JP2019064002A - Plate-making device - Google Patents

Abstract

To provide a plate-making device which can make a plate capable of reducing deterioration of printing image quality.SOLUTION: A control part so controls electric power sources 37A, 37B as to set a same voltage according to an average resistance value of a heater element 36 of the whole thermal head 23 to blocks 23a, 23b when a plate-making image straddles a border between the blocks 23a, 23b. When there is no plate-making image straddling the block border, the control part so controls the electric power sources 37A, 37B as to set an individual voltage according to an average resistance value of the heater element 36 in each of the blocks 23a, 23b to the blocks 23a, 23b.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a plate making apparatus for making a master.

  There is known a plate making apparatus which uses a thermal head to make a master for stencil printing. The thermal head has a plurality of heating elements arranged along the main scanning direction, and the masters are perforated by the heating elements to make a plate.

  Among such plate making apparatuses, there are apparatuses for setting a voltage for each of a plurality of blocks divided in the main scanning direction with respect to a thermal head. For example, in a plate-making apparatus for making a wide plate such as A2 width, a voltage is set for each of a plurality of blocks with respect to a thermal head (for example, see Patent Document 1). In this case, a voltage corresponding to the average resistance value of the heating element is set for each block. Thereby, the variation in the diameter of the perforation due to the variation in the resistance value of the heating element is reduced. As a result, variations in density in a printed image using a master made of a plate can be suppressed.

JP, 2013-169737, A

  However, if the voltage according to the average resistance value of the heating element is set for each block as described above, the difference in the setting voltage between the blocks causes the power (energy) between the heating elements adjacent to each other across the block boundary to The difference may be large. As a result, the difference in diameter between the heating elements adjacent to each other across the block boundary may be large. For this reason, a difference in density may be noticeable between one side and the other side of the block boundary in the print image corresponding to the plate-making image across the block boundary, and the print image quality may be degraded.

  If the voltage corresponding to the average resistance value of the heating elements in the entire thermal head is set to the entire thermal head, the difference in power between the adjacent heating elements across the block boundary can be suppressed as described above. For this reason, the difference in density between one side and the other side of the block boundary in the print image corresponding to the plate-making image across the block boundary becomes less noticeable.

  However, in this case, the variation in the diameter of the perforation due to the variation in the power of the heating element in the entire thermal head becomes large. As a result, the variation in density in the entire printed image printed using the plate made is large, and the printing image quality may be degraded. For example, in the case of making a plurality of mark images into a single plate by marking plate making, there is a possibility that the density of each mark image in the print image may vary.

  The present invention has been made in view of the above, and it is an object of the present invention to provide a plate making apparatus capable of making a plate capable of reducing deterioration in print image quality.

  In order to achieve the above object, according to one aspect of the present invention, a plurality of heating elements are arrayed along the main scanning direction, and the resistance value of the plurality of heating elements has continuity along the main scanning direction. A thermal head including a resistor and forming a plate-making image by forming a plate-making image by drilling through a master with the heating element, and supplying a voltage to the thermal head for each of a plurality of blocks divided in the main scanning direction by the heating resistor. The same voltage according to the average resistance value of the heating elements of the plurality of blocks is set for the plurality of blocks continuing through the boundary between the power supply unit and the blocks across the plate-making image. The power supply unit is controlled to set a voltage according to the average resistance value of the heating element in the block for the block where there is no plate-making image across the boundary between the adjacent blocks. Plate making apparatus is provided, characterized in that it comprises a control unit for.

  According to another aspect of the present invention, a thermal head is formed by connecting a plurality of blocks each having a heating resistor in which a plurality of heating elements are arranged, and forming a plate-making image by drilling through a master by the heating elements. And a power supply unit for supplying a voltage to each of the plurality of blocks with respect to the thermal head, and a plurality of platemaking images across the plurality of blocks continuing via the boundary between the blocks across the platemaking image. The voltage of each block is set so that the electric powers of the heating elements adjacent to each other across the boundary become equal at the boundary, and for the block where there is no plate-making image across the boundary between the adjacent blocks A control unit configured to control the power supply unit to set a voltage according to an average resistance value of the heating element in the block Edition device is provided.

  According to the plate-making apparatus of the present invention, it is possible to make a plate capable of reducing deterioration in print image quality.

It is a whole perspective view of the platemaking apparatus which concerns on 1st Embodiment. It is a schematic block diagram of the thermal head in 1st Embodiment. It is a control block diagram of the platemaking apparatus shown in FIG. It is a flowchart of the voltage setting system determination process in 1st Embodiment. It is a figure which shows an example of the platemaking image which straddles a block boundary. It is a figure which shows an example of the image pattern which does not have the platemaking image which straddles a block boundary. (A) is a figure which shows an example of the image pattern before arrangement | positioning adjustment of a platemaking image. (B) is a figure which shows an example of the image pattern after arrangement | positioning adjustment of the platemaking image with respect to the image pattern of (a). It is a figure which shows an example of the resistance value of the heating element in the thermal head of 1st Embodiment, and a setting voltage. It is a figure for demonstrating the power difference of two adjacent heating elements on both sides of the block boundary in the case of an individual voltage setting system. It is a figure for demonstrating the electric power difference of two adjacent heating elements on both sides of the block boundary in the case of the whole voltage setting system. It is a schematic block diagram of the thermal head in 2nd Embodiment. It is a figure which shows an example of the resistance value of the heating element in the thermal head of 2nd Embodiment, and a setting voltage.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same or equivalent parts or components are denoted by the same or equivalent reference numerals throughout the drawings.

