JP2004042668A - Printing up to the edge of the printing paper without soiling the platen - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform printing up to the end of a print sheet while preventing an ink drop from shooting at a platen. <P>SOLUTION: A platen 26n is provided with groove parts 26r, 26f, 26na and 26nb. Nozzles #1 and #2 of a print head 28 pass above the downstream side groove part 26r when main scanning is performed in the direction of an arrow MS. A print sheet P is guided by means of a guide and subscanning is performed in the direction of an arrow SS such that the opposite side ends of the print sheet P are located, respectively, above the left groove part 26na and the right groove part 26nb. Image data Dn is holding the information of an image as the information of recording state of dots in each pixel. These pixels are set in a range exceeding the outer circumferential end of the print sheet P. When the front end of the print sheet P reaches a position on the upstream side of the nozzle #1 above the downstream side groove part 26r through widthwise scanning, printing is started at the upper end part Pf of the print sheet P by means of the nozzles #1 and #2. <P>COPYRIGHT: (C)2004,JPO

Description

The present invention relates to a technique for recording dots on the surface of a recording medium using a dot recording head, and more particularly, to a technique for performing printing up to the edge of printing paper without soiling a platen.

In recent years, printers that eject ink from nozzles of a print head have become widespread as output devices for computers. FIG. 29 is a side view showing the periphery of a print head of a conventional printer. The printing paper P is supported on the platen 26o so as to face the head 28o. The printing paper P is sent in the direction of arrow A by the upstream paper feed rollers 25p and 25q arranged upstream of the platen 26o and the downstream paper feed rollers 25r and 25s arranged downstream of the platen 26o. . When ink is ejected from the head, dots are sequentially recorded on the printing paper P, and an image is printed.

In order to print an image to the edge of the printing paper without margins in such a printer as described above, the image data is set up to the edge of the printing paper, and when printing, the printing paper is placed under the printing head, that is, the platen. It is necessary to dispose it so as to be positioned above and to eject ink droplets from the print head. However, in such printing, when an ink droplet is displaced from the end of the printing paper where it should originally land due to an error in the feeding of the printing paper or a deviation of the landing position of the ink droplet, the ink droplet lands on the platen. There is. In such a case, the printing paper that subsequently passes on the platen is stained by the ink that has landed on the platen.

The present invention has been made to solve the above-described problems in the conventional technology, and has as its object to provide a technique for performing printing up to the edge of printing paper without causing ink drops to land on a platen.

In order to solve at least a part of the above problems, the present invention provides a dot recording apparatus that records dots on the surface of a print medium using a dot recording head provided with a plurality of dot forming elements that eject ink droplets. As a target, a predetermined process is performed. This dot recording apparatus includes a platen that extends in the main scanning direction so as to face the dot forming element in at least a part of the main scanning path. The platen includes an upstream groove portion provided in the main scanning direction at a position facing the dot forming element positioned at least on the upstream side in the sub-scanning direction among the plurality of dot forming elements; And a downstream groove portion extending in the main scanning direction at a position facing at least a dot forming element located at a downstream end in the sub-scanning direction among the dot forming elements.

At the time of dot formation, at least one of the plurality of dot forming elements is driven to form dots while driving at least one of the dot recording head and the print medium to perform main scanning. The sub-scan is performed by driving the print medium in a direction intersecting with the main-scan direction. At that time, first, print data including image data for recording an image in an extended area having a length exceeding at least the upper and lower ends of the print medium is prepared. Then, ink droplets are ejected to the extended area based on the print data. If such printing is performed in the above-described dot recording apparatus, printing can be performed up to the edge of the printing paper without causing ink drops to land on the platen.

Note that when ejecting ink droplets to the extended area, when ejecting ink droplets to the upper end of the print medium, the print medium is supported by the platen, and the upper end of the print medium is above the opening of the downstream groove, In addition, it is preferable to set the position of the print medium in the sub-scanning direction such that the upper end is located upstream of the dot forming element at the downstream end in the sub-scanning direction in the sub-scanning direction. When ejecting ink droplets to the lower end of the print medium, the print medium is supported by the platen, the lower end of the print medium is above the opening of the upstream groove, and the lower end of the print medium is It is preferable to set the position of the print medium in the sub-scanning direction so as to be located downstream of the dot forming element at the upstream end in the sub-scanning direction. According to this aspect, the upper end of the print medium is printed on the upstream groove, and the lower end of the print medium is printed on the downstream groove, so that the end of the print is printed without soiling the platen. Can be.

In addition, the platen is further provided in a range including at least a landing range of ink droplets from the plurality of dot forming elements in the sub-scanning direction, and a pair of side plates provided at intervals substantially equal to the width of the print medium. In the case of having a groove, it is preferable to perform the following. That is, when preparing print data, an image is recorded in an extended area having a width exceeding the left and right ends of the print medium and having a width not exceeding the interval between the outer side walls of the pair of side grooves. Of print data including image data for use. With such an embodiment, printing can be performed without margins on the left and right edges of the print medium.

When ejecting ink droplets to the extended area, the main scanning of the print medium is performed so that the print medium is supported by the platen and both ends of the print medium are kept at the positions of the side grooves. Is preferably set. With such an embodiment, the left and right edges of the print medium can be printed without margins without soiling the platen.

The print data may include, as image data, information on the recording state of dots in each pixel in the extended area. With such an embodiment, it is possible to easily set a portion of the extended area beyond the edge of the print medium.

The present invention can be realized in various modes as described below.
(1) Dot recording method, printing control method, printing method.
(2) Dot recording device, print control device, printing device.
(3) Computer programs for realizing the above devices and methods.
(4) A recording medium on which a computer program for realizing the above apparatus and method is recorded.
(5) A data signal embodied in a carrier wave, including a computer program for realizing the above apparatus and method.

Hereinafter, embodiments of the present invention will be described in the following order based on examples.
A. Overview of the embodiment:
B. First embodiment:
C. Second embodiment:
D. Third embodiment:
E. FIG. Embodiment having side grooves:
F. Modification:

A. Overview of the embodiment:
FIG. 1 is an enlarged plan view showing the structure of a part of the left side of a platen of an inkjet printer according to an embodiment of the present invention. The platen 26n is provided with a downstream groove 26r, an upstream groove 26f, a left groove 26na, and a right groove 26nb (not shown) so as to form a quadrilateral. The portion surrounded by these grooves is the central portion 26c of the platen 26n. In FIG. 1, the upper surface of the platen where no groove is provided is a portion indicated by a fine diagonal line from upper right to lower left. The nozzles # 1 and # 2 (indicated by double circles) of the print head 28 pass over the downstream groove 26r when the print head 28 is fed in the main scanning direction in the direction of the arrow MS. In FIG. 1, the printing paper P is sub-scanned in the direction of the arrow SS from above to below. At this time, the printing paper P is guided by a guide (not shown), and is sub-scanned so that both side ends are positioned on the left groove 26na and the right groove 26nb of the platen 26n, respectively.

