JP5310179B2 - Thermal transfer printer, printing method, and thermal transfer printing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thermal transfer printer for detecting and confirming the setting direction of the image receiving paper in double-sided printing, and also to provide the image receiving paper. <P>SOLUTION: When making the double-sided printing on a plurality of image receiving paper 41 by a thermal transfer printer 1, image data is acquired from media such as a USB memory and an SD card, and a printing condition is input by an input part 23. The control part 11 of the thermal transfer printer 1 determines that the image receiving paper 41 is the correct setting direction, when a sensor 33 detects a mark 65 or a hole 67 of the image receiving paper 41 in a predetermined position, and the control part 11 of the thermal transfer printer 1 prints the image data on a surface of the image receiving paper 41 by indicating the fact to a printing part 16. After wholly finishing the printing on the surface of the image receiving paper 41, the control part 11 of the thermal transfer printer 1 determines whether the setting direction of the image receiving paper 41 set for reverse surface printing is correct, and prints the image data on a reverse surface of the image receiving paper 41 by indicating the fact to the printing part 16 when the setting direction is correct. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

The present invention relates to a thermal transfer printer, and more particularly, to a thermal transfer printer, an image receiving paper, and the like for detecting and confirming a setting direction of the image receiving paper during double-sided printing.

Conventionally, characters and images are formed on a transfer medium using a thermal transfer method. As the thermal transfer method, a thermal sublimation transfer method and a thermal fusion transfer method are widely used. In recent years, it has become widespread to print image data taken with a digital camera as a photograph with a home thermal transfer printer.
When printing multiple images on both sides and creating a photo book, etc., set a sheet-type image-receiving paper on a household thermal transfer printer and start printing image data. There is a case where the printing direction on the front and back sides is different, and an image is printed upside down.

  In the method described in Patent Document 1, in order to prevent the thermal transfer printer from being damaged by mistakenly inserting paper other than the dedicated thermal transfer image receiving paper, and to prevent erroneous insertion of the front and back of the thermal transfer image receiving paper, Discloses a method of preventing a malfunction by providing a logo mark, a design, or the like that functions as a detection mark for detecting a sensor for use.

  In the method described in Patent Document 2, when performing double-sided printing, in order to be able to perform double-sided printing only on double-sided thermal transfer image-receiving paper capable of double-sided printing, paper determination is performed on both the front and back sides at the start of printing. A mark is printed, and it is determined whether or not a heat sensitive layer is formed on both sides of the thermal transfer image receiving paper by judging that a paper judgment mark is printed on both the front and back sides by a sensor, and performs double-sided printing. This method is disclosed.

JP 2008-307801 A JP 2009-018593 A

  However, for example, with the method disclosed in Patent Document 1, it is possible to determine the front and back of image-receiving paper that can be printed on one side, but it cannot be applied to image-receiving paper for double-sided printing. With the method disclosed in Patent Document 2, the front and back sides of the image receiving paper can be determined, but the vertical direction cannot be determined.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a thermal transfer printer, image receiving paper, and the like capable of detecting and confirming the image receiving paper setting direction during double-sided printing. It is. Specifically, when one side of the image receiving paper is printed and the front side and the back side are switched and set in the printer, the image receiving paper is set correctly and the printing direction is not mistaken. With this method, if the image data is set in the wrong direction to print the first image data (front side) and the second image data (back side), the front and back images are upside down. It is possible to prevent problems such as being printed on the image and becoming unusable for photobook purposes.

In order to achieve the above-described object, the first invention is configured such that the thermal head presses the thermal transfer sheet and the image receiving paper between the platen roller and heats the heating element constituting the heating unit according to the image data. wherein by the heat transfer sheet a coloring material of the color material layer transferred to the image receiving sheet, a thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides, image acquisition for acquiring the image data Means for detecting a detection mark on the image receiving paper and confirming a setting direction of the image receiving paper, and when the setting direction of the image receiving paper is determined to be correct by the setting direction checking means, the image receiving paper comprising a printing means for printing the image data on paper, and the detection mark is a hole formed in the image receiving paper, the projections on the cylindrical surface of the platen roller Is provided, the set direction confirmation section, holes detects by fitting the image receiving paper of holes in the protrusions, a thermal transfer printer, characterized in that to check the setting direction of the image receiving paper.