  The embodiment shown below exemplifies an apparatus etc. for embodying the technical idea of this invention, and the technical idea of this invention is the material, shape, structure, arrangement etc. of each component. Does not specify the following. Various changes can be added to the technical idea of the present invention within the scope of the claims.

First Embodiment
FIG. 1 is an overall perspective view of a plate making apparatus according to a first embodiment of the present invention. FIG. 2 is a schematic block diagram of a thermal head of the plate making apparatus shown in FIG. FIG. 3 is a control block diagram of the plate making apparatus shown in FIG. In the following description, upper, lower, left, right, front and rear indicated by arrows in FIG.

  As shown in FIG. 1, the plate-making apparatus 1 according to the first embodiment includes a housing 2, a plate-making unit 3, a moving mechanism unit 4, a movable positioning member 5, guide shafts 6A and 6B, and a control unit. And 7.

  The housing 2 accommodates each part of the plate making apparatus 1. The housing 2 is formed in a box shape whose upper side is open.

  The plate making unit 3 makes the frame master 11. The framed master 11 is obtained by stretching the master 13 on a rectangular frame 12. The framed master 11 is set in the plate-making apparatus 1 such that the front end is supported by a support (not shown) provided on the housing 2 and the rear end is supported by the movable positioning member 5. In the master 13 of the frame master 11, a heat melting film made of a thermoplastic resin is adhered by an adhesive to a mesh-like ridge formed by knitting warps and wefts made of silk, synthetic resin, stainless steel, etc. It is formed.

  As shown in FIGS. 1 and 3, the plate making unit 3 includes a platen roller 21, a platen cover 22, a thermal head 23, a thermal head power supply unit 24 (corresponding to a power supply unit in the claims), and a head base 25. Equipped with

  The platen roller 21 presses the master 13 of the framing master 11 from the upper side to the thermal head 23. The platen roller 21 is formed in a cylindrical shape elongated in the left-right direction. The platen roller 21 is urged toward the thermal head 23 by a spring (not shown).

  The platen cover 22 covers the platen roller 21 and rotatably holds the platen roller 21. The platen cover 22 is rotatably attached to sliders 41A and 41B, which will be described later, around a pivot shaft 22a.

  The thermal head 23 pierces the master 13 of the framed master 11 to form a plate-making image. The thermal head 23 is disposed below the master 13 of the framed master 11 set in the plate making apparatus 1. The thermal head 23 has an elongated shape in the left-right direction. The thermal head 23 is a long thermal head capable of making a wide plate such as A2 width.

  As shown in FIG. 2, the thermal head 23 includes a heating resistor 31, a plurality of driver ICs 32, and electrodes 33A, 33B, 34A, 34B.

  The heating resistor 31 has a plurality of heating elements 36 arranged at predetermined intervals along the main scanning direction (left and right direction). The heating resistor 31 is formed to extend from the left end to the right end of the thermal head 23.

  The heating element 36 generates heat when a voltage is applied, and the master 13 is perforated. Each heating element 36 is formed by removing the portion of the wiring material layer stacked on the heating resistor material forming the heating resistor 31 to form the heating element 36 and exposing the heating resistor material. Here, the wiring material layer is made of a material that constitutes a wiring for connecting the heating element 36 and the driver IC 32.

  Each heating element 36 is formed to have a predetermined resistance value. However, the resistance value of each heating element 36 has a variation due to a manufacturing error. In addition, since each heating element 36 is formed of one heating resistor material as described above, the resistance value of the heating element 36 in the heating resistor 31 has continuity along the main scanning direction. (See FIG. 8). That is, although there is variation in the resistance value of each heating element 36, the difference in resistance value between adjacent heating elements 36 is suppressed to a predetermined value or less.

  The driver IC 32 selectively drives the plurality of heating elements 36 based on the image data for plate making. Each driver IC 32 drives a plurality of heating elements 36 allocated to each driver IC 32. Here, the image data for platemaking is data indicating the presence or absence of perforation for each pixel.

  The electrodes 33A, 33B, 34A, and 34B are electrodes for supplying the voltage from the thermal head power supply unit 24 to the heating element 36 of the heating resistor 31.

  Here, in the plate making apparatus 1, voltages are separately supplied to the thermal head 23 to the left block 23 a and the right block 23 b into which the heating resistor 31 is divided. That is, the thermal head 23 is divided into the block 23 a on the left and the block 23 b on the right according to the voltage supply source.

  The electrodes 33A and 33B are for supplying a voltage from the power supply 37A of the thermal head power supply unit 24 described later to the heating element 36 of the block 23a on the left side. The electrodes 34A and 34B are for supplying the voltage from the power supply 37B to the heating element 36 of the block 23b on the right side. The electrodes 33A and 34A are power supply electrodes to which a power supply voltage is supplied, and the electrodes 33B and 34B are ground electrodes.

  The thermal head power supply unit 24 supplies the thermal head 23 with a voltage for driving the heating element 36. The thermal head power supply unit 24 has power supplies 37A and 37B. The power supply 37A supplies a voltage to the block 23a on the left side of the thermal head 23. The power supply 37 B supplies a voltage to the block 23 b on the right side of the thermal head 23.

  The head base 25 supports the thermal head 23. The head base 25 is formed in an elongated plate shape in the left-right direction. The head base 25 is fixed to sliders 41A and 41B described later.

