JP2000033782A - Transfer sheet, manufacture thereof and transfer method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transfer sheet which can be manufactured efficiently and is free from the impairing of the image quality of a transfer image as well as a method for manufacturing the transfer sheet and a transfer method. SOLUTION: The transfer sheet 10 has two sets each of transfer regions 12Y, 12M, 12C of different colors arranged as a fixed repeating unit, formed alternately with a detection mark formed for each transfer region and different marks imparted to each of the groups. Two sets of the transfer regions 12Y, 12M, 12C are printed by plural transfer layer printing cylinders 101, 102, 103, each of which has a plate part for a different transfer region in a multiface insetting fashion, and different detection marks 13a, 13b for the two sets are printed using a single detection mark printing cylinder 104. The detection marks 13a, 13b have recorded information on the positional relationship between the sets. Further an image is transferred by correcting the printing characteristics of the heat transfer layer per set based on the detection marks 13a, 13b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transfer sheet suitably used for an ink ribbon or the like of a thermal transfer printer, a method for manufacturing the same, and a transfer method.

[0002]

2. Description of the Related Art FIG. 2 is a schematic view showing a conventional transfer sheet and a method for manufacturing the same. In the case of an ink ribbon (see Japanese Patent Publication No. 6-96307) as an example, this type of transfer sheet 20 includes a belt-shaped ribbon (base sheet) 21 and a plurality of ribbons provided at different positions in the longitudinal direction of the ribbon. The color (yellow, magenta, cyan) ink area (thermal transfer layer) 22 (22Y, 22M, 22C) and the ink area provided at the end of the ink area of the ribbon at right angles to the longitudinal direction of the ribbon Lines (detection marks) 23 having different numbers of colors are provided.

[0005] The transfer sheet 20 is manufactured by a method such as gravure printing using printing cylinders 201 to 204 having a circumference three times the length of the transfer layer 22. First, the yellow (Y) printing cylinder 201 prints the Y transfer area 22Y, and then the magenta (M) printing cylinder 202 prints the M transfer area 22Y.
M is printed, and a cyan (C) printing cylinder 203 prints C
The transfer area 22C is printed. Finally, the detection mark 23 is printed at a time by the mark printing cylinder 204.

[0004]

In the above-mentioned conventional method for manufacturing a transfer sheet, the transfer layer is set to one for each YMC printing cylinder.
Since printing was performed one by one, there was a problem that production efficiency was poor. For this purpose, it is conceivable to provide a plurality of plate portions of the transfer layer on the same printing cylinder (multiple printing) and print.
However, when a plurality of plate portions are formed on the same printing cylinder, the thickness and the like of the manufactured transfer layer slightly differ due to a manufacturing error of each plate portion. When printing on a printer using the formed film, there was a problem that a difference in hue occurred. In particular, when a sublimation transfer method capable of transferring a full-color image is used, there is a possibility that the gray hue varies from highlight to halftone for each screen. An object of the present invention is to provide a transfer sheet having good production efficiency and not impairing the image quality of a transferred image and a method of manufacturing the same.
The purpose is to provide a transfer method.

[0005]

According to a first aspect of the present invention, a plurality of sets in which a plurality of transfer regions of different functions are arranged in a constant repeating unit are formed. In a transfer sheet on which a detection mark is formed for at least one area of the transfer area or for each set of the transfer area, the pattern of the detection mark for each set is at least two or more types. Transfer sheet.

According to a second aspect of the present invention, in the transfer sheet according to the first aspect, the detection marks are formed by different plate portions on the same printing cylinder, and are different for each of the transfer areas. It is.

According to a third aspect of the present invention, in the transfer sheet according to the second aspect, the detection marks are formed by different plate portions on the same printing cylinder, and information on the position of the transfer area is recorded. This is a transfer sheet characterized by the following.

According to a fourth aspect of the present invention, a plurality of sets in which a plurality of transfer areas having different functions are arranged in a fixed repeating unit are formed, and at least one of the transfer areas is provided or the transfer area is provided. In a transfer sheet on which a detection mark is formed for each set of regions, the detection marks of each set are
A transfer sheet characterized by a pattern having the same shape in appearance, wherein at least one of the detection marks in each transfer area included in an arbitrary set has different characteristics from other detection marks.