By forming the detection mark of the hole to receive image paper, the double-sided printing in a thermal transfer printer, the setting direction of the image receiving sheet detecting, it is possible to confirm.
Further, it is preferable that the printing means can select a binding margin portion to be either a short side or a long side of the image receiving paper.

The second invention is to provide a thermal head is pressed against a thermal transfer sheet and the image-receiving sheet between the platen roller, exothermed heating elements constituting the heating portion according to the input image data, the color material of the heat transfer sheet by transferring the color material layer on the image receiving paper, the thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides, there in printing process for printing the image data on both surfaces of the image receiving paper An image acquisition step for acquiring the image data, a set direction confirmation step for detecting a detection mark on the image receiving paper and confirming a setting direction of the image receiving paper, and a setting direction of the image receiving paper by the setting direction confirmation step If it is determined that correct, anda printing step of printing the image data to the image-receiving sheet, said detection mark is a hole formed in the image receiving paper Ri, the protrusions on the cylindrical surface of the platen roller is provided, the set direction check process, a hole is detected by fitting the image receiving paper of holes in the protrusions, confirm the setting direction of the image receiving paper The printing method is characterized by the following.

The third invention is to provide a thermal head is pressed against a thermal transfer sheet and the image-receiving sheet between the platen roller, exothermed heating elements constituting the heating portion according to image data, the color of the color material layer of the thermal transfer sheet by transferring the timber to the receiving sheet, a thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides, a thermal transfer printing system composed of the image receiving sheet, the thermal transfer printer The image acquisition means for acquiring the image data, the detection direction on the image receiving paper is detected, the setting direction checking means for checking the setting direction of the image receiving paper, and the setting direction checking means determines the setting direction of the image receiving paper. If it is determined correct, anda printing means for printing the image data to the image-receiving sheet, wherein the detection mark is formed on the image receiving paper hole There, the protrusions on the cylindrical surface of the platen roller is provided, the set direction confirmation section, a hole is detected by fitting the image receiving paper of holes in the protrusions, confirm the setting direction of the image receiving paper And a thermal transfer printing system.

  According to the present invention, it is possible to provide a thermal transfer printer, image receiving paper, and the like capable of detecting and confirming the image receiving paper setting direction during double-sided printing.

The figure which shows the outline | summary of the hardware constitutions of the thermal transfer printer 1 which concerns on this invention. The figure which shows an example of a structure of the printing part 16 of the thermal transfer printer 1. FIG. The figure which shows an example of the cross-sectional structure of the image receiving paper 41 The figure which shows an example of the mark 65 formed in the image receiving paper 41 The figure which shows an example of the hole 67 formed in the image receiving paper 41 2 is a flowchart showing a flow of double-sided printing processing of the thermal transfer printer 1 according to the present invention. Schematic diagram for explaining determination of the setting direction of the image receiving paper 41 in which the mark 65 is formed only on the surface Schematic diagram for explaining determination of the setting direction of the image receiving paper 41 having the marks 65 formed on both sides The schematic diagram for demonstrating the determination of the setting direction by the position of the binding margin part 63 of the image receiving paper 41

Embodiments of a thermal transfer printer according to the present invention will be described below in detail with reference to the drawings.
First, an outline of the thermal transfer printer 1 according to the present invention will be described with reference to FIG.
The thermal transfer printer 1 is a household printer for printing a sheet-type image receiving paper, and may be either a thermal sublimation transfer method or a thermal fusion transfer method. In the thermal transfer printer 1, a control unit 11, a storage unit 12, an input unit 13, a display unit 14, a media input / output unit 15, a printing unit 16, and the like are connected via a bus 17.