  The moving mechanism unit 4 moves the plate making unit 3 in the front-rear direction (sub scanning direction). The moving mechanism unit 4 includes sliders 41A and 41B and a moving motor 42.

  The sliders 41A and 41B move in the front-rear direction along the guide shafts 6A and 6B in order to move the plate making unit 3 in the front-rear direction. The sliders 41A and 41B are disposed apart from each other in the left-right direction. The sliders 41A and 41B are configured to be movable in the front-rear direction by the driving force of the moving motor 42. The platen cover 22 is connected to the sliders 41A and 41B, and the head base 25 is connected to the sliders 41A and 41B. Thereby, the plate making unit 3 is moved in the front-rear direction together with the sliders 41A and 41B.

  The moving motor 42 generates a driving force for moving the sliders 41A and 41B.

  The movable positioning member 5 supports the frame 12 at the rear end portion of the framing master 11. The movable positioning member 5 is movable in the front-rear direction along the guide shafts 6A and 6B. The movable positioning member 5 includes a frame mounting portion 46 and sliders 47A and 47B.

  The frame mounting portion 46 is a portion that supports the rear end portion of the frame 12. The frame mounting portion 46 is formed in an elongated shape in the left-right direction.

  The sliders 47A and 47B are portions that support the frame mounting portion 46 and move in the front-rear direction along the guide shafts 6A and 6B. The sliders 47A and 47B are connected to the left end and the right end of the frame mounting portion 46, respectively.

  The guide shafts 6A and 6B guide the movement of the sliders 41A and 41B and the movable positioning member 5 in the front-rear direction. The guide shafts 6A and 6B are formed in an elongated shape extending in the front-rear direction, and are spaced apart from each other in the left-right direction in the housing 2 and installed.

  The control unit 7 controls the operation of each unit of the plate making apparatus 1. The control unit 7 includes a CPU, a RAM, a ROM, a hard disk, and the like.

  At the time of plate making, when the plate making image crosses the boundary (block boundary) between the blocks 23a and 23b at the time of plate making, the control unit 7 sets the power supplies 37A and 37B to set voltages in the blocks 23a and 23b by the whole voltage setting method. Control. The whole voltage setting method is a method of setting the same voltage according to the average resistance value of the heating element 36 of the entire thermal head 23 for both blocks 23a and 23b.

  If there is no plate-making image that crosses the block boundary, the control unit 7 controls the power supplies 37A and 37B to set the voltage to the blocks 23a and 23b by the individual voltage setting method. The individual voltage setting method is a method of setting an individual voltage according to the average resistance value of the heating element 36 in each of the blocks 23a and 23b with respect to the blocks 23a and 23b.

  Next, the operation of the plate making apparatus 1 for making the frame master 11 will be described.

  When the plate master 11 is subjected to plate making, the control unit 7 performs voltage setting method determination processing. The voltage setting method determination process is a process of determining the voltage setting method for the blocks 23a and 23b of the thermal head 23 as the above-described overall voltage setting method or the individual voltage setting method.

  The voltage setting method determination process will be described with reference to the flowchart of FIG.

  In step S1 of FIG. 4, the control unit 7 determines, based on the image data for plate making, whether or not there is a plate making image across the block boundary. When the main scanning line in which two pixels adjacent to each other across the block boundary are both included in the main scanning line in the image data is included in the main scanning line in the image data, the plate-making image straddling the block boundary is I judge that there is. The control unit 7 stores the position of the block boundary on the image data in advance.

  Here, for example, the plate-making image 51 shown in FIG. 5 crosses a block boundary. On the other hand, for example, in the case of the image pattern in which the plate-making image 52 is disposed as shown in FIG. 6, the block boundary passes through the blank portion and there is no plate-making image 52 straddling the block boundary. Here, the image pattern of FIG. 6 is an image pattern of marking plate making in which a plurality of plate making images 52 which are mark images are arranged.

  Returning to FIG. 4, when it is determined that there is a plate-making image that crosses a block boundary (step S1: YES), in step S2, the control unit 7 adjusts the arrangement of the plate-making image so that the plate-making image does not cross the block boundary. Determine if you can.

  Specifically, when the block boundary can be adjusted to pass through the blank portion by shifting the plate-making image in the main scanning direction, the plate-making image does not cross the block boundary by adjusting the arrangement of the plate-making image. Can.

  For example, in the image pattern in which the plate-making images 52 are arranged as shown in FIG. 7A, the block boundaries are made into the plate-making images 52 as shown in FIG. 7B by shifting the plate-making images 52 in the main scanning direction. It is possible that there is no straddling. Thus, even if the arrangement of the plate-making image 52 is adjusted, the content of the print image can be substantially maintained.

  By the way, in the image pattern of the marking plate-making as shown in FIG. 7, the relative positional relationship between the plate-making images 52 can be changed since each mark image is separated and used in the printed matter. For this reason, for example, it is also possible to make the plate border image not straddle the block border by shifting only each plate-making image 52 in the second row from the left in the third row to the left.

  Here, for example, in the case of the plate-making image 51 of FIG. 5, in order to shift the plate-making image 51 so that the block boundary passes through the blank portion, the range of the plate size shown by the rectangle surrounding the plate-making image 51 is exceeded. It is necessary to shift the plate-making image 51. For this reason, in this case, it is impossible to adjust the blank portion so that the block boundary passes by shifting the plate making image 51 in the main scanning direction.

