening point of the thermoplastic resin forming the second base material layer (4) by the heat plate. It is heated to about 100 to 200 ° C., and ^{a pressure of about 10 to 200 kgf / cm 2} is applied for a period of time according to the melting characteristics of the thermoplastic resin, and a second group is applied onto the first base material layer (2). The material layer (4) is laminated by heat welding.

(First base material layer)
The first base material layer (2) is a thermoplastic resin layer having absorption characteristics at the first wavelength, which is an ultraviolet region of 350 to 370 nm or an infrared region of 700 nm to 1300 nm, or an ink having absorption characteristics at the first wavelength. The layer is formed on the above-mentioned thermoplastic resin layer having no absorption property at the first wavelength.

Known thermal resins such as polycarbonate (PC) or polyethylene terephthalate glycol (PETG), polyvinyl chloride (PVC), and acrylonitrile-butagen-styrene copolymer resin (ABS resin) are examples of the thermoplastic resin layer having absorption characteristics in the ultraviolet region. A plastic resin sheet can be used. The ink layer is formed by applying an ink obtained by dispersing powders or pigments such as zinc oxide, titanium oxide compound, and cerium oxide in varnish or the like to the thermoplastic resin layer by screen printing, gravure printing, intaglio printing, inkjet printing, or the like. The ones that have been printed can be mentioned.

As the thermoplastic resin layer having absorption characteristics in the infrared region, a known infrared color-developing sheet containing carbon such as an infrared laser color-developing sheet can be used. The ink layer, diphosphorus pentoxide and (P 2 _{O 5)} as a main component, iron oxide, any or ink glass-based powders or the like, or a pigment dispersed in the varnish or the like containing both screen printing copper oxide , The one formed by applying to the thermoplastic resin layer by gravure printing, intaglio printing, or the like.

The color of the first base material layer (2) is not particularly limited as long as it does not affect the color development property of the first color layer (3) described later, and may be transparent, white or other colored colors. good. For example, when considering the color development property due to ultraviolet absorption, it contains a resin sheet such as white polycarbonate (PC) containing titanium dioxide (white titanium), which is one of the titanium oxide compounds, and titanium dioxide (white titanium). White ink is preferred. Further, when considering the color development property due to infrared absorption, an IR (infrared) laser color development sheet containing carbon is preferable.

(First color layer)
FIG. 2 shows a plan view and a cross-sectional view of the first color layer (3) formed on the first base material layer (2). In FIG. 2B, a white polycarbonate containing titanium dioxide (white titanium) as the first base material layer (2) is irradiated with an ultraviolet laser (hereinafter referred to as “UV laser”) as the first wavelength. This is an example in which the first black color layer (3) is formed on a part of the surface layer of the first base material layer (2).

The first color layer (3) is continuously formed from the surface layer to the lower layer as shown in FIG. 2 (c) by adjusting the focus of the UV laser, and the lower layer or the figure as shown in FIG. 2 (d). As shown in 2 (e), it may be formed in the middle. Alternatively, as shown in FIG. 2 (f), the first color layer (3) may be formed on the first base material layer (2) with a known black ink or reddish brown ink.

Although an example in which the first color layer (3) is formed by a UV laser has been described, even when the first color layer (3) is formed by an infrared laser (hereinafter referred to as “IR laser”), the first color layer (3) has absorption characteristics in the infrared region. It is similarly formed on the base material layer (2).

The color of the first color layer (3) is blackish or reddish brownish. The blackish color may be any blackish hue, and includes not only black but also hues such as gray close to black and brown close to black. The reddish-brown color may be any reddish-brown hue, and includes warm hues such as orange and brown. The color of the first color layer (3) is formed by irradiating a resin sheet with a UV laser or an IR laser to develop a black or reddish brown color, or by using a known black ink or reddish brown ink. ..

(Second base material layer)
FIG. 3 shows a plan view and a cross-sectional view of the second color layer (5) formed on the second base material layer (4). The second base material layer (4) is a transparent thermoplastic resin layer having absorption characteristics in a second wavelength in an infrared region of 700 nm to 1300 nm or an ultraviolet region of 350 to 370 nm, or an absorption characteristic in a second wavelength. A transparent ink layer having the above-mentioned is formed on a transparent thermoplastic resin layer having no absorption characteristic at the above-mentioned second wavelength. The second base material layer (4) is required to be transparent in the first color layer (3) and the second base material layer (4) formed in the first base material layer (1). This is because the formed second color layer (5) is superposed so that it can be visually recognized.

