KR20060007136A - Method and apparatus of printing using shuttle tph(thermal print head) - Google Patents

Abstract

The present invention relates to a printing method and apparatus using a shuttle type thermal transfer head for printing on media by moving the thermal transfer head laterally in a printing apparatus using a thermal transfer head. The method comprises the steps of: (a) printing an image on the media using the thermal transfer head while conveying the media in the longitudinal forward direction; (b) moving the thermal transfer head laterally by a predetermined value; And (c) printing the image onto the media using the thermal transfer head while conveying the media in the longitudinal reverse direction.

According to the present invention, the thermal transfer head can be moved laterally to print on the media, so that even if the print area of the media is large, the thermal transfer head can be printed using the existing small thermal transfer head without increasing the size of the thermal transfer head. In addition, the instantaneous energy consumption and the increase in heat generated by using a large thermal head can be reduced.

Description

Method and apparatus for printing using thermal transfer head of shuttle method {Method and apparatus of printing using shuttle TPH (Thermal Print Head)}

1 is a perspective view showing a general configuration of a thermal transfer printing apparatus.

Figure 2 is a block diagram showing the configuration of a printing apparatus using a shuttle thermal transfer head according to the present invention.

3 is a detailed block diagram illustrating an embodiment of the TPH driving unit of FIG. 2.

4 is a detailed block diagram illustrating an embodiment of the driving unit of FIG. 3.

5 is a block diagram showing the configuration of an apparatus for controlling a thermal transfer head.

6 is a block diagram showing the configuration of a printing apparatus using two shuttle thermal transfer heads.

7 is a flowchart illustrating a printing method using a shuttle thermal transfer head according to the present invention.

8A to 8C are views illustrating an embodiment of a printing method using a shuttle thermal transfer head.

FIG. 9 is a flowchart illustrating an exemplary embodiment of printing while transferring the media of FIG. 7 in a forward / reverse direction.

 10A to 10C are diagrams showing an embodiment of a printing method using two shuttle thermal transfer heads.

The present invention relates to a printing method and apparatus using a thermal transfer head, and more particularly, to a printing method and apparatus using a shuttle type thermal transfer head capable of printing by moving the thermal transfer head laterally.

The thermal transfer printing apparatus applies a heat transfer head to an ink ribbon in contact with the media to transfer ink to the media to form an image, or a thermal transfer head on a media on which an ink layer expresses a predetermined color in response to heat. Refers to an apparatus for forming an image by applying heat.

1 is a perspective view showing a general configuration of a thermal transfer printing apparatus. The illustrated printing apparatus includes a thermal transfer head 100, a thermal transfer head nozzle 110, a platen roller 120, and a transfer unit 130, and the transfer unit 130 includes a motor 140 and a driving roller 150. ), The driven roller 160 and the media sensor 170.

The thermal transfer head 100 applies heat to the media transferred by the transfer unit 130. The thermal transfer head nozzle 110 supplies the ink required for printing to the platen roller 120, respectively. The platen roller 120 faces the thermal transfer head 100 with the media therebetween to support the media so that the ink can be adsorbed, and rotates according to the transfer of the media.

The motor 140 is a driving source for supplying the media to be printed to the thermal transfer head 100, and the driving roller 150 is engaged with the motor 140 to rotate and transport the media. The driven roller 160 is rotated in engagement with the drive roller 150 with the media interposed therebetween to convey the media. The media sensor 170 detects a position of media to be printed.

As described above, in the case of printing using the thermal transfer head according to the prior art, it is not possible to print a print area having a lateral length longer than the length of the thermal transfer head, and in order to print on a large size of media, thermal transfer is appropriately performed. The size of the head must be increased. Therefore, as the size of the thermal transfer head increases, the production cost of the printing apparatus is increased, and the instantaneous power consumption and heat generation of the printing apparatus are increased.

The technical problem to be achieved by the present invention, in order to solve the above problems in printing using the thermal transfer head, by allowing the thermal transfer head to move laterally, a large size using a small thermal transfer head The present invention provides a printing method and apparatus using a shuttle thermal transfer head capable of printing on media.