  Returning to FIG. 4, when it is determined that the block making image does not straddle the block boundary by adjusting the arrangement of the plate making image (step S2: YES), the control unit 7 determines the block boundary in step S3. The arrangement of the plate-making images in the image data is adjusted so that the plate-making images do not cross over.

  Next, in step S4, the control unit 7 determines the voltage setting method as the individual voltage setting method.

  The set voltage Va for the block 23a on the left side and the set voltage Vb for the block 23b on the right side in the individual voltage setting method are expressed by the following formulas (1) and (2), respectively.

Va = (P × Ra) ^1/2 (1)
Vb = (P × Rb) ^1/2 (2)
Here, Ra is an average resistance value of the heating element 36 in the block 23a. Rb is an average resistance value of the heating element 36 in the block 23 b. P is a set power for perforating the master 13 with a predetermined perforation diameter in the heating element 36.

  When it is determined in step S1 that there is no plate-making image across the block boundary (step S1: NO), the control unit 7 proceeds to step S4, and determines the voltage setting method as the individual voltage setting method.

  If it is determined in step S2 that the block boundaries can not be made to be across the platemaking image (step S2: NO), in step S5, the control unit 7 determines the voltage setting method as the entire voltage setting method. .

  The set voltage Vt in the overall voltage setting method is expressed by the following equation (3).

Vt = (P × Rt) ^1/2 (3)
Here, Rt is an average resistance value of all the heating elements 36 in the thermal head 23.

  When the voltage setting method for the blocks 23a and 23b is determined in step S4 or step S5, the voltage setting method determination process ends.

  When the voltage setting method is determined by the voltage setting method determination process, the control unit 7 controls the power supplies 37A and 37B to supply a voltage according to the determined voltage setting method to the blocks 23a and 23b.

  Then, the control unit 7 causes the thermal head 23 to form a perforated image based on the image data on the master 13 while moving the plate making unit 3 from the front end of the master 13 to the rear side by the moving mechanism unit 4.

  Here, FIG. 8 shows an example of the resistance value of the heating element 36 in the thermal head 23 and the above-mentioned set voltages Va, Vb and Vt.

  As described above, the resistance value of the heating element 36 has variations as shown in FIG. Therefore, the average resistances Ra and Rb of the heating elements 36 in each of the blocks 23a and 23b may be different from each other, and they may be different from the average resistance Rt of the heating elements 36 in the entire thermal head 23.

  In the example of FIG. 8, Ra = 3050 [Ω], Rb = 3250 [Ω], and Rt = 3150 [Ω]. Assuming that the set power P in the heating element 36 is 0.08 [W], Va = 15.6 [V], Vb = 16.1 [V], and Vt = from the above formulas (1) to (3). It will be 15.9 [V].

  Further, in the example of FIG. 8, as shown in FIG. 9 and FIG. 10, the resistance value R1 of the left heating element 36l of the two heating elements 36 adjacent to each other across the block boundary is 3105 [Ω]. The resistance value Rr of the heating element 36r is 3107 [Ω]. Here, as shown in FIG. 8, since the resistance value of each heating element 36 has continuity along the main scanning direction, the resistance value Rl and the resistance value Rr are substantially the same value.

  In the case of the individual voltage setting method, as shown in FIG. 9, the power Pl of the heating element 36l is 0.078 W, and the power Pr of the heating element 36r is 0.083 W. That is, a relatively large power difference occurs between the heating element 36l and the heating element 36r.

  In the case of the whole voltage setting method, as shown in FIG. 10, the electric power Pl of the heating element 36l is 0.081 [W], and the electric power Pr of the heating element 36r is Pr = 0.081 [W]. That is, there is almost no power difference between the heating element 36l and the heating element 36r.

  Here, the perforation diameter by the heating element 36 is proportional to the power. Also, the larger the perforation diameter, the higher the density in the printed image.

  Therefore, in the case of the individual voltage setting method, in the printed image, the difference in density between the pixel perforated by the heating element 36l and the pixel perforated by the heating element 36r is large. Therefore, when there is a plate-making image across the block boundary, using the individual voltage setting method, in the printed image corresponding to the plate-making image across the block boundary, the density difference is noticeable between one side and the other side of the block boundary There is.

  On the other hand, in the case of the entire voltage setting method, in the printed image, the difference in density between the pixel perforated by the heating element 36l and the pixel perforated by the heating element 36r hardly occurs.

  For this reason, in the plate making apparatus 1, as described above, when there is a plate making image across the block boundary, voltages are set to the blocks 23a and 23b by the entire voltage setting method.

  On the other hand, in the overall voltage setting method, the variation in the diameter of perforations of the heating elements 36 in the entire thermal head 23 becomes larger than in the individual voltage setting method.

  For example, as shown in FIG. 8, the resistance value Rmax = 3400 [Ω] in the heating element 36 having the largest resistance value and the resistance value Rmin = 2950 [Ω] in the heating element 36 having the smallest resistance value. Further, it is assumed that the heating element 36 with the largest resistance value is in the block 23b on the right side, and the heating element 36 with the smallest resistance value is in the block 23a on the left side.

In this case, the power Pmt = Vt ² /Rmax=0.073 [W] in the entire voltage setting method of the heating element 36 having the largest resistance value. Further, the resistance value becomes the power ^Pms = Vb 2 /Rmax=0.076[W] in individual voltage setting method of the maximum of the heating element 36. Further, the electric power Pnt = Vt ² /Rmin=0.085 [W] in the entire voltage setting method of the heating element 36 having the smallest resistance value. In addition, the power Pns in the individual voltage setting method of the heating element 36 having the smallest resistance value is Pns = Va ² /Rmin=0.082 [W].