The second base material layer (4) is not particularly limited as long as it is a transparent thermoplastic resin layer, and is formed by laminating a single layer or a plurality of thermoplastic resin layers. As the transparent thermoplastic resin layer, a known thermoplastic resin sheet such as polycarbonate (PC) or polyethylene terephthalate glycol (PETG), polyvinyl chloride (PVC), acrylonitrile-butagen-styrene copolymer resin (ABS resin) is used. Can be used. As the ink layer, a transparent ink in which known ultraviolet absorptions of triazine type, oxalic acid anilide type, cyanoacrylate type, salicylate type, and benzophenone type are dispersed in a varnish or the like is thermoplastic by screen printing, gravure printing, intaglio printing, or the like. Examples thereof include those formed by being applied to a resin layer.

As the thermoplastic resin layer having absorption characteristics in the infrared region, a known infrared color-developing sheet having transparency can be used. In addition, as the ink layer, an ink _{containing diphosphorium pentoxide (P 2} O ₅ ) as a main component and containing either or both of iron oxide and copper oxide, or a glass powder or the like in which a pigment is dispersed in a varnish or the like is used. Examples thereof include those formed by applying to a thermoplastic resin layer by screen printing, gravure printing, intaglio printing, or the like.

(Second color layer)
The second color layer (5) is formed by irradiating a transparent laser color-developing sheet as the second base material layer (4) with an IR laser. In FIG. 3B, a transparent laser coloring sheet as the second base material layer (4) is irradiated with an IR laser, and the reddish brown second color layer (5) is used as the second base material. This is an example in which the layer (4) is continuously formed from the surface layer to the lower layer.

The second color layer (5) is a surface layer as shown in FIG. 3 (c), a lower layer as shown in FIG. 3 (d), or a lower layer as shown in FIG. 3 (e) by adjusting the focus of the IR laser. May be formed in the middle. Alternatively, as shown in FIG. 3 (f), the second color layer (5) may be formed on the second base material layer (4) with a known black ink or reddish brown ink.

The color of the second color layer (5) is blackish or reddish brown like the first color layer (3), but when the color of the first color layer (3) is blackish, When the color of the second color layer (5) is reddish brown and the color of the first color layer (3) is reddish brown, the color of the second color layer (5) is black. The color of the second color layer (5) is made to develop a blackish or reddish brownish color by irradiating the laser coloring sheet with an IR laser, or a black ink or red known on the second base material layer (4). It is formed by brown ink.

An example of forming the second color layer (5) by an IR laser has been described, but when it is formed by a UV laser, it is similarly formed on the second base material layer (4) having absorption characteristics in the ultraviolet region. Will be done.

(Composite color image layer)
As shown in FIG. 4, the synthetic color image layer (1) is formed on the first color layer (3) formed on the first base material layer (2) and on the second base material layer (4). The second color layer (5) is laminated. In the present embodiment, the first color layer (3) and the second color layer (5) are superimposed, but some of them may be formed close to each other or adjacent to each other. Proximity and adjacency mean that one end of the first color layer (3) and the second color layer (5) are in contact with each other, and the first color layer (3) and the second color layer (5) are adjacent to each other. Those that do not touch one end of the are called proximity. In the composite color image layer (1), one of the colors of the first color layer (3) and the second color layer (5) is formed in black and the other is reddish brown. .. This is because if one of the colors is reddish-brown, the human skin color can be reproduced.

In the production of the synthetic color image layer (1), as shown in FIG. 5 (a), the second base material layer (4) is laminated on the first base material layer (2) by thermocompression bonding or adhesion. Later, as shown in FIG. 5 (b), the first color layer (3) is focused on the first base material layer (2) as a laser beam (6) of the first wavelength by a UV laser or an IR laser. To form. Next, as shown in FIG. 5 (c), the second color layer (4) is focused on the IR laser or the UV laser as the laser light (7) of the second wavelength. 5) is superimposed and formed. In this case, it is necessary to superimpose the two color layers in a positional relationship in which the first color layer (3) and the second color layer (5) match.

Alternatively, after forming the first color layer (3) on the first base material layer (2) by printing in advance, the second base material layer (4) is laminated on the first base material layer (2). After that, the second base material layer (4) may be formed by irradiating the second base material layer (4) with an IR laser or a UV laser as the laser light (7) of the second wavelength to superimpose the second color layer (5). good. Alternatively, after laminating the second base material layer (4) on which the second color layer (5) is formed in advance by printing on the first base material layer (2), the laser light of the first wavelength (1). The first color layer (3) may be formed by 6).