According to a fifth aspect of the present invention, there is provided a transfer sheet in which a plurality of sets in which a plurality of transfer areas of different functions are arranged in a fixed repeating unit are formed, and a detection mark is formed for each set of the transfer areas. In the above, the detection mark of each set
A transfer sheet having the same shape in appearance, wherein the characteristics of at least one set of detection marks are different from the characteristics of another set of detection marks.

The invention of claim 6 is the invention of claim 4 or claim 5.
Wherein the detection mark has a different transmittance or reflectance from an optical sensor used to read the detection mark.

According to a seventh aspect of the present invention, in the transfer sheet according to the sixth aspect, with respect to the detection marks having different transmittances or reflectances, a difference in transmittance or reflectance is in a visible region (4).
00 nm to 700 nm).
0% or less of the transfer sheet. According to an eighth aspect of the present invention, in the transfer sheet according to the sixth aspect, with respect to the detection marks having different transmittances or reflectances, the detection mark having a higher transmittance or reflectance has a thickness of 800 nm.
When the transmittance or the reflectance is measured at any wavelength of from 950 nm to 950 nm, a detection mark having a transmittance or a reflectance of 1% or more and 10% or less and a transmittance or a reflectance of 800 nm is low.
A transfer sheet having a transmittance or reflectance of 1% or less at any wavelength of from 950 nm to 950 nm.

According to a ninth aspect of the present invention, there is provided an image processing apparatus comprising:
5. The transfer sheet according to claim 1, wherein the detection marks are formed by different plate portions on the same printing cylinder, and are different for each of the transfer areas.

According to a tenth aspect of the present invention, in the transfer sheet according to the ninth aspect, the detection marks are formed by different plate portions on the same printing cylinder, and information on a position of the transfer area is recorded. This is a transfer sheet characterized by the following.

According to an eleventh aspect of the present invention, a plurality of sets in which a plurality of transfer regions having different functions are arranged in a constant repeating unit are formed, and at least one of the transfer regions is provided or the transfer region is provided. In the method of manufacturing a transfer sheet for manufacturing a transfer sheet on which a detection mark is formed for each set of areas, the transfer areas are printed by a plurality of transfer layer printing cylinders each having a plurality of printing plates of the different transfer areas. Printing a plurality of sets, among the plurality of sets of the repeating units,
A method for manufacturing a transfer sheet, wherein at least one detection mark including a non-identical mark is printed by one detection mark printing cylinder.

According to a twelfth aspect of the present invention, a plurality of sets in which a plurality of transfer regions having different functions are arranged in a fixed repeating unit are formed, and at least one of the transfer regions or at least one of the transfer regions is formed. In the method of manufacturing a transfer sheet for manufacturing a transfer sheet on which a detection mark is formed for each set of areas, the transfer areas are printed by a plurality of transfer layer printing cylinders each having a plurality of printing plates of the different transfer areas. Printing a plurality of sets, among the plurality of sets of the repeating units,
It is a pattern having the same shape in appearance, and at least one of the detection marks of each transfer area included in an arbitrary set is printed by one detection mark printing cylinder having characteristics different from those of the other detection marks. This is a method for producing a transfer sheet.

According to a thirteenth aspect of the present invention, there is provided a transfer sheet wherein a plurality of sets in which a plurality of transfer areas having different functions are arranged in a fixed repeating unit are formed, and a detection mark is formed for each set of the transfer areas. In the method of manufacturing a transfer sheet, a plurality of sets of the transfer areas are printed by a plurality of transfer layer printing cylinders on which the plate portions of the different transfer areas are multi-faced, and the plurality of sets of the repeating units are printed. so,
A method for manufacturing a transfer sheet, characterized in that printing is performed with one detection mark printing cylinder having the same shape in appearance and the characteristics of at least one set of detection marks are different from the characteristics of another set of detection marks. .