The printing method using the shuttle thermal transfer head according to the present invention for solving the above technical problem, (a) printing the image on the media using the thermal transfer head, while transporting the media in the longitudinal forward direction. step; (b) moving the thermal transfer head laterally by a predetermined value; And (c) printing the image onto the media using the thermal transfer head while transferring the media in the longitudinal reverse direction.

Preferably, the predetermined value in steps (a) and (c) is the lateral length of the thermal transfer head.

The step (c) may include calculating a lateral length of the area to be printed remaining in the media, and comparing the calculated lateral length with the lateral length of the thermal transfer head; As a result of the comparison, if the calculated transverse length is equal to or greater than the transverse length of the thermal transfer head, printing an image on the media using all the bits of the thermal transfer head while transporting the media in the longitudinal reverse direction. ; And as a result of the comparison, when the calculated transverse length is less than the transverse length of the thermal transfer head, the media is transferred to the media using only the bits corresponding to the calculated transverse length of the thermal transfer head while transferring the media in the longitudinal reverse direction. It is preferable to include printing an image.

Preferably, the thermal transfer head comprises: a first thermal transfer head that heats the media to print at least one or more of yellow, magenta, and cyan data; And a second thermal transfer head configured to apply heat to media for printing the remaining data except for the data printed by the first thermal transfer head among the three data.

When the thermal transfer head is composed of first and second thermal transfer heads, the step (a) is performed after the first thermal transfer head applies heat to the media while transferring the media in the longitudinal forward direction, and then the second thermal transfer. Preferably, a head is used to heat the media to print an image, and in the step (c), the first thermal transfer head heats the media while transferring the media in the longitudinal reverse direction. It is preferable that the heads heat the media to print an image.

Preferably, the printing method comprises the steps of: (d) checking whether there is an area to be printed on the media; And (e) printing the image on the media by using the thermal transfer head while moving the thermal transfer head laterally by a predetermined value and then transferring the media in the longitudinal forward direction when the area to be printed remains. It further includes.

In the step (e), if the area to be printed (e1) remains, calculating the transverse length of the remaining area to be printed on the media, and comparing the calculated transverse length with the transverse length of the thermal transfer head. ; (e2) if the calculated transverse length is greater than or equal to the transverse length of the thermal transfer head, printing an image on the media using all the bits of the thermal transfer head while transporting the media in the longitudinal forward direction; ; And (e3) when the calculated transverse length is less than the transverse length of the thermal transfer head, using only bits corresponding to the calculated transverse length of the thermal transfer head while transporting the media in the longitudinal forward direction. It is preferable to include printing an image on the media.

The printing apparatus using a shuttle thermal transfer head according to the present invention for solving the above technical problem, the transfer unit for transferring the media in the longitudinal forward / reverse direction; A thermal transfer head for printing an image by applying heat to the media conveyed by the conveying unit; And it characterized in that it comprises a TPH drive for moving the thermal transfer head in the transverse side.

Preferably, the TPH driving unit, a print check unit for confirming whether a print area remains in the media; And a driving unit for moving the thermal transfer head laterally by a predetermined value when a print area remains.

It is preferable that the predetermined value is a lateral length of the thermal transfer head.

Preferably, the printing apparatus further includes a TPH control unit for controlling the thermal transfer head to apply heat to the media using only bits corresponding to a print area remaining in the media.

Preferably, the TPH control unit, the length calculation unit for calculating the lateral length of the print area remaining in the media; A length comparison part comparing the calculated transverse length and the transverse length of the thermal transfer head; And using all the bits of the thermal transfer head when the calculated transverse length is greater than or equal to the transverse length of the thermal transfer head, and when less than one, use only bits corresponding to the calculated transverse length of the thermal transfer head to heat the media. It includes a bit control unit for controlling the thermal transfer head to apply.

The TPH driving unit, the motor for moving the thermal transfer head; An encoder for converting and outputting an operation of the motor into an electrical signal; A distance calculator configured to calculate a moving distance of the motor using the electrical signal; And a motor controller for controlling the operation of the motor by using the calculated movement distance and the predetermined value.

Preferably, the thermal transfer head comprises: a first thermal transfer head that heats the media to print at least one of yellow, magenta, and cyan data; And a second thermal transfer head configured to apply heat to media for printing the remaining data except for the data printed by the first thermal transfer head among the three data.