  The control unit 11 includes a CPU (Central Processing Unit) that executes a program, a RAM (Random Access Memory) for storing program instructions or data, a ROM (Read Only Memory), and the like. The control unit 11 controls each device connected via the bus 17 in accordance with a program stored in the storage unit 12.

  The storage unit 12 stores a program for controlling each device of the thermal transfer printer 1, image data, and various control data. The codes of these programs are read from the storage unit 12 to the RAM as needed by the CPU of the control unit 11, executed as various functions, and send image data to the printing unit 16 to instruct printing.

The input unit 13 is a user interface device such as a numeric key, an arrow key, a function key, or a touch panel, and performs selection of an image to be printed by the thermal transfer printer 1, input of printing conditions, and the like.
The display unit 14 is a display such as an LCD (Liquid Crystal Display) or the like, and displays the state of the thermal transfer printer 1 and information input by the user via the input unit 13.

The media input / output unit 15 is an image data acquisition unit that acquires an image to be printed. A USB (Universal Serial Bus) memory, an SD (Secure Digital) memory card, a mini SD card, a compact flash (registered trademark), an xD picture card, Image data is acquired by reading the image data from a medium such as a compact disk.
The thermal transfer printer 1 may acquire an image by connecting to a network such as the Internet through a communication unit (not shown), or may acquire an image from a computer through infrared communication, Bluetooth, USB connection, or the like.

Although not shown, the printing unit 16 includes a thermal head composed of a plurality of heating resistors formed in a line on the substrate, a thermal head driving unit, and the like. When the image data to be printed is sent in response to an instruction from the control unit 11, the printing unit 16 applies energy according to the pixel value to the thermal head, whereby the ink of the thermal transfer sheet at the application part melts and adheres to the recording paper. The output image is printed on the image receiving paper.
The thermal transfer sheet has yellow Y, magenta M, cyan C, and a thermal transfer protective layer that gives a function of protecting the transferred dye, and color printing is performed by transferring these inks in layers.

  Next, an example of the configuration of the printing unit 16 of the thermal transfer printer 1 will be described with reference to FIG.

  As shown in FIG. 2, the printing unit 16 of the thermal transfer printer 1 includes a thermal head 21, a thermal transfer sheet 23, a thermal transfer sheet supply roll 25, a thermal transfer sheet take-up roll 27, a nip roller 29, a platen roller 31, a sensor 33, and a paper feed port. 35, a discharge port 37 and the like. In addition, the thermal transfer printer 1 includes a conveyance mechanism for the image receiving paper 41, a control unit that performs printing control, and the like.

The image receiving paper 41 is a sheet-type image receiving paper, and is conveyed by a conveying roller or the like (not shown) from the paper supply port 35 for printing. In order for the thermal transfer printer 1 to detect the setting direction of the image receiving paper 41, a mark or hole for detecting the setting direction is formed on the image receiving paper 41. Details of the image receiving paper 41 will be described later.
The thermal transfer sheet 23 is obtained by providing yellow Y, magenta M, cyan C, and a protective color material layer on a base sheet.
As for the planar configuration of the thermal transfer sheet 23, areas having color material layers of yellow Y, magenta M, and cyan C are provided in the surface order. The transfer order of the color materials is yellow Y, magenta M, cyan C, and protective layer. Further, a region having a black K color material layer may be further added as a planar configuration.

The thermal head 21 includes a heat generating unit, an image information input unit, an elevating unit, a control unit, and the like (not shown).
When performing printing, the thermal head 21 presses the thermal transfer sheet 23 and the image receiving paper 41 between the platen roll 31 and includes a heating element that constitutes a heating unit according to the image data input by the image information input unit. Heat is generated, and the color material of the color material layer of the thermal transfer sheet 23 is transferred to the image receiving paper 41.