Specifically, as shown in FIG. 6A, the image data (9), which is the base image, is decomposed into a black component and a reddish brown component by an image processing device, and the first color data of the black component ( 10) and the second color data (11) of the reddish-brown component are created. In FIG. 6 (a), the first color data (10) of the black component and the second color data (11) of the reddish brown component have the same shape, but as shown in FIG. 6 (b), they have the same shape. The first color data (10) of the black component and the second color data (11) of the reddish brown component do not have the same shape and do not have to completely overlap.

Next, as shown in FIG. 6 (c), the first color data (10) created is applied to the first base material layer (2) by laser light (6) of the first wavelength or printing. The second color layer (3) and the second base material layer (4) are subjected to the laser light (7) of the second wavelength or the second color layer (5) by printing according to the second color data (11). The composite color image layer (1) can be created by forming the composite color image layer (1) in the same region that overlaps with one color layer (3).

Alternatively, according to the created first color data (10), a second wavelength laser beam (7) is applied to the second base material layer (4), or a second black color layer (5) is printed. A synthetic color image layer by forming a first color layer (3) on a first base material layer (2) by a second color data (11) or a laser beam (6) of a first wavelength by printing. (1) may be created (not shown).

(Manufacturing method)
Next, a method for producing the color image laminate (A1) will be described with reference to FIG. The method for producing the color image laminate (A1) of the present invention is a step of producing a color data (S1), a step of producing a first color layer (S2), and a step of producing a synthetic color image layer (1). It has at least (S2).

(Color data creation process)
In the color data creation step (S1), the image data (9), which is the base image forming the composite color image layer (1), is decomposed into a black component and a reddish brown component by an image processing device, and the black component is used. The first color data (10) and the second color data (11) of the reddish-brown component are created. In this specification, a face image is used as the base image of the image data (9), but the base image is not particularly limited, and characters, numbers, symbols, patterns, landscapes, portraits, etc. with gradation are used. be able to.

(Step of producing the first color layer (S2))
In the step (S2) of producing the first color layer, the first base material layer (2) is subjected to the first color data (10) or the second color data (11), and the first base material layer (2) is in the infrared region or the ultraviolet region. A black or reddish brown first color layer (3) is prepared by irradiating or printing a laser beam (6) having one wavelength. When the first color layer (3) is produced by the laser light (6) of the first wavelength, the second base material layer (4) is laminated on the first base material layer (2) by heat welding. After that, the first base material layer (2) is focused on the laser beam having the first wavelength to prepare the first color layer (3).

As the laser light (6) having the first wavelength, a known laser can be used as long as the first base material layer (2) is colored. For example, as the laser in the infrared region, for example, a CO2 laser, a fiber laser, a YAG laser, a near infrared laser, a semiconductor laser or the like can be used. Further, the laser may be a laser array or the like in which a plurality of laser light emitting elements are bundled. Further, as the laser in the ultraviolet region, a semiconductor laser can be used.

The average output P (unit: W) of the light source of the laser beam (6) of the first wavelength is not particularly limited, but is, for example, 0.5 to 30 W, preferably 1 to 20 W. The average output P can be set by the output% of the laser output condition. For example, in a laser with a maximum output of 30 W, if the output is set to 30%, the average output P becomes 9 W. By setting the value within this numerical range, it becomes easy to achieve both the color density and the production cost. When the light source of the laser beam (6) having the first wavelength is a pulse laser, the repetition frequency is not particularly limited, but is 5 to 50 kHz, more preferably 10 to 30 kHz. By setting the value within this numerical range, it becomes easy to achieve both the print density and the production cost.

The speed at which the first color layer (3) is produced may be appropriately adjusted depending on the productivity, the desired color development density, and the like. For example, the moving speed of the laser spot is 0.5 to 10 m / s, preferably 1 to 6 m / s. Within this numerical range, it becomes easier to achieve both industrial productivity (drawing speed) and improvement of color density.

When the first color layer (3) is produced by the first ink, the first known black ink or reddish brown ink is offset printed, and the first printing method such as IJP is used in advance. After printing and forming on the base material layer (2), the second base material layer (4) is laminated on the first base material layer (2) by heat welding.

(Step of producing a composite color image layer)
In the step (S3) of producing the synthetic color image layer (1), a laser beam (7) having a second wavelength in the ultraviolet region or an infrared region is used as the second wavelength in the second base material layer (4). At a position where the reddish brown or black second color layer (5) is superimposed on the first color layer (3) by focusing the laser beam (7) of the second wavelength and irradiating or printing. Form. It should be noted that preferably, one of the laser light (7) having the second wavelength and the laser light (6) having the first wavelength is in the ultraviolet region and the other is in the infrared region.