The image data Dn used for recording an image on the printing paper P is a grid that divides the image area into a grid, and holds image information as information of a dot recording state in each “pixel”. I have. In FIG. 1, pixels are indicated by broken lines. As shown in FIG. 1, these pixels are set beyond the outer edge of the printing paper P. In FIG. 1, the printing paper P is a portion indicated by a coarse oblique line from upper left to lower right.

(4) When the printing paper P is set on the guide, the printing paper P is sub-scanned in the direction of the arrow SS. When the front end reaches a position on the downstream groove 26r and upstream of the nozzle # 1, the sub-scan feed of the printing paper P is stopped. Thereafter, printing of the upper end portion Pf of the printing paper P (in FIG. 1, the printing paper P is located at the lower end side because it is drawn upside down) is started by the nozzles # 1 and # 2. Since the pixels for recording dots are set beyond the upper end Pf of the printing paper P, an image can be formed without creating a margin at the upper end of the printing paper P. Further, since the nozzles # 1 and # 2 used for printing are located on the downstream groove 26r, even if the ink droplets come off the printing paper P, the ink droplets land in the downstream groove 26r, and the platen It does not land on the central portion 26c of the 26n. Therefore, the lower surface of the printing paper P is not stained by ink droplets that have landed on the central portion 26c of the platen 26n. Similarly, for the left and right side edges of the printing paper P, printing of pixels set beyond the left and right edges is performed in the main scanning in the left groove portion 26na and the right groove portion 26nb (not shown). This is done by the nozzle located above. Therefore, it is possible to print the left and right side edges without blanks without soiling the central portion 26c of the platen 26n.

B. First embodiment:
(1) Configuration of device:
FIG. 2 is a block diagram illustrating a configuration of an image processing apparatus and a printing apparatus according to an embodiment of the present invention. As shown in the figure, the scanner 12 and the printer 22 are connected to the computer 90. When a predetermined program is loaded and executed on the computer 90, the computer 90 functions as an image processing apparatus, and also functions as a printing apparatus together with the printer 22. The computer 90 includes the following units interconnected by a bus 80, centering on a CPU 81 that executes various arithmetic processes for controlling operations related to image processing according to a program. The ROM 82 previously stores various programs and data necessary for the CPU 81 to execute various arithmetic processes, and the RAM 83 temporarily stores various programs and data necessary for the CPU 81 to execute various arithmetic processes. This is the memory that is read and written. The input interface 84 controls input of signals from the scanner 12 and the keyboard 14, and the output interface 85 controls output of data to the printer 22. The CRTC 86 controls signal output to the CRT 21 capable of color display, and the disk controller (DDC) 87 controls data transfer with the hard disk 16, the flexible drive 15, or a CD-ROM drive (not shown). The hard disk 16 stores various programs loaded and executed in the RAM 83 and various programs provided in the form of device drivers.

他 In addition, a serial input / output interface (SIO) 88 is connected to the bus 80. The SIO 88 is connected to the modem 18, and is connected to the public telephone line PNT via the modem 18. The computer 90 is connected to an external network via the SIO 88 and the modem 18. By connecting to a specific server SV, it is also possible to download a program required for image processing to the hard disk 16. In addition, it is also possible to load a necessary program from a flexible disk FD or a CD-ROM and cause the computer 90 to execute the program.

FIG. 3 is a block diagram illustrating a software configuration of the printing apparatus. In the computer 90, an application program 95 operates under a predetermined operating system. A video driver 91 and a printer driver 96 are incorporated in the operating system, and image data D to be transferred to the printer 22 is output from the application program 95 via these drivers. An application program 95 for retouching an image reads an image from the scanner 12 and displays the image on the CRT 21 via the video driver 91 while performing predetermined processing on the image. The data ORG supplied from the scanner 12 is original color image data ORG that is read from a color original and includes three color components of red (R), green (G), and blue (B).

When the application program 95 issues a print command, the printer driver 96 of the computer 90 receives the image data from the application program 95, and receives the image data from the application program 95 in a signal (here, cyan, magenta, light cyan, light magenta, (A multilevel signal for each color of yellow and black). In the example shown in FIG. 3, the printer driver 96 includes a resolution conversion module 97, a color correction module 98, a halftone module 99, and a rasterizer 100. Further, a color correction table LUT and a dot formation pattern table DT are also stored. Note that the application program 95 corresponds to an “image data generation unit”.

The resolution conversion module 97 serves to convert the resolution of the color image data handled by the application program 95, that is, the number of pixels per unit length into a resolution that can be handled by the printer driver 96. Since the image data whose resolution has been converted in this manner is still image information of three colors of RGB, the color correction module 98 refers to the color correction table LUT and uses the cyan (C), The data is converted into data of each color of magenta (M), light cyan (LC), light magenta (LM), yellow (Y), and black (K).

The color-corrected data has a gradation value with a width of, for example, 256 gradations. The halftone module 99 executes a halftone process for expressing this gradation value in the printer 22 by forming dots in a dispersed manner. The halftone module 99 refers to the dot formation pattern table DT to set the dot formation pattern of each ink dot according to the gradation value of the image data, and then execute the halftone processing. The image data thus processed is rearranged by the rasterizer 100 in the order of data to be transferred to the printer 22, and output as final print data PD. The print data PD includes raster data indicating a dot recording state during each main scan and data indicating a sub-scan feed amount. The raster data and the data indicating the sub-scan feed amount included in the print data PD correspond to image data D substantially representing an image to be printed. That is, these data have information on the recording state of dots in each pixel in the extended area as image data. In the present embodiment, the printer 22 only plays a role of forming ink dots in accordance with the print data PD and does not perform image processing. However, it goes without saying that these processes may be performed by the printer 22.

Next, a schematic configuration of the printer 22 will be described with reference to FIG. As shown in the drawing, the printer 22 includes a mechanism for transporting a sheet P by a paper feed motor 23, a mechanism for reciprocating a carriage 31 in the axial direction of a platen 26 by a carriage motor 24, and a print head mounted on the carriage 31. And a control circuit 40 for exchanging signals with the paper feed motor 23, the carriage motor 24, the print head 28, and the operation panel 32. ing.