  As described above, the powers Pmt and Pnt in the overall voltage setting method have a larger amount of deviation with respect to the set power P = 0.08 [W] than the powers Pms and Pns in the individual voltage setting method. That is, in the whole voltage setting method, the variation in power of each heating element 36 in the entire thermal head 23 becomes larger than in the individual voltage setting method, so the variation in the diameter of perforations by each heating element 36 becomes larger.

  For this reason, in the overall voltage setting method, the variation in density in the entire print image printed using the master 13 that has been made is greater than in the individual voltage setting method. From this, in the whole voltage setting method, for example, when printing and printing an image pattern of marking plate-making as shown in FIG. 6, the density of the printed image of each plate-making image 52 may vary.

  Therefore, in the plate making apparatus 1, as described above, when there is no plate making image across the block boundary, voltages are set to the blocks 23a and 23b by the individual voltage setting method.

  As described above, in the plate-making apparatus 1, when the plate-making image crosses the block boundary at the time of plate-making, the control unit 7 sets the power supply 37A to set the voltage to the blocks 23a and 23b by the overall voltage setting method, Control 37B. If there is no plate-making image that crosses the block boundary, the control unit 7 controls the power supplies 37A and 37B to set the voltage to the blocks 23a and 23b by the individual voltage setting method.

  Thereby, when there is a plate-making image straddling a block boundary, a plate that can suppress a difference in density between one side and the other side of the block boundary in the printed image corresponding to the plate-making image striding the block boundary is plate-making it can. In addition, when there is no plate-making image across the block boundary, it is possible to make a plate which can suppress variations in density in the entire print image. As a result, according to the plate making apparatus 1, it is possible to make a plate which can reduce the deterioration of the printing image quality.

  Further, in the case where the plate making image straddles the block boundary, if the plate making image does not straddle the block boundary by adjusting the arrangement of the plate making image, the plate making image does not straddle the block boundary. Adjust the arrangement of the platemaking image in the same way.

  As a result, even when the plate-making image originally crosses the block boundary, it is possible to set the voltage by the individual voltage setting method and perform plate-making while substantially maintaining the contents of the plate-making image. As a result, even when the plate-making image originally crosses the block boundary, it is possible to make the plate capable of reducing the variation in density in the entire print image while substantially maintaining the content of the print image.

Second Embodiment
Next, a second embodiment in which the thermal head and the voltage setting method of the first embodiment described above are changed will be described.

  FIG. 11 is a schematic configuration diagram of a thermal head in the second embodiment. As shown in FIG. 11, the thermal head 61 in the second embodiment is formed by connecting blocks 62A and 62B, each of which is a short thermal head, in the main scanning direction. Similar to the thermal head 23 of the first embodiment, the thermal head 61 is a long thermal head capable of making a wide plate such as A2 wide.

  The block 62A includes a heating resistor 63A, a plurality of driver ICs 32, and electrodes 33A and 33B. The block 62B includes a heating resistor 63B, a plurality of driver ICs 32, and electrodes 34A and 34B.

  The heating resistor 63A of the block 62A has a plurality of heating elements 36 arranged at predetermined intervals along the main scanning direction (left and right direction). The heating resistor 63 </ b> A is formed of the same one as the heating resistor 31 of the first embodiment in a short length. The heating resistor 63B of the block 62B has the same configuration as the heating resistor 63A.

  The heating resistor 63A of the block 62A and the heating resistor 63B of the block 62B are separately formed. Therefore, the resistance value of the heating element 36 does not have continuity between the blocks 62A and 62B (between the heating resistors 63A and 63B).

  The plurality of driver ICs 32 of the block 62A selectively drive the plurality of heating elements 36 of the heating resistor 63A of the block 62A based on the image data for plate making. The plurality of driver ICs 32 of the block 62B selectively drive the plurality of heating elements 36 of the heating resistor 63B of the block 62B based on the image data for plate making.

  The electrodes 33A and 33B of the block 62A are electrodes for supplying the voltage from the power supply 37A of the thermal head power supply unit 24 to the heating element 36 of the heating resistor 63A. The electrodes 34A and 34B of the block 62B are electrodes for supplying the voltage from the power supply 37B of the thermal head power supply unit 24 to the heating element 36 of the heating resistor 63B. The electrodes 33A and 34A are power supply electrodes to which a power supply voltage is supplied, and the electrodes 33B and 34B are ground electrodes.

  In the second embodiment, the power supply 37 A of the thermal head power supply unit 24 supplies a voltage to the block 62 A on the left side of the thermal head 61. The power supply 37 B supplies a voltage to the block 62 B on the right side of the thermal head 61.

  In the second embodiment, when the platemaking image straddles the boundary (block boundary) between the blocks 62A and 62B at the time of platemaking, the control unit 7 sets the voltage to the blocks 62A and 62B by the boundary reference method. The power supplies 37A and 37B are controlled. The boundary reference method is a method of setting an individual voltage in each of the blocks 62A and 62B so that the power of the heating elements 36 adjacent to each other across the block boundary becomes equal.

  If there is no plate-making image across the block boundary, the control unit 7 controls the power supplies 37A and 37B to set the voltage in the average resistance value reference method for the blocks 62A and 62B. The average resistance value reference system is the same system as the individual voltage setting system in the first embodiment. That is, the average resistance value reference method is a method of setting individual voltages according to the average resistance value of the heating element 36 in each of the blocks 62A and 62B to the blocks 62A and 62B.