When the second color layer (5) is produced by the laser light (7) of the second wavelength, the second color layer (3) is formed on the first base material layer (2). After laminating the base material layer (4) of the above by heat welding, the second base material layer (4) is focused on the laser beam (7) of the second wavelength to prepare the second color layer (5). do. As the laser light (7) of the second wavelength, a known laser can be used as long as the second base material layer (4) is colored. For example, a semiconductor laser can be used as the laser in the ultraviolet region. As the laser in the infrared region, for example, a CO2 laser, a fiber laser, a YAG laser, a near infrared laser, a semiconductor laser and the like can be used. Further, the laser may be a laser array or the like in which a plurality of laser light emitting elements are bundled.

The second color layer (5) formed by the laser light (7) of the second wavelength is a blackish or reddish brownth layer formed in the step (S2) of producing the first color layer (3). Since it is paired with the one color layer (3), the second color layer (5) is formed of a reddish brown system or a black system. That is, when the first color layer (3) is blackish, the second color layer (5) is formed by reddish brownish colors. When the first color layer (3) is reddish brown, the second color layer (5) is formed by blackish colors.

The output, irradiation speed, and printing conditions of the laser beam (7) of the second wavelength are the same as those for forming the first color layer (3), and are therefore omitted.

When the second color layer (5) is formed by the second ink, it is heat-bonded and laminated on the first base material layer (2) on which the first color layer (3) is formed. A known reddish-brown ink or black-based ink is formed on the second base material layer (4) at a position where it overlaps with the first color layer (3) by using a known printing method such as offset printing or IJP. Will be done.

Therefore, the color image laminate (A1) of the present invention decomposes the color components into two types, black and reddish brown, and forms each color layer into a different thermoplastic resin layer to form a color image laminate (A1). It is possible to prevent forgery and falsification of personal information, etc. given to A1).

(Second embodiment)
Next, as shown in FIG. 8, as a second embodiment, the transparent intermediate layer (8) is laminated between the first base material layer (2') and the second base material layer (4'). A color image laminate (A2) having a configuration in which the composite color image layer (1') is three-dimensionally visible by the parallax barrier method will be described. For convenience of explanation, the parts that overlap with the first embodiment will be omitted, and only the different parts will be described.

As shown in FIGS. 8 (a) and 8 (b), the color image laminate (A2) of the second embodiment has a first color layer (3') and a second color layer (5'). Are the same pattern, and at least a part of them are laminated, and the second color layer (5') is formed by shifting the distance (T) with respect to the center of the first color layer (3'). When a person observes under the observation conditions that one eye visually recognizes the positively reflected light and the other eye visually recognizes the diffusely reflected light, the first color layer (3') and the second color layer are observed. A stereoscopic image can be visually recognized by (5').

Further, in FIG. 8A, for convenience of explanation of the invention, the first color layer (3') is shown by a dotted line in order to clarify the shifted distance (T), but in reality, the shifted distance is shown. Since (T) is small, it is visually recognized as one composite color image layer (1') synthesized by the first color layer (3') and the second color layer (5'). The distance (T) will be described later.

Next, with reference to FIG. 9, the relationship between the shifted distances (T) of the first color layer (3') and the second color layer (5') will be described. As shown in FIG. 9, the second color layer (5') is based on the center (P1) of the first color layer (3') formed on the first base material layer (2'). The distance (T) of the center (P2) of the second color layer (5') is shifted to form the second base material layer (4'), or the first color layer (3) is not shown. ´) and the second color layer (5 ′) are formed by shifting the arrangement pitch by a distance (T).

From the principle of the parallax barrier method, the shift distance (T) between the first color layer (3') and the second color layer (5') depends on the thickness of the transparent intermediate layer (8), but is from 1 mm. Stereoscopic viewing is possible by shifting by 3 mm, and the shift distance (T) may be adjusted according to a desired sense of depth. When the shift distance (T) is less than 1 mm, the change in the composite color image layer (1) is small, which makes it difficult to stereoscopically view the composite color image layer (1). If it exceeds 3 mm, the visibility of the composite color image layer (1) is lowered.

The transparent intermediate layer (8) is not particularly limited as long as it is a transparent thermoplastic resin layer, and is formed by laminating a single layer or a plurality of thermoplastic resin layers. Examples of the thermoplastic resin layer forming the transparent intermediate layer (8) include polycarbonate (PC), polyethylene terephthalate glycol (PETG), polyvinyl chloride (PVC), acrylonitrile-butagen-styrene copolymer resin (ABS resin), and the like. A known thermoplastic resin sheet can be used.