When the thermal transfer head is composed of first and second thermal transfer heads, the THP driver may include: a first TPH driver configured to move the first thermal transfer head laterally; And a second TPH driving unit which moves the second thermal transfer head laterally.

The printing method using the thermal transfer head of the shuttle method may be embodied as a computer-readable recording medium recording a program for execution in a computer.

Hereinafter, a printing method and apparatus using a shuttle thermal transfer head according to the present invention will be described in detail with reference to the accompanying drawings. 7 is a flowchart illustrating a printing method using a shuttle thermal transfer head according to the present invention. 2 is a block diagram illustrating a configuration of a printing apparatus using a shuttle thermal transfer head according to the present invention. The illustrated printing apparatus includes a transfer unit 200, a thermal transfer head 210, and a TPH driving unit 220. The printing method shown in FIG. 7 will be described with reference to the printing device shown in FIG. 2.

The transfer unit 200 transfers the media 230 at a predetermined printing speed in the longitudinal forward direction, and the thermal transfer head 210 applies an image to the media 230 transferred by the transfer unit 200 to generate an image. Print (step 700).

The THP driver 220 checks whether printing is completed (step 710), and if the printing is not completed, moves the thermal transfer head 210 laterally by a predetermined value (step 720). The predetermined value is a movement distance preset by the user, and is preferably set to the lateral length of the thermal transfer head 210. 3 is a block diagram of an embodiment of the THP driver, and the TPH driver 220 includes a print checker 300 and a driver 310. The print confirming unit 300 checks whether the printing has been completed in all the print areas to be printed, and the driving unit 310 receives the signal of the print completion from the print confirming unit, and when the printing is not completed, the thermal transfer. Move the head laterally.

The transfer unit 200 transfers the media 230 at a predetermined printing speed in the longitudinal reverse direction, and the thermal transfer head 210 applies an image to the media 230 transferred by the transfer unit 200 to generate an image. Print (step 730).

The THP driver 220 checks whether the printing has been completed in the printing area to be printed (step 740), and if the printing is not completed, moves the thermal transfer head 210 laterally by a predetermined value (step 750). ), Repeating steps 700 to 740.

8A to 8C show an embodiment of a printing method using a shuttle thermal transfer head. Referring to FIG. 8A, the media is transferred in the longitudinal forward direction A1 in order to apply heat to the area 800 to be printed in the media 230 using the thermal transfer head 210 having a length of x, The thermal head 210 prints by applying heat to the media 230 to be transferred.

Referring to FIG. 8B, after the thermal transfer head 210 applies heat to the longitudinal end of the media 230 to print a print area corresponding to the transverse length x of the media 230, the thermal transfer head has a transverse direction (B). Go to).

 Referring to FIG. 8C, after the thermal transfer head 210 is moved laterally (B) x, the media 230 is transferred in the longitudinal reverse direction A2, and the thermal transfer head 210 is transferred to the media. Heat 230 to print. The thermal transfer head 210 repeats the above process until the printing is completed in the print area 800 and prints on the media 230.

FIG. 9 is a flowchart illustrating an embodiment of printing while transferring the media of FIG. 7 in a forward / reverse direction. 5 is a block diagram showing the configuration of an apparatus for controlling a thermal transfer head. The illustrated control device includes a length calculator 500, a length comparator 510, and a bit controller 520. The embodiment shown in FIG. 9 will be described with reference to the control device shown in FIG. 5.

The length calculator 500 calculates the horizontal length of the remaining area to be printed (step 900). In the method for calculating the lateral length, for example, the lateral length of the area to be printed is stored in advance, and the moving distance is changed from the lateral length of the stored print area whenever the thermal transfer head 210 is moved laterally. By subtracting, the transverse length of the remaining area to be printed can be calculated.

The length comparison unit 510 compares the calculated transverse length with the transverse length of the thermal transfer head 210 (step 910). As a result of comparison, when the calculated transverse length of the remaining print area is greater than or equal to the transverse length of the thermal transfer head 210, the bit control unit 520 prints the thermal transfer head 210 using all the bits. Control (step 920).