  The voltage setting method determination process in the second embodiment is performed in the same procedure as the voltage setting method determination process in the first embodiment described above. However, in the case where the voltage setting method is determined to be the overall voltage setting method in the first embodiment, the boundary reference method is determined in the second embodiment. In the case where the voltage setting method is determined to be the individual voltage setting method in the first embodiment, in the second embodiment, the average resistance value reference method which is the same method as the individual voltage setting method is determined.

  In the average resistance reference method, the set voltage Va represented by the above equation (1) is set for the block 62A on the left side, and the set voltage Vb represented by the equation (2) for the block 62B on the right side is It is set. Here, in the second embodiment, Ra of the formula (1) is an average resistance value of the heating element 36 in the block 62A. Moreover, Rb of Formula (2) is an average resistance value of the heating element 36 in the block 62B.

  The set voltages Vl and Vr set in the blocks 62A and 62B by the boundary reference method are calculated as follows.

  First, when setting voltages Va and Vb corresponding to the average resistances Ra and Rb are set in the blocks 62A and 62B, respectively, electric powers Pl and Pr of two heating elements 36 adjacent to each other across the block boundary are It calculates by Formula (4) and Formula (5).

Pl = Va ² / Rl (4)
Pr = Vb ² / Rr (5)
Here, the electric power P1 is the electric power of the left heating element 36 (the heating element 36 at the right end of the heating resistor 63A) of the two heating elements 36 adjacent to each other across the block boundary. The power Pr is the power of the heating element 36 (the heating element 36 at the left end of the heating resistor 63B) on the right side of the two heating elements 36 adjacent to each other across the block boundary. Rl is a resistance value of the left heating element 36 (the heating element 36 at the right end of the heating resistor 63A) of the two heating elements 36 adjacent to each other across the block boundary. Rr is a resistance value of the heating element 36 (the heating element 36 at the left end of the heating resistor 63B) of the right side of the two heating elements 36 adjacent to each other across the block boundary.

  Next, the average power Pav of the powers Pl and Pr is calculated by the following equation (6).

Pav = (Pl + Pr) / 2 (6)
Then, the set voltages Vl of the blocks 62A and 62B are set according to the following formulas (7) and (8) so that the powers of the two heating elements 36 adjacent to each other across the block boundary become the average power Pav. Calculate Vr.

Vl = (Pav × Rl) ^1/2 (7)
Vr = (Pav × Rr) ^1/2 (8)
By setting the set voltages Vl and Vr in the blocks 62A and 62B, the electric powers of the heating elements 36 adjacent to each other across the block boundary become equal, so the diameter of the perforations by the heating elements 36 becomes equal. . For this reason, in the printed image corresponding to the plate-making image straddling the block boundary, the difference in density between the one side and the other side of the block boundary is suppressed from being noticeable.

  Here, FIG. 12 shows an example of the resistance value of the heating element 36 in the thermal head 61 and the above-mentioned set voltages Va, Vb, Vl and Vr.

  As described above, between the blocks 62A and 62B of the thermal head 61 (between the heating resistors 63A and 63B), the resistance value of the heating element 36 does not have continuity as shown in FIG.

  In the example of FIG. 12, Ra = 3100 [Ω] and Rb = 3250 [Ω]. Assuming that the set power P in the heater element 36 is 0.08 W, Va = 15.75 V and Vb = 16.12 V from the above equations (1) and (2).

  Further, in the example of FIG. 12, the resistance value R1 of the heating element 36 on the left side of the two heating elements 36 adjacent to each other across the block boundary is 3050 [Ω], and the resistance value Rr of the heating element 36 on the right side is 3150 [Ω]. Ω]. For this reason, from Formula (4)-Formula (7), it becomes Vl = 15.81 [V] and Vr = 16.06 [V].

  As described above, in the second embodiment, the control unit 7 sets the power supply 37A to set the voltage to the blocks 62A and 62B by the boundary reference method when the platemaking image straddles the block boundary at the time of platemaking. Control 37B. If there is no plate-making image across the block boundary, the control unit 7 controls the power supplies 37A and 37B to set the voltage in the average resistance value reference method for the blocks 62A and 62B.

  Thereby, when there is a plate-making image straddling a block boundary, a plate that can suppress a difference in density between one side and the other side of the block boundary in the printed image corresponding to the plate-making image striding the block boundary is plate-making it can. In addition, when there is no plate-making image across the block boundary, it is possible to make a plate which can suppress variations in density in the entire print image. As a result, in the second embodiment as well, as in the first embodiment, it is possible to make a plate capable of reducing the decrease in print image quality.

  Also in the second embodiment, as in the first embodiment, when the plate-making image straddles the block boundary, the control unit 7 adjusts the arrangement of the plate-making image so that the plate-making image does not cross the block boundary. If possible, the arrangement of the platemaking images is adjusted so that the platemaking images do not cross the block boundaries.

  As a result, even when the plate-making image originally crosses the block boundary, it is possible to set the voltage by the individual voltage setting method and perform plate-making while substantially maintaining the contents of the plate-making image. As a result, even when the plate-making image originally crosses the block boundary, it is possible to make the plate capable of reducing the variation in density in the entire print image while substantially maintaining the content of the print image.