  The thermal transfer supply roll 25 is obtained by winding the thermal transfer sheet 23. The thermal transfer sheet 23 wound around the thermal transfer supply roll 25 is conveyed at the time of printing, and passes through the heat generating part of the thermal head 21, so that the thermal transfer sheet take-up roll 27. Rolled up.

The platen roller 31 is cylindrical and includes a drive mechanism such as a motor (not shown) and conveys the image receiving paper 41. On the cylindrical surface of the platen roller 31, the image receiving paper 41 is conveyed and printing by the thermal head 21 is performed.
The nip roller 29 is a roller that assists the conveyance of the image receiving paper 41. The pair of nip rollers is provided in proximity to the platen roller 31 at a position where the thermal head 21 is sandwiched.
When printing, the platen roller 31 and the nip roller 29 securely convey the image receiving paper 41 while being sandwiched. Further, the nip roller 29 has a smooth surface and does not cause unevenness on the surface of the image receiving paper 41.

The sensor 33 detects a later-described mark formed on the image receiving paper 41 in order to confirm the setting direction of the image receiving paper 41. Various combinations of the mark formed on the image receiving paper 41 and the sensor 33 are conceivable. For example, the sensor 33 is an infrared sensor, a CCD image sensor, a visible light sensor, or the like.
Although the sensor 33 is provided on the upstream side in the printing direction with respect to the thermal head 21, the position of the sensor 33 is not limited to this, and may be provided on the downstream side with respect to the thermal head 21, for example.
The sensors 33 are provided on both the front and back sides of the image receiving paper 41. For example, when marks are formed on both sides of the image receiving paper 41, they may be provided only on the front side or only on the back side.

When the thermal transfer printer 1 detects the setting direction of the image receiving paper 41, when a hole is formed on the image receiving paper 41, the sensor 33 is provided at the same position as when the mark is formed, only on the front side or only on the back side. You may do it. In this case, the sensor 33 detects the hole as a detection mark and confirms the setting direction of the image receiving paper 41.
Alternatively, the sensor 33 may be provided on the platen roller 31. In this case, the sensor 33 is provided as a protrusion on the cylindrical surface of the platen roller 31 and detects the hole by fitting the hole of the image receiving paper 41 into the protrusion to confirm the setting direction of the image receiving paper 41.

Next, the details of the image receiving paper 41 used in the thermal transfer printer 1 will be described with reference to FIGS.
3 is a diagram illustrating an example of a cross-sectional configuration of the image receiving paper 41, FIG. 4 is a diagram illustrating an example of a mark 65 formed on the image receiving paper 41, and FIG. 5 is an example of a hole 67 formed in the image receiving paper 41. FIG.

The image receiving paper 41 is an image receiving paper for printing image data by the thermal transfer printer 1 and creating a photo book.
As shown in FIG. 3, the image receiving paper 41 has a configuration in which an adhesive layer 57, a porous film 55, a primer 53, and a receiving layer 51 are sequentially provided on both sides of a paper material 59.
For these, various structures or materials can be used in consideration of the strength, heat resistance, dyeing property of the coloring material, and the like.
Further, the color material of the thermal transfer sheet 23 is transferred to the receiving layer 51 of the image receiving paper 41. By providing the receiving layer 51 on both sides, double-sided printing of the image receiving paper 41 is possible.

  As shown in FIGS. 4 and 5, the image receiving paper 41 has a printing portion 61 that is an image printing region and a binding margin portion 63 that serves as a binding margin when binding a photo book or the like in the same region on both sides. . In order to detect the set direction of the image receiving paper 41, a mark 65 or a hole 67 is formed as a detection mark in the binding margin portion 63 (end portion) of the image receiving paper 41. The mark 65 and the hole 67 can be detected by the sensor 33 of the thermal transfer printer 1.

The mark 65 only needs to have a shape that can identify the setting direction of the image receiving paper 41. For example, a mark such as a bearing symbol and a shape symbol such as ■ and ● are formed in the binding margin portion 63. When the mark 65 is formed on the front surface or the back surface, it is desirable that either the front surface or the back surface mark 65 is located at the same position when detected by the sensor 33 above (or below). That is, it is desirable to form each mark 65 at a position where both the front surface and the back surface can be detected by one sensor 33 having a small detection range.
The hole 67 is formed in an arbitrary shape at an arbitrary position of the binding margin portion 63.