According to a fourteenth aspect of the present invention, in the transfer method using the transfer sheet according to any one of the first to tenth aspects, information on a positional relationship between the sets is recorded on the transfer sheet. A transfer method characterized in that a detection mark is formed in advance, and the characteristics of each set are corrected and transferred based on the detection mark.

[0018]

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
An embodiment of the present invention will be described in more detail. (First Embodiment) FIG. 1 is a schematic diagram showing a first embodiment of a transfer sheet and a method for manufacturing the same according to the present invention. The transfer sheet 10 of this embodiment is, as shown in the lower side of FIG.
Base sheet 11, thermal transfer layer 12, detection mark 13
(13a, 13b) and the like.

The base sheet 11 serves as a carrier of the transfer sheet 10 and may have a predetermined heat resistance and strength. For example, paper, a plastic sheet such as PET,
Metal foil or the like can be used. Its thickness is 0.
It is 5 to 50 μm, preferably 3 to 10 μm.

The thermal transfer layer 12 is formed on the base sheet 11 and has a transfer area 1 for each color of yellow, magenta and cyan.
One set is formed in the order of 2Y, 12M, 12C,
Each set is provided in plurality in the longitudinal direction. Thermal transfer layer 12
Is a layer made of a resin containing a dye that migrates by melting or sublimation by heating, and the dye is preferably a heat-sublimable disperse dye, an oily dye, or a basic dye, and has a molecular weight of Is from 150 to 800, preferably
310 to 700. From among these, it is selected in consideration of the thermal sublimation temperature, hue, weather resistance, solubility in the ink composition or in the binder, and the like. The thermal transfer layer 12 is formed by dissolving the selected dye together with a resin using a solvent to form an ink composition, and then printing it to a thickness of 0.3 to 2 μm by an appropriate printing method such as gravure printing.

The detection mark 13 is a mark for detecting information on the thermal transfer sheet 10 and may be made of any material as long as the presence of the mark can be confirmed by optical, electric or magnetic detection means. It may be formed. Information on the thermal transfer sheet 10 includes, for example, the distinction between the front and back of the thermal transfer sheet 10, the recording start position, the distinction (direction) between the head and the tail, the type, the grade, the number of frames that can be printed on one thermal transfer sheet, the end notice, and each color. Of the thermal transfer layer, or the name of the manufacturer, the version of the printer, and the determination as to whether or not the product is genuine.

The detection mark 13 is, for example, a mark made of a composition containing a pigment or a dye which can be distinguished by a light source to be used in relation to the detection means and which is optically detected, or a metal powder. A mark made of a conductive resin or metal foil containing carbon or carbon in the resin and electrically detected, a magnetic composition containing a magnetic metal or a compound or a mark formed by a deposited film of a magnetic metal and a magnetic mark , Etc. to be detected. As the detecting means, any means can be used, but those which can be simplified as a device are means for optically detecting.

When the thermal transfer layer 12 of each color and the detection mark 13 overlap in the same area and the dye or pigment in the detection mark 13 has a general hue, it is necessary to use an appropriate color filter. Is the thermal transfer layer 12
If a dye in the infrared transmission is selected as the dye therein and the detection mark 13 is detected by infrared rays as a mark for shielding the infrared rays, detection can be performed regardless of the hue of the thermal transfer layer 12.

The infrared light-shielding mark can be formed by a composition containing an infrared light-shielding substance in a resin, and the most suitable infrared light-shielding substance is carbon black which absorbs infrared rays most easily. As the resin containing the infrared ray shielding material, polyurethane resin, polyamide resin, vinyl chloride / vinyl acetate copolymer resin, or vinyl chloride / acrylic copolymer resin, cellulose acetate butyrate, and the like are suitable. They can be used alone or as a mixture. These resins may be further crosslinked with a polyisocyanate compound.