If the calculated lateral length of the remaining print area is less than the lateral length of the thermal transfer head 210, the bit control unit 520 is the thermal transfer head 210 is the lateral length of the remaining print area of all the bits. Control to print using only the bit corresponding to the (step 930).

For example, if you want to print on an 8-inch by 10-inch print area using a 3-inch long, 300dpi thermal head, the media 230 will be transported in the longitudinal forward direction, 3 inches wide. When the area is printed and the medium 3 inches is printed while the media 230 is conveyed in the longitudinal reverse direction, the horizontal length of the remaining print area is 2 inches. Accordingly, the bit control unit 520 controls the thermal transfer head 210 to heat and print the media 230 using only 600 bits corresponding to 2 inches of 900 bits, which are all bits.

10A to 10C illustrate a printing method using two shuttle thermal transfer heads. 6 is a block diagram showing a configuration of a printing apparatus using two shuttle type thermal transfer heads. The illustrated printing apparatus includes a transfer unit 200, a first thermal transfer head 600, a second thermal transfer head 610, a first TPH driver 620, and a second TTP driver 630. The printing method illustrated in FIGS. 10A to 10C will be described with reference to the printing apparatus illustrated in FIG. 6.

 10A, the transfer unit 200 transfers the media 230 in the longitudinal forward direction A1, and the first thermal transfer head 600 first applies heat to the transferred media 230. The second thermal transfer head 610 sequentially heats and prints the media 230.

The media 230 has ink layers of a predetermined color formed on both sides of a base sheet, and each ink layer preferably has a single layer structure by a single color ink or a multi-layer structure for expressing two or more colors. For example, the ink layer of the first surface may be provided with two layers for the yellow and magenta colors, and the ink layer of the second surface may be provided with one layer for the cyan colors. Yellow and magenta colors of the ink layer of the first surface may be selectively expressed by the temperature and the heating time of the first thermal transfer head 600. For example, when the first thermal transfer head 600 is heated at a high temperature for a short time, a yellow color may be expressed, and when the first thermal transfer head 600 is heated at a low temperature, a magenta color may be expressed. The cyan color of the ink layer of the second surface may be expressed by the second thermal transfer head 610 applying heat.

Referring to FIG. 10B, the first thermal transfer head 600 and the second thermal transfer head 610 are printed by applying heat to a longitudinal end of the print area 1000 of the media 230, and then printing the first TPH driver. 620 and the second TTP driving unit 630 are moved in the lateral direction B. FIG.

 Referring to FIG. 10C, the transfer unit 200 transfers the media 230 in the longitudinal reverse direction A2, and the second thermal transfer head 610 first heats the transferred media 230. The first thermal transfer head 600 sequentially heats and prints the media 230. The first thermal transfer head 600 and the second thermal transfer head 610 are repeatedly printed on the media 810 until the printing is completed in the print area 1000.

The invention can also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like, which are also implemented in the form of carrier waves (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

Although a preferred embodiment of the present invention has been described in detail above, those skilled in the art to which the present invention pertains can make various changes without departing from the spirit and scope of the invention as defined in the appended claims. It will be appreciated that modifications or variations may be made. Accordingly, modifications to future embodiments of the present invention will not depart from the technology of the present invention.

According to the printing method and apparatus using the shuttle thermal transfer head according to the present invention as described above, it is possible to print on the media by moving the thermal transfer head laterally so that even if the print area of the media is large, It is possible to print using existing small sized thermal head without increasing the size, thereby reducing energy consumption and heat generation at the moment caused by using large sized thermal head.

Claims (17)