Next, processing for performing double-sided printing in the thermal transfer printer 1 will be described with reference to FIG.
FIG. 6 is a flowchart showing the flow of double-sided printing processing of the thermal transfer printer 1 according to the present invention.

When performing double-sided printing on a plurality of image receiving papers 41 with the thermal transfer printer 1, when a user inserts media such as a USB memory or an SD card storing image data captured by a digital camera or the like into the thermal transfer printer 1, the thermal transfer printer 1. The control unit 11 acquires image data through the media input / output unit 15. Further, the control unit 11 of the thermal transfer printer 1 acquires the printing conditions input by the user through the input unit 13 such as numeric keys, arrow keys, function keys, etc. (step 101). The acquired image data and printing conditions are stored in the storage unit 12. The printing conditions are the printing direction, front and back, number of pages, etc. of each image data.
The thermal transfer printer 1 may acquire image data from a computer via infrared communication, Bluetooth, USB connection, network connection, or the like, or may acquire it from a server via a network such as the Internet.

The controller 11 of the thermal transfer printer 1 detects the mark 65 or the hole 67 on the image receiving paper 41 by the sensor 33 and confirms whether the setting direction of the image receiving paper 41 is correct (step 102).
When the sensor 33 detects the mark 65 or the hole 67 of the image receiving paper 41 at a predetermined position, the control unit 11 of the thermal transfer printer 1 determines that the image receiving paper 41 is in the correct setting direction (step 103). If the image receiving paper 41 cannot be detected, it is determined that the setting direction of the image receiving paper 41 is not correct, a warning is displayed on the display unit 14 that the setting direction of the image receiving paper 41 is not correct (step 104), and the image receiving paper 41 is set again. Wait for.

After confirming that the image receiving paper 41 is set in the correct setting direction, the control unit 11 of the thermal transfer printer 1 instructs the printing unit 16 to print the image data designated by the user on the surface of the image receiving paper 41. (Step 105).
The control unit 11 of the thermal transfer printer 1 determines whether or not the printing of the image data on the surface of the image receiving paper 41 has been completed (step 106), and repeats the processing from step 102 to step 106 until the printing is completed.

After the printing on the front surface of the image receiving paper 41 is completed, the control unit 11 of the thermal transfer printer 1 displays on the display unit 14 to set the image receiving paper 41 in order to print the back surface of the image receiving paper 41 because the printing on the front surface is completed. To do.
After the user sets the image receiving paper 41 in the thermal transfer printer 1, the control unit 11 of the thermal transfer printer 1 detects the mark 65 or the hole 67 on the image receiving paper 41 by the sensor 33, and the setting direction of the image receiving paper 41 is changed. It is confirmed whether it is correct (step 107).
When the sensor 33 detects the mark 65 or the hole 67 of the image receiving paper 41 at a predetermined position, the control unit 11 of the thermal transfer printer 1 determines that the image receiving paper 41 is in the correct setting direction (step 108). If the image receiving paper 41 cannot be detected, it is determined that the setting direction of the image receiving paper 41 is not correct, a warning is displayed on the display unit 14 that the setting direction of the image receiving paper 41 is not correct (step 109), and the image receiving paper 41 is set again. Wait for.

After confirming that the image receiving paper 41 is set in the correct setting direction, the control unit 11 of the thermal transfer printer 1 instructs the printing unit 16 to print the image data designated by the user on the back surface of the image receiving paper 41. (Step 110).
The control unit 11 of the thermal transfer printer 1 determines whether printing of the image data on the back surface of the image receiving paper 41 has been completed (step 111), and repeats the processing from step 107 to step 111 until all printing is completed.