When an infrared light-shielding substance is used, the weight ratio of the infrared light-shielding substance to the resin in the detection mark is 1/10 to 10/1, and the thickness is
It is about 0.5 to 5 μm. The configuration of the device for detecting the infrared light shielding detection mark 13 is, for example, an infrared projector such as an infrared light emitting diode disposed on one surface of the running thermal transfer sheet 10, an infrared sensor, and the other of the thermal transfer sheet 10. It comprises a reflector disposed on the surface and a computer connected to the infrared sensor, and instructs the printer to perform various operations based on signals from the infrared sensor.

The wavelength is 900 to 2500 nm, especially 900
If an infrared projector capable of emitting infrared rays of ~ 1000 nm and an infrared sensor sensitive to the same wavelength range are used, the dye in the thermal transfer layer 12 does not absorb infrared rays in this wavelength range. The infrared rays penetrate through the thermal transfer layer 12, and the detection efficiency of the infrared light shielding detection mark 13 can be increased. Therefore, as the dye in the thermal transfer layer 12, it is preferable to select and use a dye that substantially transmits infrared light having a wavelength within the above range. The detailed composition of each part of such a thermal transfer sheet is disclosed in Japanese Patent Application Laid-Open No. 1-220491 proposed by the present applicant, and a detailed description thereof will be omitted.

In this embodiment, as shown in the right end of FIG. 1, different detection marks 13a and 13b are printed for each set of YMC.

Next, the transfer sheet 10 according to this embodiment will be described.
Will be described. In this embodiment, each of the YMC printing cylinders 101, 102, and 103 has a circumference that is six times the length of the transfer layer 12, and each of the YMC transfer layers 12
Two plate portions of Y, 12M, and 12C are provided (two impositions). Also, the mark printing cylinder 104 has the same circumference, and the two sets of detection marks are different from each other in the first set of transfer layer repeat units and the second set of transfer layer repeat units. A plate section is provided.

First, the two Y transfer areas 12Y are printed simultaneously by the Y printing cylinder 101, and then the M printing cylinder 102 prints the two Y transfer areas 12Y.
The two M transfer regions 12M are printed at the same time, and the two C transfer regions 12C are simultaneously printed by the C printing cylinder 103. Then, finally, different detection marks 13a and 13b are printed at once by the mark printing cylinder 204.

The detection marks 13a and 13b record information indicating the positional relationship with respect to the plate portion at the time of manufacture in addition to the information indicating the color of the conventional YMC. Is measured in advance, and when printing with a printer, the correction of the color tone can be performed by inputting a correction value of the characteristic.

According to this embodiment, the transfer sheet 10 can be manufactured efficiently by arranging two transfer layers. Also, the detection mark 13 on the transfer sheet 10
Since the positional relationship between the sets of transfer layers provided on two surfaces can be known from a and 13b, it is possible to form a uniform and good image by performing transfer with its characteristics corrected.

In the embodiment described above, the detection mark 1
3a and 13b are printed on different plate portions of the same mark printing cylinder 104 and have different patterns or marks in appearance for each set of multiple impositions. In each of the embodiments described below,
Each set of detection marks is a pattern having the same shape in appearance, and at least one of the detection marks of each transfer area included in an arbitrary set has a different characteristic from other detection marks, or each set of detection marks has a different characteristic. The detection marks are apparently identical in shape, and the characteristics of at least one set of detection marks are different from the characteristics of the other sets of detection marks. Therefore, a method of providing a detection mark will be described as a comparative example, and a description will be given while clarifying differences from the following embodiment.

FIG. 3 is a plan view showing a comparative example of the transfer sheet. In the following comparative examples, it is assumed that the detection mark 42 itself has uniform characteristics. Transfer sheet 40A
In this example, the detection mark 43Y is provided only in the transfer area 42Y at the head of each set. In this case, there is an advantage that only one optical sensor is required. However, the transfer area 42Y
Is read, and the transfer area 42 is read.
Since the start positions of M and 42C are determined by time measurement such as the number of pulses of the motor feeding the transfer sheet, there is a large error. For this reason, in particular, the final area 42C where errors are accumulated needs to be sufficiently longer than the actual printing area so that the printing does not protrude, leading to an increase in material costs.