The mechanism for reciprocating the carriage 31 in the axial direction of the platen 26 is provided in parallel with the axis of the platen 26, and an endless drive belt is provided between the carriage shaft 24 and the carriage motor 24 for slidably holding the carriage 31. A pulley 38 on which the carriage 36 is extended and a position detection sensor 39 for detecting the origin position of the carriage 31 are provided.

The carriage 31 has a cartridge 71 for black ink (K) and color ink containing six color inks of cyan (C), light cyan (LC), magenta (M), light magenta (LM), and yellow (Y). Cartridge 72 can be mounted. A total of six ink discharge heads 61 to 66 are formed on the print head 28 below the carriage 31, and an introduction pipe 67 for guiding ink from the ink tank to each color head is formed at the bottom of the carriage 31. It is erected. When the cartridge 71 for black (K) ink and the cartridge 72 for color ink are mounted on the carriage 31 from above, the introduction pipe 67 is inserted into the connection hole provided in each cartridge, and the ejection heads 61 to 66 are discharged from each ink cartridge. Can be supplied to the printer.

The heads 61 to 66 of each color provided at the lower portion of the carriage 31 are provided with 48 nozzles Nz for each color, and each of the nozzles is a piezoelectric element which is one of the electrostrictive elements and has excellent responsiveness. The element PE is arranged. The piezo element PE is provided at a position in contact with an ink passage for guiding ink to the nozzle Nz. As is well known, the piezo element PE is an element that distorts the crystal structure due to the application of a voltage and converts electro-mechanical energy very quickly. In the present embodiment, by applying a voltage having a predetermined time width between the electrodes provided at both ends of the piezo element PE, the piezo element PE expands by the voltage application time and deforms one side wall of the ink passage. As a result, the product of the ink passage 68 contracts in accordance with the expansion of the piezo element PE, and the ink corresponding to the contraction becomes the particles Ip and is discharged from the tip of the nozzle Nz at a high speed. Printing is performed by the permeation of the ink particles Ip into the paper P mounted on the platen 26.

FIG. 5 is an explanatory diagram showing the arrangement of the inkjet nozzles Nz in the ink ejection heads 61 to 66. These nozzles are arranged from six nozzle arrays that eject ink for each color of black (K), cyan (C), light cyan (LC), magenta (M), light magenta (LM), and yellow (Y). 48 nozzles are arranged in a row at a constant nozzle pitch k. The “nozzle pitch” is a value indicating how many rasters (that is, how many pixels) the intervals of the nozzles arranged on the print head in the sub-scanning direction are. For example, the pitch k of the nozzles arranged at intervals of three rasters is four.

FIG. 6 is a plan view showing the periphery of the platen 26. FIG. The platen 26 is provided in the main scanning direction longer than the maximum width of the printing paper P usable in the printer. Upstream of the platen 26, upstream paper feed rollers 25a and 25b are provided. While the upstream paper feed roller 25a is a single drive roller, the upstream paper feed roller 25b is a plurality of small rollers that rotate freely. Downstream of the platen, downstream paper feed rollers 25c and 25d are provided. The downstream paper feed roller 25c is a plurality of rollers provided on the drive shaft, and the downstream paper feed roller 25d is a plurality of freely rotating small rollers. A groove is provided on the outer peripheral surface of the downstream paper feed roller 25d in parallel with the rotation axis direction. That is, the downstream paper feed roller 25d has teeth (portions between the grooves) radially on the outer peripheral surface, and looks like a gear when viewed from the rotation axis direction. The downstream paper feed roller 25 d is generally called a “jagged roller” and plays a role of pressing the printing paper P onto the platen 26. The downstream paper feed roller 25c and the upstream paper feed roller 25a rotate synchronously so that the outer peripheral speeds are equal.

The print head 28 reciprocates in the main scan on the platen 26 sandwiched between the upstream paper feed rollers 25a and 25b and the downstream paper feed rollers 25c and 25d. The print paper P is held by the upstream paper feed rollers 25a and 25b and the downstream paper feed rollers 25c and 25d, and the portion therebetween is supported by the upper surface of the platen 26 so as to face the nozzle row of the print head 28. Then, the sub-scan feed is performed by the upstream paper feed rollers 25a and 25b and the downstream paper feed rollers 25c and 25d, and an image is sequentially recorded by ink ejected from the nozzles of the print head 28. The upstream paper feed rollers 25a and 25b are "upstream sub-scanning drive units" described in the claims, and the downstream paper feed rollers 25c and 25d are "downstream sub-scan drive drives" in the claims. Department ".

The platen 26 is provided with an upstream groove 26f and a downstream groove 26r on the upstream side and the downstream side in the sub-scanning direction, respectively. The upstream groove 26f and the downstream groove 26r are provided along the main scanning direction longer than the maximum width of the printing paper P usable in the printer. Absorbing members 27f and 27r for receiving and absorbing the ink droplets Ip are arranged at the bottoms of the upstream groove 26f and the downstream groove 26r, respectively. The downstream groove portion 26r is provided at a position facing a part of the nozzle group Nr on the downstream side including the most downstream nozzle among the nozzles Nz on the print head 28 (the nozzles indicated by oblique lines in FIG. 6). I have. The upstream groove 26f is provided at a position facing a part of the upstream nozzle group Nf (not shown in FIG. 6) including the most upstream nozzle among the nozzles on the print head 28. When the sub-scanning feed is performed by the upstream paper feed rollers 25a and 25b and the downstream paper feed rollers 25c and 25d, the printing paper P passes over the openings of the upstream groove 26f and the downstream groove 26r. Go.

Next, the internal configuration of the control circuit 40 (see FIG. 4) of the printer 22 will be described. Inside the control circuit 40, in addition to the CPU 41, the PROM 42, and the RAM 43, a PC interface 45 for exchanging data with the computer 90, and a drive for outputting ink dot ON / OFF signals to the ink ejection heads 61 to 66. A buffer 44 and the like are provided, and these elements and circuits are interconnected by a bus. The control circuit 40 receives the dot data processed by the computer 90, temporarily stores the dot data in the RAM 43, and outputs the dot data to the driving buffer 44 at a predetermined timing. The RAM 43 corresponds to a “print data storage” in the claims.

In the printer 22 having the hardware configuration described above, the carriage 31 is reciprocated by the carriage motor 24 while the paper P is being conveyed by the paper feed motor 23, and at the same time, the piezo elements of each nozzle unit of the print head 28 are driven. By discharging ink droplets Ip of each color, ink dots are formed to form a multi-color image on the paper P.