Next, an example of determining the setting direction of the image receiving paper 41 will be described with reference to FIGS.
FIG. 7 is a schematic diagram for explaining determination of the setting direction of the image receiving paper 41 having the mark 65 formed only on the front surface, and FIG. 8 illustrates determination of the setting direction of the image receiving paper 41 having the mark 65 formed on both sides. FIG. 9 is a schematic diagram for explaining the determination of the setting direction based on the position of the binding margin portion 63 of the image receiving paper 41.

FIG. 7 is a view of the image receiving paper 41 being conveyed as viewed from above in FIG. The sensor 33 a is disposed on the conveyance path of the image receiving paper 41, and the sensor 33 b is disposed on the bottom of the conveyance path of the image receiving paper 41. A mark 65 is formed only on the surface of the image receiving paper 41. The image receiving paper 41 is conveyed from the left to the right, and the sensors 33a and 33b confirm the setting direction.
The set direction of the image receiving paper 41 includes four patterns shown in FIG. That is, (a) surface is upper and mark 65 is front, (b) surface is upper and mark 65 is rear, (c) back is upper and mark 65 is front, (d) back is upper and mark 65 is rear, There are four patterns.
For example, it is assumed that the printing direction in which the binding margin portion 63 is positioned forward is correct. In this case, in step 102 of FIG. 6 in which it is determined whether or not the surface is set in the correct direction, when the sensor 33a installed on the conveyance path detects the mark 65, it is determined that the setting direction is correct. That is, in step 102, if the image receiving paper 41 is set as shown in FIG.
Further, in step 107 of FIG. 6 in which it is determined whether or not the back surface is set in the correct direction, when the sensor 33b installed under the transport path detects the mark 65, it is determined that the setting direction is correct. That is, in step 107, if the image receiving paper 41 is set as shown in (c) of FIG.

  FIG. 8 is a view of the state of conveying the image receiving paper 41 as seen from above in FIG. The sensor 33 is disposed either above or below the conveyance path of the image receiving paper 41. On the image receiving paper 41, marks 65 are formed on both the front and back surfaces. The shape of the mark 65 may be different between the front surface and the back surface so that the sensor 33 can distinguish between the front surface and the back surface. For example, as shown in FIG. 8, the front surface may be ● and the back surface may be ■. The image receiving paper 41 is conveyed from left to right, and the sensor 33 confirms the setting direction.

When the marks 65 are formed on both the front and back surfaces, the set direction of the image receiving paper 41 includes four patterns shown in FIG. That is, (e) the mark 65 is on the front and front, and the back mark 65 is the same, (f) the mark 65 is on the back and front, and the back mark 65 is the same, (g) the mark 65 is on the front and front, There are four patterns in which the position of the mark 65 on the back surface is different, and (h) the mark 65 is on the rear and front surface, and the position of the mark 65 on the back surface is different. That the positions of the marks 65 on the front surface and the back surface are the same means that they are in the same position when detected by the sensor 33. Further, that the positions of the marks 65 on the front surface and the back surface are different means that the positions are different when detected by the sensor 33.
Here, the patterns in which the marks 65 are formed at the same position on the front and back surfaces are (e) and (f). In the case of (e) and (f), the range detected by the sensor 33 is small, and it is preferable to increase the detection range of the sensor 33 or to dispose a plurality of sensors.

For example, it is assumed that the printing method in which the binding margin portion 63 is positioned forward is correct. In this case, in step 102 in FIG. 6 in which it is determined whether or not the front surface is set in the correct direction, the sensor 33 installed on either the upper or lower side of the conveyance path marks the front surface mark 65 (●) in front of the image receiving paper 41. If detected at, it is determined that the set direction is correct. That is, in step 102, when the image receiving paper 41 is (e) or (g) shown in FIG. On the other hand, if the image receiving paper 41 is (f) or (h) shown in FIG.
Further, in step 107 in FIG. 6 for determining whether or not the back surface is set in the correct direction, when the sensor 33 installed on either the upper or lower side of the transport path detects the mark 65 (■) in front of the image receiving paper 41. Judge that the set direction is correct. That is, in step 107, if the image receiving paper 41 is (e) or (g) shown in FIG. On the other hand, if the image receiving paper 41 is (f) or (h) shown in FIG.