In the transfer sheet 40B, two detection marks 43YY are provided in the transfer area 42Y at the head of each set, and one detection mark 43M, 43C is provided in each of the other transfer areas 42M, 42C. Things. In this case, there is an advantage that only one optical sensor is required. However, 2
The length of the base sheet is increased by the number of the detection marks 43YY, and the cost is increased.

In the transfer sheet 40C, a detection mark 43Y of the full width is provided in the transfer area 42Y at the head of each set, and short detection marks 43m and 43c in the width direction are provided in the other transfer areas 42M and 42C. It is provided. In this case, two optical sensors are required on the left and right sides in the traveling direction. However, the length of the transfer sheet is not increased, and the time required for detection can be reduced.

The transfer sheet 40D is a transfer region 42Y at the head of each set provided with a thick detection mark 43Y _1, the other transfer region 42M, the 42C, under normal thickness of the detection mark 43M, a 43C provided Things. In this case,
Only _one optical sensor is required, and the head of each set and the head of each color are determined based on the difference between the time when the thick detection mark 43Y1 is detected and the time when the other detection marks 43M and 43C are detected. can do. The transfer sheet only needs only a longer amount of detection mark 43Y ₁ becomes thick.

(Second and Third Embodiments) FIG. 4 is a plan view showing second and third embodiments of a transfer sheet according to the present invention. In each of the embodiments described below, parts that perform the same functions as those in the first embodiment described above include:
The same reference numeral is given or a common reference numeral is given at the end, and duplicate description is omitted as appropriate. In the transfer sheet 50A of the second embodiment, two sets a and b in which transfer areas 52Y, 52M, and 52C of three different colors (yellow, magenta, and cyan) are arranged in a repeating unit are formed, and each transfer area 52Y is formed. , 52M, 52C, the first transfer area 52Y
Are formed with detection marks 53Ya and 53Yb '. The detection marks 53Ya and 53Yb 'of each pair a and b are
Although they have the same shape in appearance, characteristics such as transmittance (or reflectance) of the detection mark 53Ya of the set a are different from characteristics such as transmittance (or reflectance) of the detection mark 53Yb of the set b. In the following description, those with no dash (') in the sign of the detection mark have a low transmittance (high optical density), a high sensor output,
Attached ones have high transmittance (low optical density) and low sensor output. This transfer sheet 50A
Can be manufactured in the same manner as in FIG. 1 by two imposition printing on each printing cylinder.

The detection marks 53Ya and 53Y'b are
The transmittance (or reflectance) of the optical sensor used to read the detection mark 53, here, the infrared (IR) sensor, is different.

Regarding the detection marks 53Ya and 53Y'b, the difference in transmittance or reflectance is in the visible region (400 nm to 400 nm).
It is preferably 10% or less at any wavelength of 700 nm). The reason for this is that the difference is hard to see visually, which is effective in preventing forgery.

As for the detection marks 53Ya and 53Y'b, a detection mark having a high transmittance or reflectance is 800
When the transmittance or the reflectance is measured at any wavelength from nm to 950 nm, the detection mark having a transmittance or a reflectance of 1% or more and 10% or less and having a low transmittance or a reflectance is 80%.
At any wavelength from 0 nm to 950 nm, the transmittance or the reflectance is desirably 1% or less when measured. The optical characteristics of the detection mark having a high transmittance or reflectance are preferably 10% or less when the transmittance or reflectance is measured at any wavelength from 800 nm to 950 nm, so that erroneous detection is less likely to occur. For example, mark ink is the most common black mark incorporating carbon black, and when detection is performed using a general-purpose IR sensor, detection is not stable if the transmittance in the IR region is 10% or more. Detection mark 53Y with different transmittance etc.
a, 53Y'b can be formed by changing the depth of the plate of the mark printing cylinder described above. The detection of the different detection marks 53Ya and 53Y'b may be performed at the mark read sensitivity in accordance with the mark such as the transmittance.

According to the present embodiment, the detection mark 53Y
Since a and 53Y'b have different transmissivities (or reflectivities), it is possible to know the positional relationship between each pair of transfer layers provided with two surfaces, and to perform transfer with its characteristics corrected.
A good image without unevenness can be formed.