In the printer of this embodiment, the upper end Pf of the printing paper P is printed on the downstream groove 26r, and the lower end Pr is printed on the upstream groove 26f. A printing process different from that of the intermediate portion of the printing paper is performed. In this specification, the printing process in the middle portion of the printing paper is called “intermediate process”, the printing process near the top edge of the printing paper is called “top processing”, and the printing process near the bottom edge of the printing paper is “bottom processing”. Call. When the upper end processing and the lower end processing are collectively called, they are called “upper / lower end processing”.

The width W of the upstream groove 26f and the downstream groove 26r in the sub-scanning direction can be determined by the following equation.

W = p × n + α

Here, p is the feed amount [inch] of one sub-scan feed in the upper and lower end processing. n is the number of sub-scan feeds performed in each of the upper end processing and the lower end processing. α is a sub-scan feed error assumed in each of the upper end processing and the lower end processing. It is preferable that the value of α in the lower end process (upstream groove portion 26f) is set to be larger than the value of α in the upper end process (downstream groove portion 26r). If the width of the groove of the platen is determined by the above equation, it is possible to provide a groove having a width sufficient to receive ink droplets ejected from the nozzles during upper and lower end processing.

(2). Sub-scan feed:
(I) Upper end processing of the first embodiment:
FIG. 7 is an explanatory diagram showing how each raster is recorded by which nozzle near the upper end (front end) of the printing paper. Here, for simplicity, the description will be made using only one nozzle row. It is assumed that one nozzle row has eight nozzles. At the time of main scanning, each nozzle is responsible for recording one raster. Here, the “raster” is a row of pixels arranged in the main scanning direction. The “pixel” is a square grid virtually defined on a print medium in order to define a position where an ink droplet lands and a dot is recorded. Here, it is assumed that the nozzles are arranged at intervals of three rasters.

に お い て In FIG. 7, one row of cells arranged vertically represents the print head 28. The numbers 1 to 8 in each cell indicate the nozzle number. In the specification, “#” is added to these numbers to indicate each nozzle. In FIG. 7, the print heads 28 which are relatively fed in the sub-scanning direction with time are shown sequentially shifted from left to right. As shown in FIG. 7, in the upper end process, the sub-scan feed for each dot is repeated seven times. The “dot” in the unit of the sub-scan feed amount means a pitch corresponding to one dot corresponding to the print resolution in the sub-scan direction, which is equal to the pitch of the raster.

(5) Thereafter, the process proceeds to the intermediate processing, and the feeding of 5, 2, 3, and 6 dots is repeated in that order. A method of performing sub-scanning by combining different feed amounts in this manner is called “irregular feed”. When the above-described sub-scan feed is performed, each raster is recorded by two nozzles except for some rasters. That is, in this embodiment, each raster is printed by two nozzles. For example, in FIG. 7, the fifth raster from the top is recorded by nozzle # 2 and nozzle # 1. At this time, the nozzle # 2 records, for example, an even-addressed pixel, and the nozzle # 1 records an odd-addressed pixel. The ninth raster from the top is recorded by nozzles # 3 and # 2. In this manner, a method of printing by sharing pixels in one raster by a plurality of nozzles is called "overlap printing". In overlap printing, dots of one raster are recorded by a plurality of nozzles passing on the raster in a plurality of main scans in which the position of the printing paper in the sub-scanning direction with respect to the print head is different from each other.

On the other hand, in FIG. 7, the four rasters from the top row only pass the nozzle # 1 once in the main scan during printing. Therefore, for these rasters, it is not possible to print with two nozzles sharing pixels. Therefore, in this embodiment, these four rasters are not used for recording an image. In other words, the rasters that can be used for recording an image in the present embodiment are the fifth and subsequent rasters from the upstream end in the sub-scanning direction among the rasters in which the nozzles on the print head 28 can record dots. A raster area that can be used to record this image is called a “printable area”. A raster area that is not used for image recording is referred to as a “non-printable area”. In FIG. 7, the rasters on which the nozzles on the print head 28 can record dots are numbered sequentially from the top on the left side of the figure. Hereinafter, the same applies to the drawings for explaining the dot recording of the upper end processing. It should be noted that the nozzles surrounded by a thick frame in the drawing are nozzles that record dots in a raster.

In FIG. 7, three nozzles pass through the thirteenth and fifteenth rasters from the top in the main scan during printing. In such a raster in which three or more nozzles pass during printing, it is assumed that only two of the nozzles record dots. It is preferable that these rasters are recorded by nozzles passing over the rasters after shifting to intermediate processing as much as possible. In the intermediate processing, irregular feeding is performed, and the combination of nozzles passing on adjacent rasters is different. Therefore, compared to the upper end processing in which regular feeding is performed one dot at a time, the print result is high in image quality. It is because it can be expected to become.

In this embodiment, an image is recorded without a margin up to the upper end of the printing paper. As described above, in the present embodiment, among the rasters on which the nozzles on the print head 28 can record dots, the fifth and subsequent rasters (printable area) from the upstream end in the sub-scanning direction are used to print an image. Can be recorded. Therefore, if the printing paper is arranged with respect to the print head 28 and the recording of the dots is started so that the fifth raster from the end is located at a position almost at the upper end of the printing paper, theoretically, Images can be recorded up to the upper end of the printing paper. However, during the sub-scan feed, an error may occur in the feed amount. Further, the ejection direction of the ink droplet may be shifted due to a manufacturing error of the print head or the like. For such a reason, it is preferable that no margin is formed at the upper end of the printing paper even when the landing position of the ink droplet on the printing paper is shifted. Therefore, in the present embodiment, the image data D used for printing is set from the fifth raster from the upstream end in the sub-scanning direction among rasters on which the nozzles on the print head 28 can record dots. It is assumed that printing is started from a state where the upper end of the paper P is at the seventh raster position from the upstream end in the sub-scanning direction. Therefore, the assumed position of the upper end of the printing paper with respect to each raster at the start of printing is the position of the seventh raster from the upstream end in the sub-scanning direction, as shown in FIG.

FIG. 8 is a plan view showing the relationship between the image data D and the printing paper P. As described above, in this embodiment, the image data D is set beyond the upper end Pf of the printing paper P to the outside of the printing paper P. Also, for the lower end side, the image data D is set beyond the lower end Pr of the printing paper P to the outside of the printing paper P for the same reason. Therefore, in the present embodiment, the relationship between the size of the image data D and the printing paper P and the relationship between the arrangement of the image data D and the printing paper P during printing are as shown in FIG. That is, according to the image data D, an image can be recorded in an extended area (an area indicated by a dashed line in FIG. 8) having a length exceeding at least the upper and lower ends of the print medium. In the present embodiment, the width of the portion of the image data D set beyond the upper end Pf of the printing paper P to the outside of the printing paper P is two rasters. Similarly, the width of the portion of the image data D set beyond the lower end Pr of the printing paper P to the outside of the printing paper P is also equivalent to two rasters. In this specification, the terms “upper end (part)” and “lower end (part)” are used to refer to the edges of the printing paper P in correspondence with the top and bottom of the image data recorded on the printing paper P, When referring to the edge of the printing paper P in correspondence with the traveling direction of the sub-scanning feed of the printing paper P on the printer 22, the words "front end (part)" and "rear end (part)" may be used. is there. In the present specification, in the printing paper P, “upper end (part)” corresponds to “front end (part)”, and “lower end (part)” corresponds to “rear end (part)”.