Other Embodiments
As described above, although the present invention has been described by the first and second embodiments, it should not be understood that the description and the drawings, which form a part of this disclosure, limit the present invention. Various alternative embodiments, examples and operation techniques will be apparent to those skilled in the art from this disclosure.

  In the first embodiment described above, the thermal head power supply unit includes two power supplies, and the thermal head is divided into two blocks according to the voltage supply source. However, the number of blocks for dividing the thermal head is not limited to two, and may be plural. Then, the control unit sets the same voltage according to the average resistance value of the heating elements of the plurality of blocks for a plurality of blocks which are continuous via the block boundary across the plate-making image, For a block having no plate-making image straddling the boundary between them, the thermal head power supply unit may be controlled to set a voltage according to the average resistance value of the heating element in the block. In addition, when the control unit can reduce the number of boundaries between blocks straddling the plate-making image by adjusting the arrangement of the plate-making images, the number of boundaries between blocks straddling the plate-making image decreases. The arrangement may be adjusted.

  For example, in the first embodiment, it is assumed that the thermal head is divided into five blocks, and voltages can be individually set in each block. Here, five blocks are referred to as first to fifth blocks in order from one side in the main scanning direction.

  In this case, it is assumed that there are a plate-making image across the block boundary between the first block and the second block and a plate-making image across the block boundary between the second block and the third block. Further, it is assumed that there is no plate-making image across the block boundary between the third block and the fourth block and no plate-making image across the block boundary between the fourth block and the fifth block.

  In this case, the first to third blocks become continuous blocks via block boundaries straddling the plate-making image. Also, the fourth and fifth blocks are blocks having no plate-making image that crosses the boundary between the adjacent blocks. And the same voltage according to the average resistance value of the heating element of the 1st-3rd block is set to the 1st-3rd block. Further, for the fourth and fifth blocks, voltages corresponding to the average resistance value of the heating elements in the fourth and fifth blocks are set.

  As a result, in the print image corresponding to the plate-making image across the block boundaries of the first to third blocks, it is possible to suppress the difference in density between one side and the other side of the block boundaries, and suppress the fourth and fifth blocks. It is possible to make a plate which can suppress the variation in density in the printed image corresponding to the plate making image by As a result, it is possible to make a plate capable of reducing the reduction in print image quality.

  In this case, by adjusting the arrangement of the plate-making image, at least one of the block boundary between the first block and the second block and the block boundary between the second block and the third block is the plate-making. If it is possible to make the image not be a block boundary crossing, the arrangement of the platemaking image may be adjusted as such. This reduces the number of boundaries between blocks straddled by the plate-making image.

  For example, in the case where it is possible to make the block boundary between the second block and the third block not to be a block boundary straddling the plate-making image by adjusting the arrangement of the plate-making image, plate making as such When the image alignment is adjusted, the number of boundaries between blocks straddled by the plate-making image is reduced from two to one. In this case, the same voltage is set for the first and second blocks in accordance with the average resistance value of the heating elements of the first and second blocks. Further, for the third to fifth blocks, voltages corresponding to the average resistance value of the heating elements in the blocks are set.

  As a result, while substantially maintaining the content of the print image, it is possible to reduce variations in density in the print image corresponding to the plate-making image in the third to fifth blocks as compared with the case where the arrangement adjustment of the plate-making image is not performed. Can be made. That is, it is possible to make a printing plate capable of reducing variations in density in the entire print image while substantially maintaining the content of the print image.

  Further, in the second embodiment described above, two blocks, each of which is a short thermal head, are connected to constitute a thermal head, and voltage is supplied to each block by two power supplies provided corresponding to the two blocks. Configuration has been described. However, the number of blocks (short thermal heads) constituting the thermal head is not limited to two, and may be plural. Then, with respect to a plurality of blocks continuous through the block boundary across which the plate making image spans, the control unit equalizes the electric powers of the heating elements adjacent to each other across the block boundary across the block border across the plate making image. Thus, the voltage of each block is set, and for a block having no plate-making image across the boundary between adjacent blocks, the thermal head power supply is set to set a voltage according to the average resistance value of the heating element in the block. It is sufficient to control the unit. In addition, when the control unit can reduce the number of boundaries between blocks straddling the plate-making image by adjusting the arrangement of the plate-making images, the number of boundaries between blocks straddling the plate-making image decreases. The arrangement may be adjusted.

  For example, in the second embodiment, it is assumed that the thermal head is configured by connecting five blocks (short thermal heads), and voltages can be set individually for each block. Here, five blocks are referred to as first to fifth blocks in order from one side in the main scanning direction.

  In this case, it is assumed that there are a plate-making image across the block boundary between the first block and the second block and a plate-making image across the block boundary between the second block and the third block. Further, it is assumed that there is no plate-making image across the block boundary between the third block and the fourth block and no plate-making image across the block boundary between the fourth block and the fifth block.

  In this case, the first to third blocks become continuous blocks via block boundaries straddling the plate-making image. Also, the fourth and fifth blocks are blocks having no plate-making image that crosses the boundary between the adjacent blocks. Then, with respect to the first to third blocks, voltages of the blocks are set such that the electric powers of the heating elements adjacent to each other across the block boundary at the block boundaries straddling the plate-making image become equal. Further, for the fourth and fifth blocks, voltages corresponding to the average resistance value of the heating elements in the fourth and fifth blocks are set.