In the transfer sheet 50B of the third embodiment, the transfer areas 52Y, 52M and 52C are formed in the same manner as in the second embodiment, but the transfer areas 52Ya and 5 of each pair a and b are formed.
2Ma, 52Ca and transfer regions 52Yb, 52Mb, 5
The detection marks 53Ya, 53Ma, 53Ca and the detection marks 53Yb, 53Mb, 53Cb are formed on 2Cb. The detection marks 53a (53Ya, 5
3Ma, 53Ca) and the detection mark 53b (53Yb,
53Mb, 53Cb) are patterns having the same external appearance as a whole. However, in the set a, the detection mark 5
Characteristics such as transmittance (or reflectance) are different between 3Y′a and the detection marks 53Ma and 53Ca. In group b,
The detection marks 53Y'b and 53M'b and the detection marks 53
Cb differs in characteristics such as transmittance (or reflectance).
Furthermore, when the pair a and the pair b are compared, the detection mark 5
3Ma and the detection mark 53M'b have different characteristics such as transmittance (or reflectance). Here, when the patterns are compared with each other, detection marks having different characteristics (53Ma and 53Ma) are used.
M′b) has at least one of the detection marks 53a, 53b in the set depending on the information to be written.
It is enough to have only one.

According to the present embodiment, the thermal transfer sheet 50B
It is possible to record more information about

As will be described later, the width and number of detection marks having different characteristics such as transmittance can be appropriately set, and the information can be detected by the width and number of pulses at the time of detection. . For example, when judging a genuine product, it is difficult to visually determine the transmittance and the like.
If a complicated pattern is used, it can be easily determined.

Also, for example, when used in a printer of a different version, or when a cassette of non-genuine transfer sheets is mounted, the detection mark is different.
An error can be displayed and disabled.
The method of detection on the printer side is described in Japanese Patent Publication No. 2-2195.
Since it is described in detail in No. 1, etc., the description is omitted here.

(Fourth to Seventh Embodiments) FIGS. 5A and 5B are plan views showing fourth to seventh embodiments of the transfer sheet according to the present invention, respectively. In the embodiment of FIG. 5, the detection marks having the same shape in appearance are such that the first detection mark of each set is two lines, and the detection mark attached to the other transfer area is one line. It is.

The transfer sheet 60A according to the fourth embodiment includes a detection mark 63YYa at the head of each pair a and b and a detection mark 6Y.
3Y′Y′b has a different transmittance. The transfer sheet 60B according to the fifth embodiment is a sheet in which each printing layer and mark printing cylinder of YMC are provided with three plate portions of each transfer layer and detection mark (three impositions). , B, and c, the first detection mark 63YYa, the detection mark 63YY'b, and the detection mark 63Y'Y'c have different transmittances.

The transfer sheet 60C of the sixth embodiment is made of YM
The transfer sheet 60 according to the fifth embodiment, except that an overprotect layer OP is provided in addition to the transfer layer C of FIG.
Same as B.

The transfer sheet 60D of the sixth embodiment has the same detection mark 63Y at the head of each set a, b, but has the same detection mark 63Ma of the magenta transfer layer in each set a, b.
The detection mark 63M'b differs from the transfer sheet 60A of the fourth embodiment in that their transmittance is different. The transfer sheet 60E of the seventh embodiment is obtained by adding three patterns to the pattern of the transfer sheet 60D of the sixth embodiment. In this case, the detection marks of the magenta or cyan transfer layer in each set a, b, and c are the detection marks 6 of the set a.
For 3Ma and 63Ca, the detection mark 63M 'of the set b is set.
b and the detection mark 63C'c of the set c have different transmittances.

(Eighth to Tenth Embodiments) FIG. 6 is a plan view showing an eighth to a tenth embodiment of a transfer sheet according to the present invention. In each embodiment of FIG. 6, the detection mark at the head of each set is a single line of the entire width, and the detection marks attached to the other transfer areas are short single lines to the middle in the width direction. , A detection mark having a pattern of the same shape in appearance. In addition, in each embodiment of FIG. 6, two optical sensors are required on the left and right in the traveling direction to read the detection mark.