Examples of the present invention will be described with reference to the same manner as in the above-described embodiments. The contents of the present invention are not limited to the scope of these examples.

(Example 1)
In Example 1, as a manufacturing example, the color image laminate (A1) shown in FIG. 1 is used as an IR laser coloring sheet for the first base material layer (2) and a transparent resin sheet for the second base material layer (4). It is formed by laminating.

In order to form the composite color image layer (1), as shown in FIG. 6A, the image data (9), which is a human image of the base image, is decomposed into a black component and a reddish brown component by an image processing device. The first color data (10) of the black component and the second color data (11) of the reddish brown component were created.

The first base material layer (2) uses a transparent laser color-developing sheet (thickness 0.40 mm, dimensions 300 mm (length) x 100 mm (horizontal)) as the IR laser color-developing sheet, and is a second base material. As the layer (4), transparent polycarbonate (PC: trade name "WC-020", thickness 0.10 mm: manufactured by Mitsubishi Gas Chemical Company, dimensions 300 mm (length) x 100 mm (width)) was used as the transparent resin sheet. ..

Next, as shown in FIG. 5A, the second base material layer (4) is laminated on the first base material layer (2), and an SD type molding press machine (“SDOP” manufactured by Dumbbell Co., Ltd.) −1042-2HC-AT-WC1V-PG3 ”) was used to perform thermocompression bonding from 160 ° C to 185 ° C for 30 seconds at a mechanical setting of 2.5 MPa, and after heat welding, it was cooled to 50 ° C. ..

Next, as shown in FIG. 5 (b), an IR laser having a wavelength of 1064 nm (Keyence laser marker (3Axis YVO ₄ LaserMarker MD-V9900)) is used as the laser light (6) of the first wavelength, and the color is black. A black-based first color layer (3) was prepared on the first base material layer (2) based on the first color data (10) of the system components.

Next, on the second base material layer (4), an inkjet printer and a dry offset printing machine (ultraviolet curable dry offset red ink (DIC Graphic Co., Ltd .: Dicure RTX ink)) are used, respectively, to produce a reddish brown color. A composite color image layer (1) is produced by printing a reddish-brown second color layer (5) at a position overlapping the first color layer (3) based on the second color data (11) of the components. A color image laminate (A1) was formed.

(Example 2)
In the second embodiment, a white polycarbonate containing titanium dioxide (white titanium) is used as the first base material layer (2) of the first embodiment, and the wavelength of 355 nm is used as the laser light (6) of the first wavelength. A black-based first color layer (3) was prepared on the first base material layer (2) from the first color data (10) of the black-based component using the UV laser of. Others have the same configuration as in Example 1.

When the composite color image layer (1) of Example 1 and Example 2 was observed, a person in whom the black-based first color layer (3) and the reddish-brown second color layer (5) were synthesized was observed. I was able to confirm the portrait by skin color.

A1, A2 color image laminate 1, 1'synthetic color image layer 2, 2'first base material layer 3, 3'first color layer 4, 4'second base material layer 5, 5'second Color layer 6 Laser light of the first wavelength 7 Laser light of the second wavelength 8 Transparent intermediate layer 9 Image data 10 First color data 11 Second color data

Claims (3)

A first substrate layer having a first color layer formed by a first wavelength laser beam or a first ink, and a second wavelength laser beam laminated on the first substrate layer or A synthetic color image layer having at least a second base material layer having a second color layer formed by a second ink and formed by superimposing the first color layer and the second color layer. Have and
A color image laminate characterized in that one of the first color layer and the second color layer is a blackish image and the other is a reddish brownish image. The color image laminate according to claim 1, wherein either one of the laser light having the first wavelength and the laser light having the second wavelength is in the ultraviolet region and the other is in the infrared region. The method for producing a color image laminate according to claim 1 or 2.
The image data that is the basis of the composite color image layer is decomposed into a black component and a reddish brown component by an image processing device, and the first color data of the black component and the second color data of the reddish brown component are obtained. The process of creating and
A step of producing the first color layer on the first base material layer with the first ink or the laser light of the first wavelength based on the first color data or the second color data.
Based on the second color data or the first color data, the second color layer is placed at a position where the first color layer and the second base material layer of the first base material layer overlap. A method for producing a color image laminate, which comprises at least a step of producing and producing the synthetic color image layer.

Images