FIG. 9 shows the image receiving paper 41 when the binding margin portion 63 that forms a binding margin when binding a photo book or the like is formed on the short side and on the long side. As shown in (i) of FIG. 9, the mark 65 is formed on the image receiving paper 41 before printing.
For example, assume that the printing method in which the image receiving paper 41 is set in the thermal transfer printer 1 so that the mark 65 is in front is correct.
When forming the binding margin portion 63 on the short side of the image receiving paper 41, the thermal transfer printer 1 confirms that the surface is set in the correct direction, and as shown in FIG. 9 (j), the leading end portion in the printing direction. Is left as an unprinted area as a binding margin portion 63, and image data is printed on the print portion 61. Next, when the thermal transfer printer 1 confirms that the back surface is set in the correct direction, the leading edge portion in the printing direction is left as an unprinted area as shown in (j) in FIG. Image data is printed on the print portion 61. The determination of the set direction is as described with reference to FIG.

  When the binding margin portion 63 is formed on the long side of the image receiving paper 41, the thermal transfer printer 1 confirms that the surface is set in the correct direction, and includes a mark 65 including a mark 65 as shown in FIG. The side portion is left as an unprinted area as a binding margin portion 63, and image data is printed on the print portion 61. Next, when confirming that the back surface is set in the correct direction, the thermal transfer printer 1 leaves the long side portion including the mark 65 as an unprinted area as shown in FIG. The image data is printed on the print portion 61. The determination of the set direction is as described with reference to FIG.

As described above, the thermal transfer printer 1 can perform double-sided printing by selecting either the short side or the long side at any time without replacing the image receiving paper 41.
When the mark 65 is formed on one side, the thermal transfer printer 1 forms the binding margin portion 63 on either the short side or the long side by forming the mark 65 at one of the four corners as shown in (i). However, it is possible to print so that the mark 65 is included in the binding margin 63 on both the front surface and the back surface.
On the other hand, consider the case where the marks 65 are formed on both the front and back surfaces. It is assumed that the sensor 33 is installed either above or below the conveyance path of the image receiving paper 41. In this case, in order to perform printing so that each mark 65 is included in the front and back binding portions 63 regardless of whether the binding margin portion 63 is formed on the short side or the long side, (g ) Or (h), the mark 65 is formed. In other words, the front and back marks 65 are formed so that the positions of the marks 65 are different when detected by the sensor 33. The sensors 33 have a detection range of about the length in the short side direction, or two sensors 33 are arranged at both ends in the short side direction.

  In the foregoing, the method has been described in which, in the thermal transfer printer 1, the surface of the plurality of image receiving papers 41 is continuously printed, the user turns the plurality of image receiving papers 41 over, and the back surface is continuously printed. However, the double-sided printing method is not limited to this. For example, when the thermal transfer printer 1 has a mechanism for reversing the image receiving paper 41, or when it has a mechanism for printing both sides of the image receiving paper 41, the image receiving paper 41 may be printed on the front and back surfaces one by one. In this case, each image receiving paper 41 is subjected to processing excluding the determination processing in step 106 and step 111, and duplex printing is performed. This eliminates the need for the user to manually set the image receiving paper 41 for backside printing.

  As described above, the thermal transfer printer according to the embodiment of the present invention can provide a thermal transfer printer, image receiving paper, and the like that can detect and confirm the image receiving paper setting direction during double-sided printing.

  In addition, by forming detection marks such as marks and holes on the image receiving paper, the thermal transfer printer detects the detection mark at the time of printing, and then pulls back or sends the image receiving paper by a predetermined amount, so that the alignment of the printing is more accurate. Can also be done.