The transfer sheet 70A according to the eighth embodiment includes a detection mark 73Ya at the head of each pair a and b,
Y′b differs in transmittance. The transfer sheet 70B of the ninth embodiment is an example in which the transfer sheet 70A of the eighth embodiment has three impositions, and the leading detection mark 73Ya, the detection mark 63yy'b, and the detection mark of each set a, b, and c are provided. Mark 6
3Y'c has different transmittances. Detection mark 63
yy'b is a line having a low transmittance in the half in the width direction and a high transmittance in the other half.

The transfer sheet 70C of the tenth embodiment is an example of three impositions, like the transfer sheet 70B of the ninth embodiment. However, like the transfer sheet 60C of the sixth embodiment, the transfer sheet 70C has an over-protection layer OP. It is provided. In this case, with respect to the first detection mark 73Ya of the set a,
The first detection mark 73y'yb and the first detection mark 73yy'c of the pair b and c have different transmittances. The detection mark 73y'yb and the detection mark 73yy'c are one line having a low transmissivity in the width direction and a high transmissivity in the other half in the width direction, but the arrangement in the width direction is reversed. .

FIG. 7 is a diagram showing a detection mark of a transfer sheet according to the tenth embodiment and a modified example thereof. Tenth
As shown in FIG. 7A, the detection mark 73y'yb according to the embodiment has a half line 73 having a low transmittance in a half in the width direction.
y ', and the other half is a half line 73y having a high transmittance.
However, in the modification of FIG. 7B, three portions 73y, 73y ', and 73y having different transmittances in the longitudinal direction are formed. In this way, more information can be recorded. The portions having different transmittances may be two or four or more.

In the modification shown in FIG. 7C, portions 73y and 73y 'having different transmittances are formed so that one of them surrounds the other. Note that the number of the enclosed portion 73y may be two or more.

(Modifications) Various modifications and changes are possible without being limited to the above-described embodiments, and these are also within the equivalent scope of the present invention. For example, although the description has been made with reference to the example of two or three impositions, four or more impositions may be used. The transfer sheet can be applied to a sheet having a receiving layer in addition to the surface protective layer (OP layer).

[0056]

As described above in detail, according to the present invention, a transfer sheet can be manufactured efficiently by providing multiple transfer layers. In addition, since the positional relationship between the sets of transfer layers provided on multiple sides can be known from the detection marks on the transfer sheet, a good image can be formed by performing transfer with its characteristics corrected.

[Brief description of the drawings]

FIG. 1 is a schematic view showing an embodiment of a transfer sheet and a method of manufacturing the same according to the present invention.

FIG. 2 is a schematic diagram showing a conventional transfer sheet and a method for manufacturing the same.

FIG. 3 is a plan view showing a comparative example of a transfer sheet.

FIG. 4 is a plan view showing second and third embodiments of a transfer sheet according to the present invention.

FIG. 5 is a plan view showing fourth to seventh embodiments of the transfer sheet according to the present invention.

FIG. 6 is a plan view showing eighth to tenth embodiments of a transfer sheet according to the present invention.

FIG. 7 is a diagram showing a transfer sheet detection mark and its modification according to a tenth embodiment.

[Explanation of symbols]

 10, 50, 60, 70 Transfer sheet 11 Base sheet 12 Thermal transfer layer 13a, 13b, 53, 63, 73 Detection mark

Claims (14)