  As a result, in the print image corresponding to the plate-making image across the block boundaries of the first to third blocks, it is possible to suppress the difference in density between one side and the other side of the block boundaries, and suppress the fourth and fifth blocks. It is possible to make a plate which can suppress the variation in density in the printed image corresponding to the plate making image by As a result, it is possible to make a plate capable of reducing the reduction in print image quality.

  In this case, by adjusting the arrangement of the plate-making image, at least one of the block boundary between the first block and the second block and the block boundary between the second block and the third block is the plate-making. If it is possible to make the image not be a block boundary crossing, the arrangement of the platemaking image may be adjusted as such. This reduces the number of boundaries between blocks straddled by the plate-making image.

  For example, in the case where it is possible to make the block boundary between the second block and the third block not to be a block boundary straddling the plate-making image by adjusting the arrangement of the plate-making image, plate making as such When the image alignment is adjusted, the number of boundaries between blocks straddled by the plate-making image is reduced from two to one. In this case, for the first and second blocks, the powers of the heating elements adjacent to each other across the block boundary between the first block and the second block are equal to each other. The voltage is set. Further, for the third to fifth blocks, voltages corresponding to the average resistance value of the heating elements in the blocks are set.

  As a result, while substantially maintaining the content of the print image, it is possible to reduce variations in density in the print image corresponding to the plate-making image in the third to fifth blocks as compared with the case where the arrangement adjustment of the plate-making image is not performed. Can be made. That is, it is possible to make a printing plate capable of reducing variations in density in the entire print image while substantially maintaining the content of the print image.

  Further, in the first and second embodiments described above, the plate making apparatus for making the plate on the frame master while moving the thermal head has been described, but the plate making apparatus for making the master with the fixed thermal head while transporting the master The present invention is also applicable.

  Thus, it is a matter of course that the present invention includes various embodiments and the like which are not described herein. Accordingly, the technical scope of the present invention is defined only by the invention-specifying matters according to the scope of claims appropriate from the above description.

[Supplementary note]
The present application discloses the following invention.

(Supplementary Note 1)
A plurality of heating elements are arrayed along the main scanning direction, and resistance values of the plurality of heating elements are continuous along the main scanning direction. A thermal head to form
A power supply unit for supplying a voltage to the thermal head for each of a plurality of blocks divided in the main scanning direction by the heating resistor;
The same voltage according to the average resistance value of the heating element of the plurality of blocks is set for the plurality of blocks continuing through the boundary between the blocks across the plate-making image, and the adjacent blocks are adjacent And a control unit configured to control the power supply unit to set a voltage according to the average resistance value of the heating element in the block for the block having no plate-making image across the boundary between Plate making equipment to be.

(Supplementary Note 2)
A thermal head which is formed by connecting a plurality of blocks each having a heating resistor in which a plurality of heating elements are arranged, and forming a plate-making image by drilling through a master by the heating elements;
A power supply unit for supplying a voltage to each of the plurality of blocks with respect to the thermal head;
With respect to a plurality of consecutive blocks across the boundaries between the blocks across which the plate-making image spans, the power of the heating elements adjacent to each other across the border across the boundaries across the plate-making image is equal to each other. The power supply is configured to set a voltage of each block, and set a voltage according to the average resistance value of the heating element in the block for the block having no plate-making image across the boundary between the adjacent blocks And a control unit that controls the unit.

(Supplementary Note 3)
The control unit may adjust the layout of the plate-making image to reduce the number of boundaries between the blocks across which the plate-making image spans, so as to reduce the number of boundaries between the blocks across the plate-over image. The plate-making apparatus according to any one of appendices 1 or 2, characterized in that the arrangement of

1 Plate-making device
Reference Signs List 2 case 3 plate making unit 4 moving mechanism unit 5 movable positioning member 6A, 6B guide shaft 7 control unit 13 master 23, 36 thermal head 23a, 23b, 62A, 62B block 24 thermal head power supply unit 31, 63A, 63B heat generation resistance Body 36, 36 l, 36r Heating element 37A, 37B Power supply

Claims (3)

A plurality of heating elements are arrayed along the main scanning direction, and resistance values of the plurality of heating elements are continuous along the main scanning direction. A thermal head to form
A power supply unit for supplying a voltage to the thermal head for each of a plurality of blocks divided in the main scanning direction by the heating resistor;
The same voltage according to the average resistance value of the heating element of the plurality of blocks is set for the plurality of blocks continuing through the boundary between the blocks across the plate-making image, and the adjacent blocks are adjacent And a control unit configured to control the power supply unit to set a voltage according to the average resistance value of the heating element in the block for the block having no plate-making image across the boundary between Plate making equipment to be. A thermal head which is formed by connecting a plurality of blocks each having a heating resistor in which a plurality of heating elements are arranged, and forming a plate-making image by drilling through a master by the heating elements;
A power supply unit for supplying a voltage to each of the plurality of blocks with respect to the thermal head;
With respect to a plurality of consecutive blocks across the boundaries between the blocks across which the plate-making image spans, the power of the heating elements adjacent to each other across the border across the boundaries across the plate-making image is equal to each other. The power supply is configured to set a voltage of each block, and set a voltage according to the average resistance value of the heating element in the block for the block having no plate-making image across the boundary between the adjacent blocks And a control unit that controls the unit.   The control unit may adjust the layout of the plate-making image to reduce the number of boundaries between the blocks across which the plate-making image spans, so as to reduce the number of boundaries between the blocks across the plate-over image. The plate-making apparatus according to claim 1 or 2, wherein the arrangement of (1) is adjusted.