FIG. 9 is a side view showing the relationship between the print head 28 and the printing paper P at the start of printing. Here, the central portion 26c of the platen 26 is provided in a range R26 from a position two rasters later counted from the nozzle # 2 of the print head 28 to a position two rasters earlier counted from the nozzle # 7. It is assumed that Therefore, even when the ink droplets Ip are ejected from each nozzle in a state where there is no printing paper, the ink droplets from the nozzles # 1, # 2, # 7, and # 8 do not land on the platen 26.

In FIG. 6, the nozzle group Nr of the print head 28 indicated by oblique lines is the portion where the nozzles # 1 and # 2 are located. A downstream groove 26r is provided below a portion through which the nozzles pass during the main scanning. When the upper end Pf of the printing paper P is located at a position indicated by a dashed line on the downstream groove 26r, Printing starts.

As described above, at the start of printing, the upper end Pf of the printing paper P is located at the seventh raster position from the upstream end in the sub-scanning direction among the rasters on which the nozzles on the print head 28 can record dots. That is, with reference to FIG. 9, the upper end of the printing paper P is located six rasters behind the nozzle # 1. In FIG. 9, the position of the raster assumed on the image data is indicated by a broken line. Accordingly, if printing is to be started from this state, the uppermost raster (the fifth raster from the top in FIG. 7) of the printable area should be recorded by nozzle # 2. There is no printing paper P under the nozzle 2 yet. Therefore, if the printing paper P is correctly fed by the upstream paper feed rollers 25a and 25b, the ink droplets Ip discharged from the nozzle # 2 will fall directly into the downstream groove 26r. Also, as shown in FIG. 7, the raster at the top of this printable area is recorded by the nozzle # 1 after four one-dot feeds. However, similarly, at the stage where four one-dot feeds have been performed, there is no print paper P below the nozzle of # 1. Therefore, the ink droplet Ip ejected from the nozzle # 1 at that time also falls into the downstream groove 26r as it is. The same applies to the case of printing the second raster from the top of the printable area (the sixth raster from the top in FIG. 7).

However, when the printing paper P is sent for a reason more than the original feed amount, the upper end of the printing paper P is placed on the second raster from the top of the printable area or the uppermost row of the printable area. May come to the raster position. In this embodiment, even in such a case, the nozzles # 1 and # 2 eject the ink droplets Ip to the rasters (at a position exceeding the upper end Pf of the printing paper P). An image can be recorded at the upper end of the image, and no margin is formed. That is, even if the printing paper P is sent more than the original feeding amount, as shown by the dashed line in FIG. 9, if the extra feeding amount is less than two rasters, the printing paper P There is no margin at the top of the file. It is the CPU 41 that performs printing in an area (extended area) exceeding the upper end Pf of the printing paper P in this manner. That is, the CPU 41 corresponds to an “edge printing unit” in the claims.

Conversely, for some reason, the print paper P may be sent less than the original feed amount. In such a case, there is no printing paper at the position where the printing paper should be, and the ink droplet Ip lands on the structure below. However, as shown in FIG. 7, in the present embodiment, two rasters from the assumed upper end position of the paper are recorded by nozzles # 1 and # 2. Downstream grooves 26r are provided below these nozzles. Even if the ink droplets Ip do not land on the printing paper P, the ink drops Ip fall into the downstream grooves 26r, and the absorbing member 27r Will be absorbed. Therefore, the ink droplet Ip does not land on the upper surface of the platen 26, and does not stain the printing paper later. That is, in the present embodiment, even when the upper end Pf of the printing paper P is behind the assumed upper end position at the start of printing, if the deviation amount from the assumed upper end position is 2 rasters or less, the ink drop Ip Does not land on the upper surface of the platen 26, and does not stain the printing paper P later.

As described above, at the time of sub-scanning, the upper end Pf of the printing paper P is located above the opening of the downstream groove 26r, and the upper end Pf is located at a position upstream of the nozzle at the downstream end in the sub-scanning direction. It is the CPU 41 that sets the position of the printing paper P in the sub-scanning direction. That is, the CPU 41 corresponds to an “upper end positioning portion” in the claims.

The printing paper P is preferably held by two pairs of upstream paper feed rollers 25a and 25b and downstream paper feed rollers 25c and 25d, and is preferably fed in the sub-scanning direction. This is because the sub-scan feed can be performed more accurately than the case where the sheet is held by only one roller and the sub-scan feed is performed. However, when printing the upper end Pf of the printing paper, the printing paper P is held only by the upstream paper feed rollers 25a and 25b and is fed in the sub-scanning direction. In the present embodiment, printing is started in a state where the upper end Pf of the printing paper is located at the seventh raster position from the upstream end in the sub-scanning direction among rasters on which nozzles on the print head 28 can record dots. (See FIGS. 7 and 9). Therefore, as shown in FIG. 9, from the position until the upper end Pf of the printing paper is held by the downstream paper feed rollers 25c and 25d, that is, while the printing paper is fed by the distance of L31, the upstream paper is fed. Sub-scan feed is performed only by the feed rollers 25a and 25b, and printing is performed. In this embodiment, the sub-scan feed is performed only by the upstream paper feed rollers 25a and 25b, and the section in which printing is performed is relatively short, so that the print result has high image quality. Note that the present invention is not limited to the above-described embodiment, and the above-described effect can be obtained if the nozzle near the downstream end in the sub-scanning direction is used to print near the upper end Pf of the printing paper. This is particularly effective when the feeding accuracy of the upstream sub-scanning driving units (upstream paper feed rollers 25a and 25b) is relatively low.

(4) When printing the upper end portion, the printing paper P is supported at two places: the upstream paper feed rollers 25 a and 25 b and the upper surface of the platen 26. Therefore, the upper end portion of the printing paper P is relatively unlikely to be bent downward on the downstream groove 26r. Therefore, there is little possibility that the quality of the printing result of the upper end portion is deteriorated due to the bending of the printing paper.