[Claims] 1. A plurality of sets in which a plurality of transfer areas of different functions are arranged in a fixed repeating unit are formed, and at least one set of each transfer area or each set of the transfer areas is provided. Wherein at least two types of patterns of the detection marks for each set are provided in the transfer sheet having the detection marks formed thereon. 2. The transfer sheet according to claim 1, wherein the detection marks are formed by different plate portions on the same printing cylinder, and are different for each of the transfer areas. 3. The transfer sheet according to claim 2, wherein the detection marks are formed by different plate portions on the same printing cylinder, and information on a position of the transfer area is recorded. . 4. A plurality of sets in which a plurality of transfer regions of different functions are arranged in a fixed repeating unit are formed, and at least one of the transfer regions is provided or at least one of the transfer regions is provided. In the transfer sheet on which the detection marks are formed, the detection marks of each set have a pattern of the same shape in appearance, and at least one of the detection marks of each transfer area included in an arbitrary set has another detection mark. A transfer sheet having characteristics different from marks. 5. A transfer sheet in which a plurality of sets in which a plurality of transfer areas of different functions are arranged in a fixed repeating unit are formed, and a detection mark is formed for each set of the transfer areas. The transfer sheet according to claim 1, wherein the detection marks have the same shape in appearance, and characteristics of at least one set of detection marks are different from characteristics of another set of detection marks. 6. The transfer sheet according to claim 4, wherein the detection mark has a different transmittance or reflectance from an optical sensor used to read the detection mark. Sheet. 7. The transfer sheet according to claim 6, wherein a difference in transmittance or reflectance between the detection marks having different transmittances or reflectances is in a visible region (400 nm to 700 nm).
nm) at any wavelength of 10% or less. 8. The transfer sheet according to claim 6, wherein, with respect to the detection marks having different transmittances or reflectances, the detection marks having a higher transmittance or reflectance have a wavelength of 800 nm to 95%.
When the transmittance or the reflectance is measured at any wavelength of 0 nm, a detection mark having a transmittance or a reflectance of 1% or more and 10% or less and a transmittance or a reflectance of 800 nm to 95% is low.
A transfer sheet having a transmittance or reflectance of 1% or less at any wavelength of 0 nm. 9. Any one of claims 4 to 8
3. The transfer sheet according to claim 1, wherein the detection marks are formed by different plate portions on the same printing cylinder, and are different for each of the transfer areas. 10. The transfer sheet according to claim 9, wherein the detection marks are formed by different plate portions on the same printing cylinder, and information on a position of the transfer area is recorded. . 11. A plurality of sets in which a plurality of transfer areas having different functions are arranged in a fixed repeating unit are formed, and at least one set of each of the transfer areas or each set of the transfer areas is provided. In a method for manufacturing a transfer sheet for manufacturing a transfer sheet having detection marks formed thereon, a plurality of transfer layer printing cylinders, each of which is provided with a plurality of printing plates having different transfer areas, print a plurality of sets of the transfer areas, A method for manufacturing a transfer sheet, wherein a detection mark including at least one non-identical mark among the plurality of sets of the repeating units is printed by one detection mark printing cylinder. 12. A plurality of sets in which a plurality of transfer regions having different functions are arranged in a fixed repeating unit are formed, and at least one of the transfer regions is provided or at least one of the transfer regions is provided. In a method for manufacturing a transfer sheet for manufacturing a transfer sheet having detection marks formed thereon, a plurality of transfer layer printing cylinders, each of which is provided with a plurality of printing plates having different transfer areas, print a plurality of sets of the transfer areas, Among the plurality of sets of the repeating units, at least one of the detection marks of each transfer region included in an arbitrary set is a pattern having the same shape in appearance, and has a characteristic different from other detection marks. A method for manufacturing a transfer sheet, wherein printing is performed with two detection mark printing cylinders. 13. A transfer sheet for producing a transfer sheet in which a plurality of sets in which a plurality of transfer areas having different functions are arranged in a fixed repeating unit are formed, and a detection mark is formed for each set of the transfer areas. In the manufacturing method, a plurality of sets of the transfer areas are printed by a plurality of transfer layer printing cylinders each having a plurality of plate portions of the different transfer areas multi-faced. A method of manufacturing a transfer sheet, comprising printing with a single detection mark printing cylinder having a shape, wherein characteristics of at least one set of detection marks are different from characteristics of another set of detection marks. 14. The method according to claim 1, wherein
In the transfer method using the transfer sheet described in the paragraph, in the transfer sheet, a detection mark that records information on the positional relationship of each set is formed on the transfer sheet, and based on the detection mark, A transfer method characterized in that transfer is performed with characteristics corrected.