  The preferred embodiments of the thermal transfer printer and the like according to the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to such examples. It will be apparent to those skilled in the art that various changes or modifications can be conceived within the scope of the technical idea disclosed in the present application, and these naturally belong to the technical scope of the present invention. Understood.

DESCRIPTION OF SYMBOLS 1 ......... Thermal transfer printer 11 ......... Control part 12 ......... Memory | storage part 13 ......... Input part 14 ......... Display part 15 ......... Media input / output part 16 ......... Print part 21 ......... Thermal head 23 ......... Thermal transfer sheet 25 ......... Thermal transfer sheet supply roll 27 ......... Thermal transfer sheet take-up roll 29 ......... Nip roller 31 ......... Platen rollers 33, 33a, 33b ......... Sensor 35 ......... Paper feed port 37 ......... Discharge port 41 ......... Image receiving paper 51 ......... Receiving layer 53 ......... Primer 55 ......... Porous PP film 57 ......... Adhesive layer 59 ......... Paper material 61 ......... Printed part 63 ... ...... Binding margin 65 ……… Mark 67 ……… Hole

Claims (4)

With the thermal head is pressed against a thermal transfer sheet and the image-receiving sheet between the platen roller, exothermed heating elements constituting the heating portion according to image data, the color material of the color material layer of the thermal transfer sheet to the image receiving paper by transferring, to a thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides,
Image acquisition means for acquiring the image data;
A set direction confirmation means for detecting a detection mark on the image receiving paper and confirming a setting direction of the image receiving paper;
When the setting direction confirmation unit determines that the setting direction of the image receiving paper is correct, printing means for printing the image data on the image receiving paper;
Equipped with,
The detection mark is a hole formed in the image receiving paper,
Protrusions are provided on the cylindrical surface of the platen roller,
The setting direction confirmation means, thermal transfer printer, wherein a hole is detected by fitting the image receiving paper of holes in the protrusions, characterized by confirming the setting direction of the image receiving paper.   The thermal transfer printer according to claim 1, wherein the printing unit is capable of selecting a binding margin portion to be a short side or a long side of the image receiving paper. With the thermal head is pressed against a thermal transfer sheet and the image-receiving sheet between the platen roller, exothermed heating elements constituting the heating portion according to the input image data, wherein the coloring material of the color material layer of the thermal transfer sheet by transferred to the image receiving sheet, the thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides, a printing method for printing the image data on both sides of the image receiving paper,
An image acquisition step of acquiring the image data;
A set direction confirmation step of detecting a detection mark on the image receiving paper and confirming a setting direction of the image receiving paper;
When it is determined by the setting direction confirmation step that the setting direction of the image receiving paper is correct, a printing step of printing the image data on the image receiving paper;
Equipped with,
The detection mark is a hole formed in the image receiving paper,
Protrusions are provided on the cylindrical surface of the platen roller,
The printing method is characterized in that the setting direction confirmation step detects a hole by fitting the hole of the image receiving paper into the protrusion and confirms the setting direction of the image receiving paper . With the thermal head is pressed against a thermal transfer sheet and the image-receiving sheet between the platen roller, exothermed heating elements constituting the heating portion according to image data, the color material of the color material layer of the thermal transfer sheet to the image receiving paper by transferring a thermal transfer printer for printing the image data to the image receiving paper having a receiving layer on both sides, a thermal transfer printing system composed of the image receiving paper,
The thermal transfer printer is
Image acquisition means for acquiring the image data;
A set direction confirmation means for detecting a detection mark on the image receiving paper and confirming a setting direction of the image receiving paper;
When the setting direction confirmation unit determines that the setting direction of the image receiving paper is correct, printing means for printing the image data on the image receiving paper;
Equipped with,
The detection mark is a hole formed in the image receiving paper,
Protrusions are provided on the cylindrical surface of the platen roller,
The thermal transfer printing system, wherein the setting direction confirmation unit detects the hole by fitting the hole of the image receiving paper into the protrusion and confirms the setting direction of the image receiving paper .

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