(Ii) Top feed of comparative example:
FIG. 10 is a side view showing the relationship between the print head 28 and the printing paper P at the start of printing in the comparative example. As shown in FIG. 10, even if the upper end portion of the printing paper P is printed in the upstream groove 26f, the ink droplets that have not landed on the printing paper P do not land on the upper surface of the platen 26. However, in this comparative example, the distance L32 at which the printing paper is fed (see FIG. 10) from the start of printing on the upper end portion of the printing paper until the upper end of the printing paper is held by the downstream paper feed rollers 25c and 25d. ) Is longer than in the case of the embodiment (L31 in FIG. 7). That is, the section in which the sub-scan feed is performed only by the upstream paper feed rollers 25a and 25b and printing is performed is relatively long. For this reason, the quality of the printing result is lower than that of the embodiment.

When printing the upper end portion, the printing paper P is held only by the upstream paper feed rollers 25a and 25b. For this reason, the upper end portion of the printing paper P easily bends downward on the upstream groove 26f. Therefore, when printing the upper end portion, there is a relatively high possibility that the quality of the printing result is reduced.

(Iii) Lower end processing of the first embodiment:
FIG. 11 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process. FIG. 11 shows a portion from the point at which the (n + 1) th sub-scan feed is performed to the point at which the last (n + 17) -th sub-scan feed is performed. In this embodiment, as shown in FIG. 11, in the intermediate processing, the feeding of 5 dots, 2 dots, 3 dots, and 6 dots is repeated in that order in the sub-scanning feed up to the (n + 8) -th time, and then the lower 9 Times, that is, the (n + 9) -th to (n + 17) -th sub-scan feeds are performed by one-dot feed. As a result, each raster along the main scanning direction is recorded by two nozzles, except for some rasters. Note that in FIG. 11, the rasters on which the nozzles on the print head 28 can record dots are numbered sequentially from the bottom on the right side of the figure. Hereinafter, the same applies to the drawings describing the dot recording of the lower end processing.

In FIG. 11, in the four rasters from the bottom, the nozzle # 8 passes only once in printing. Then, the fifth or more rasters from the bottom can be recorded by two or more nozzles. Therefore, the printable area at the lower end of the printing paper is the area of the fifth or more rasters from the bottom.

In FIG. 11, three or more nozzles pass through the ninth and tenth rasters from the bottom in the main scan during printing. With respect to such a raster in which three or more nozzles pass in printing, it is preferable to perform recording by nozzles passing on the raster in the intermediate processing as much as possible. This is because the print result can be expected to have high image quality as compared with the lower end process in which the regular feed is performed dot by dot.

In the present embodiment, as in the case of the upper end, an image is recorded without margins at the lower end. As described above, in the present embodiment, among the rasters on which the nozzles on the print head 28 can record dots, the fifth or more rasters (printable area) from the downstream end in the sub-scanning direction are used to print an image. Can be recorded. However, in consideration of a case where an error occurs in the feed amount during the sub-scan feed, the recording is performed on the printing paper from the seventh raster from the downstream end in the sub-scan direction. That is, in a state where the lower end of the printing paper is at the position of the seventh raster from the upstream end in the sub-scanning direction, the ink droplets Ip are also ejected for the fifth and sixth rasters, and Perform a scan. Therefore, the assumed position of the lower end of the printing paper with respect to each raster at the end of printing is the position of the seventh raster from the downstream end in the sub-scanning direction, as shown in FIG.

FIG. 12 is a plan view showing the relationship between the upstream groove 26f and the printing paper P when printing the lower end Pr of the printing paper P. In FIG. 12, the nozzle group Nf of the portion of the print head 28 indicated by oblique lines is the portion where the nozzles # 7 and # 8 are located. An upstream groove 26f is provided below a portion through which the nozzles pass during main scanning, and when the lower end Pr of the printing paper P is located at a position indicated by a dashed line on the upstream groove 26f, Finish printing.

FIG. 13 is a side view showing the relationship between the print head 28 and the printing paper P when printing the lower end Pr of the printing paper P. As described above, when printing the lower end portion Pr of the printing paper P, the lower end Pr of the printing paper P is set at 7 from the downstream end in the sub-scanning direction of the raster on which the nozzles on the print head 28 can record dots. It is at the position of the raster (see FIG. 11). That is, the lower end of the printing paper P is located six rasters earlier than the nozzle of # 8. Therefore, in this state, if the recording of the second raster from the bottom of the printable area and the second raster from the bottom (the sixth and fifth rasters from the bottom in FIG. 11) is to be performed, # 7, # 8 The ink droplet Ip discharged from the nozzle of No. 2 falls directly into the upstream groove 26f.

Also, if the printing paper P is sent for less than the original feed amount for some reason, the nozzles # 7 and # 8 are moved to the fifth and sixth rasters from the bottom (the printing paper P (At a position exceeding the lower end Pr of the printing paper P), an image can be recorded on the lower end Pr of the printing paper P, and no margin is formed. That is, as shown by the one-dot chain line in FIG. 13, when the insufficient feed amount is equal to or less than two rasters, no margin is formed at the lower end of the printing paper P. It is the CPU 41 that performs printing in an area (extended area) exceeding the lower end Pr of the printing paper P in this manner. That is, the CPU 41 corresponds to an “edge printing unit” in the claims.

{Circle around (2)} The two rasters above the assumed upper end position of the paper (the seventh and eighth rasters from the bottom in FIG. 11) are to be recorded by nozzles # 7 and # 8. Therefore, even if the printing paper P is sent more than the original feed amount for some reason, the ejected ink droplets Ip may fall into the upstream groove 26f and land on the upper surface of the platen 26. Absent.

As described above, at the time of sub-scanning, the lower end Pr of the printing paper P is located above the opening of the upstream groove 26f, and the lower end Pr is located at a position downstream of the nozzle at the upstream end in the sub-scanning direction. It is the CPU 41 that sets the position of the printing paper P in the sub-scanning direction. That is, the CPU 41 corresponds to a “lower end positioning portion” in the claims.