In the printing method using a thermal transfer head for printing by applying heat to the media, (a) printing an image onto the media using the thermal transfer head while transferring the media to the longitudinal side; (b) moving the thermal transfer head laterally by a predetermined value; And (c) printing the image on the media using the thermal transfer head while transferring the media to the longitudinal side. The method of claim 1, wherein the predetermined value in steps (a) and (c) is A printing method using a thermal transfer head of the shuttle method, characterized in that the lateral length of the thermal transfer head. The method of claim 1, wherein step (c) comprises: Calculating a transverse length of the area to be printed remaining in the media, and comparing the calculated transverse length with the transverse length of the thermal transfer head; As a result of the comparison, if the calculated transverse length is equal to or greater than the transverse length of the thermal transfer head, printing an image on the media using all the bits of the thermal transfer head while transporting the media in the longitudinal reverse direction. ; And As a result of the comparison, when the calculated transverse length is less than the transverse length of the thermal transfer head, images are recorded on the media using only bits corresponding to the calculated transverse length of the thermal transfer head while transferring the media in the longitudinal reverse direction. Printing method using a thermal transfer head of the shuttle method comprising the step of printing. The method of claim 1, wherein the thermal transfer head, A first thermal transfer head that heats the media to print at least one of yellow, magenta, and cyan data; And And a second thermal transfer head configured to apply heat to media for printing the remaining data except for the data printed by the first thermal transfer head, among the three data. . The method of claim 5, wherein step (a) And the second thermal transfer head applies heat to the media to print the image after the first thermal transfer head heats the media while transferring the media in the longitudinal forward direction. Printing method using. The method of claim 5, wherein step (c) comprises: A shuttle type thermal transfer, wherein the second thermal transfer head heats the media while transferring the media in a longitudinal reverse direction, and then the first thermal transfer head heats the media to print an image. Printing method using head. The method of claim 1, (d) checking whether there is an area to be printed on the media; And (e) if the area to be printed remains, moving the thermal transfer head laterally by a predetermined value and then transporting the media in the longitudinal forward direction, printing an image on the media using the thermal transfer head. Printing method using a thermal transfer head of the shuttle method further comprising. The method of claim 7, wherein step (e) (e1) if the area to be printed remains, calculating the transverse length of the remaining area to be printed on the media, and comparing the calculated transverse length with the transverse length of the thermal transfer head; (e2) if the calculated transverse length is greater than or equal to the transverse length of the thermal transfer head, printing an image on the media using all the bits of the thermal transfer head while transporting the media in the longitudinal forward direction; ; And (e3) as a result of the comparison, when the calculated transverse length is less than the transverse length of the thermal transfer head, using only the bits corresponding to the calculated transverse length of the thermal transfer head while transferring the media in the longitudinal forward direction. A printing method using a shuttle thermal transfer head comprising the step of printing an image on the media. A conveying unit which conveys the media to the longitudinal side; A thermal transfer head for printing an image by applying heat to the media conveyed by the conveying unit; And Printing apparatus using a thermal transfer head of the shuttle method comprising a TPH driving unit for moving the thermal transfer head in the transverse side. The method of claim 9, wherein the TPH driving unit, A print checking unit for checking whether a print area remains on the media; And And a driving unit for moving the thermal transfer head laterally by a predetermined value when a print area remains. The method of claim 10, wherein the predetermined value is, Printing apparatus using a thermal transfer head of the shuttle method, characterized in that the lateral length of the thermal transfer head. The method of claim 9, And a TPH controller for controlling the thermal transfer head to apply heat to the media using only bits corresponding to a print area remaining in the media. The method of claim 12, wherein the TPH control unit, A length calculator for calculating a transverse length of the print area remaining in the media; A length comparison part comparing the calculated transverse length and the transverse length of the thermal transfer head; And When the calculated transverse length is greater than or equal to the transverse length of the thermal transfer head, all the bits of the thermal transfer head are used. And a bit control unit for controlling the thermal transfer head to be applied. The method of claim 9, wherein the TPH driving unit, A motor for moving the thermal transfer head; An encoder for converting and outputting an operation of the motor into an electrical signal; A distance calculator configured to calculate a moving distance of the motor using the electrical signal; And And a motor controller for controlling the operation of the motor using the calculated movement distance and the predetermined value. The method of claim 9, wherein the thermal transfer head, A first thermal transfer head that heats the media to print at least one of yellow, magenta, and cyan data; And And a second thermal transfer head configured to apply heat to media for printing the remaining data except for the data printed by the first thermal transfer head among the three data. . The method of claim 15, wherein the THP drive unit, A first TPH driver moving the first thermal transfer head laterally; And And a second TTP driving unit for moving the second thermal transfer head laterally. A computer-readable recording medium having recorded thereon a program for executing the method according to any one of claims 1 to 8.

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