Further, in this embodiment, among the rasters on which the nozzles on the print head 28 can record dots, the position of the seventh raster from the downstream end in the sub-scanning direction (that is, two rasters of nozzle # 7 in FIG. The last raster on the printing paper is recorded in a state where the lower end Pr of the printing paper is located at the (previous position), and printing is completed (see FIG. 11). Therefore, while the printing paper P is fed by the distance L41 from the position where the lower end Pr of the printing paper P leaves the upstream paper feeding rollers 25a and 25b to the position shown in FIG. 13, only the downstream paper feeding rollers 25c and 25d are used. The sub-scan feed is performed, and printing is executed. In this embodiment, the sub-scan feed is performed only by the downstream paper feed rollers 25c and 25d, and the section in which printing is performed is relatively short, so that the print result has high image quality. In particular, the downstream paper feed roller 25d is a gear-shaped roller, and the combination of the downstream paper feed rollers 25c and 25d has lower feeding accuracy than the upstream paper feed rollers 25a and 25b. Therefore, the fact that the sub-scan feed is performed only by the downstream paper feed rollers 25c and 25d and the section in which printing is performed is relatively short is very effective in improving the quality of the print result. Note that the present invention is not limited to the above-described embodiment, and the above-described effect can be obtained if the nozzle near the upstream end in the sub-scanning direction is used to print the vicinity of the lower end Pr of the printing paper. This is particularly effective when the feeding accuracy of the downstream sub-scanning drive units (downstream paper feed rollers 25c and 25d) is relatively low.

(4) When printing the lower end portion, the printing paper P is supported at two places: the downstream paper feed rollers 25 c and 25 d and the upper surface of the platen 26. Therefore, the lower end portion of the printing paper P is relatively unlikely to be bent downward on the upstream groove portion 26f. Therefore, there is little possibility that the quality of the printing result of the upper end portion is deteriorated due to the bending of the printing paper.

(Iv) Lower end feed of comparative example:
FIG. 14 is a side view showing the relationship between the print head 28 and the printing paper P when printing the lower end Pr of the printing paper P in the comparative example. As shown in FIG. 14, even when the lower end portion of the printing paper P is printed in the downstream groove 26r, ink droplets that have not landed on the printing paper P do not land on the upper surface of the platen 26. However, in the comparative example, as shown in FIG. 14, the distance L42 to which the print paper is fed from the time when the lower end of the print paper leaves the upstream paper feed rollers 25a and 25b to the time when printing is completed is the case of the embodiment ( It is longer than L41) in FIG. In other words, the sub-scan feed is performed only by the downstream paper feed rollers 25c and 25d having relatively low feed accuracy, and the section in which printing is performed is long. For this reason, the quality of the printing result is lower than that of the embodiment.

(4) When printing the lower end portion, the printing paper P is held only by the downstream paper feed rollers 25c and 25d. For this reason, the lower end portion of the printing paper P easily bends downward on the downstream groove 26r. Therefore, when printing the lower end portion, there is a relatively high possibility that the quality of the print result is reduced.

C. Second embodiment:
FIG. 15 is a side view showing the relationship between the print head 28a, the upstream groove 26fa, and the downstream groove 26ra in the second embodiment. Here, the case where the upper end processing and the lower end processing are performed in a printing apparatus in which one nozzle row has 11 nozzles will be described. In the printing apparatus used here, the downstream groove 26ra is provided at a position facing the nozzles # 1 to # 3 in the sub-scanning direction. The upstream groove 26fa is provided at a position facing the nozzles # 9 to # 11. The other points are the same as those of the printing apparatus described above. In the second embodiment, overlap printing is not performed. That is, each raster is recorded by one nozzle in one main scan.

(1) Upper end processing of the second embodiment:
FIGS. 16 and 17 are explanatory views showing how each raster is recorded by which nozzle in the upper end processing of the second embodiment. 16 and 17 show the manner in which the head prints a raster, divided into upper and lower parts. The lower part of FIG. 16 is connected to the upper part of FIG. The 38th to 42nd rasters from the top are duplicated in FIGS. 16 and 17.

よ う As shown in FIG. 16, in the upper end process of the second embodiment, the sub-scan feed of three dots is repeated eleven times. In this upper end processing, nozzles other than the nozzles # 1 to # 3 of the print head 28a are not used. It should be noted that the nozzles surrounded by a thick frame in the drawing are nozzles that record dots in a raster.

After that, instead of performing the intermediate processing immediately, the “migration processing” is performed before performing the intermediate processing. In this transition processing, the sub-scan feed of three dots is performed four times as in the upper end processing. In the transition process, all nozzles # 1 to # 11 are used. Thereafter, as shown in FIG. 17, the process proceeds to the intermediate processing, and the regular feeding of 11 dots is repeated.

In FIG. 16, nozzles do not pass through the second, third, and sixth rasters from the top in the main scan during printing. Therefore, for the sixth raster from the top, pixels cannot be printed consecutively on adjacent rasters. In the present embodiment, these six rasters are “non-printable areas”. Also, for a raster such as the thirteenth or sixteenth raster from the top, which passes through two or more nozzles, only the nozzle that last passes through the raster records dots.

In the second embodiment, among the rasters on which the nozzles on the print head 28 can record dots, an image is recorded using the seventh raster (printable area) from the upstream end in the sub-scanning direction. it can. Therefore, the image data D used for printing is set from the seventh raster from the upstream end in the sub-scanning direction. However, for the same reason as in the first embodiment, printing starts not when the upper end of the printing paper P is at the seventh position from the upstream end in the sub-scanning direction but at the 23rd raster position. . That is, the assumed position of the upper end of the printing paper P with respect to each raster at the start of printing is the position of the 23rd raster from the upstream end in the sub-scanning direction, as shown in FIG. Therefore, in the second embodiment, the image data D is provided for 16 rasters beyond the assumed upper end position of the printing paper P. For this reason, even if an error occurs in the feeding of the printing paper P and the printing paper P is sent extra, if the error is within 16 rasters, it is necessary to form an image up to the upper end of the printing paper P without any blank space. Can be.

In the second embodiment, 16 rasters set beyond the assumed upper end position of the printing paper P and 20 rasters from the upper end position are recorded only by the nozzles # 1 to # 3. A downstream groove 26ra is provided below the nozzles # 1 to # 3. Therefore, even if ink droplets are ejected for the 16 rasters set above the assumed position of the upper end of the printing paper P (that is, in a range where no printing paper exists), the ink droplets are ejected on the platen 26a. There is no landing. Further, even if ink droplets are ejected to the raster assigned to the upper end of the printing paper P in a state where the printing paper P has not been sent to the expected position due to an error in the feeding of the printing paper P, If the error is within 20 rasters, no ink droplet will land on the platen 26a.

(2) Lower end processing of the second embodiment:
FIGS. 18 and 19 are explanatory diagrams showing how each raster is recorded by which nozzle in the lower end processing of the second embodiment. FIG. 18 shows the (n + 1) th and subsequent sub-scan feeds. FIGS. 18 and 19 show the manner in which the head records a raster, divided into upper and lower parts. The lower part of FIG. 18 is connected to the upper part of FIG. Note that the 45th to 40th rasters from the bottom are duplicated in FIGS. 18 and 19.

In the present embodiment, as shown in FIGS. 18 and 19, in the intermediate processing, the regular scanning of 11 dots is repeated in the (n + 1) -th to (n + 3) th sub-scanning transmissions, and then the 3-dot feeding is repeated four times in the transition processing. . Then, thereafter, in the lower end processing, three dots are fed using only the nozzles # 9 to # 11.

In the second embodiment, as shown in FIG. 19, among the rasters on which the nozzles on the print head 28 can record dots, the image is recorded using the seventh or more rasters (printable area) from the bottom. can do. However, in the second embodiment, an image is recorded using the eighth or more rasters from the bottom. That is, the eighth or more rasters from the bottom in FIG. 19 are print areas, and image data is set for those rasters.

In FIG. 19, the 13th and 16th rasters from the bottom are passed by two or more nozzles in the main scan during printing. For such a raster in which two or more nozzles pass in printing, the nozzle that first passes on the raster records dots.

In the second embodiment, an image can be recorded by using the eighth or more rasters from the downstream end in the sub-scanning direction among the rasters on which the nozzles on the print head 28 can record dots. Therefore, the image data D used for printing is set up to the eighth raster. However, for the same reason as in the first embodiment, printing ends when the lower end of the printing paper P is at the 38th raster position, not at the 8th position from the downstream end in the sub-scanning direction. . That is, the assumed position of the lower end of the printing paper P with respect to each raster at the end of printing is the position of the 38th raster from the downstream end in the sub-scanning direction, as shown in FIG. Therefore, in the second embodiment, the image data D is provided for 30 rasters beyond the assumed lower end position of the printing paper P. For this reason, even if an error occurs in the feeding of the printing paper P and the printing paper P is not sent to the expected position, if the error is within 30 rasters, it is possible to form an image with no blank space to the lower end.

Further, in the second embodiment, 30 rasters set beyond the assumed lower end position of the printing paper P and 20 rasters upstream from the lower end position are recorded only by the nozzles # 9 to # 11. . An upstream groove 26fa is provided below the nozzles # 9 to # 11. Therefore, even if an ink droplet is ejected to a raster set beyond the assumed position of the lower end of the printing paper P (that is, in a range where the printing paper does not exist), the ink droplet lands on the platen 26a. Nothing. Further, if an error occurs in the feeding of the printing paper P and the printing paper P is excessively fed, and ink droplets are ejected to the raster assigned to the lower end of the printing paper P, the feeding of the printing paper P is not performed. If the error is within 20 rasters, no ink droplet will land on the platen 26a.

When printing the lower end of the printing paper P, the printing paper P is fed a longer distance than when printing the upper end of the printing paper P. Therefore, when recording the lower end of the printing paper P, there is a high possibility that the error in the position of the printing paper P is larger than when recording the upper end of the printing paper P. The downstream paper feed roller 25d is a gear-shaped roller, and the combination of the downstream paper feed rollers 25c and 25d has a lower feeding accuracy than the upstream paper feed rollers 25a and 25b. Therefore, from this point, there is a high possibility that the error in recording the lower end side is larger than the error in the position of the printing paper P when recording the upper end side. Therefore, as in the second embodiment, the number of rasters recorded only by the nozzles (# 9 to # 11) on the upstream groove portion 26fa at the lower end portion of the printing paper P is reduced by the downstream groove at the upper end portion of the printing paper P. It is preferable that the number of rasters is set to be larger than the number of rasters recorded only by the nozzles (# 1 to # 3) on the unit 26ra. In the image data D, it is preferable that the number of rasters set above the lower end of the printing paper P be set larger than the number of rasters set above the upper end of the printing paper P.

D. Third embodiment:
FIG. 20 is a side view showing the relationship between the print head 28b, the upstream groove 26fb, and the downstream groove 26rb in the third embodiment. Here, a case where the upper end processing and the lower end processing are performed in a printing apparatus in which one nozzle row has 48 nozzles will be described. In the printing apparatus used here, the downstream groove 26rb is provided at a position facing the nozzles # 1 to # 12 in the sub-scanning direction. The upstream groove 26fb is provided at a position facing the nozzles # 37 to # 48. The other points are the same as those of the printing apparatus described above.

FIG. 21 is an explanatory diagram showing the arrangement of the inkjet nozzles Nz in the ink ejection heads 61b to 66b in the third embodiment. In the third embodiment, the pitch of each nozzle is equal to the pitch of the raster. Therefore, the print head 28b can record dots on adjacent raster lines in one main scan. In FIG. 21, an area facing the downstream groove 26rb on the platen 26b is indicated by Rr, and an area facing the upstream groove 26fb is indicated by Rf. Nozzles in the range Rr are nozzles # 1 to # 12, and nozzles in the range Rf are # 37 to # 48. In the third embodiment, overlap printing is performed using the print head 28b.

(1) Upper end processing of the third embodiment:
FIGS. 22 and 23 are explanatory diagrams showing how each raster is recorded by which nozzle in the upper end process of the third embodiment. The lower part of FIG. 22 is connected to the upper part of FIG. Note that the 66th to 74th rasters from the top are redundantly described.

示 す As shown in FIG. 22, in the upper end processing of the third embodiment, the sub-scan feed of 6 dots is repeated 10 times. This upper end processing is printing in the “first recording mode” described in the claims. In this upper end processing, nozzles other than the nozzles # 1 to # 12 of the print head 28b are not used. In the figure, nozzles surrounded by thick frames are nozzles that record dots on a raster. The nozzles used in the upper end processing are the nozzles shown as the nozzle group N1 in FIG.

After that, the “migration process” is performed. In this transition processing, the sub-scan feed of 6 dots is performed twice as in the upper end processing. In the transition process, after the first feed, dots are recorded by nozzles # 1 to # 12 as in the case of the upper end process. After the second feed, nozzles # 1 to # 30 are used. Thereafter, as shown in FIG. 23, the process proceeds to the intermediate processing, and the regular feeding of 24 dots is repeated. In the intermediate processing, all nozzles # 1 to # 48 are used. This intermediate processing is printing in the “second recording mode” described in the claims. The nozzles used after the second feed in the transition process are the nozzles shown as the nozzle group N2 in FIG. The nozzles used in the intermediate processing are the nozzles shown as the nozzle group N3 in FIG.

In FIG. 22, overlapping printing cannot be performed for the rasters from the top to the sixth in the main scan during printing because the nozzles pass only once in the main scan. In the present embodiment, these six rasters are “non-printable areas”. In addition, for a raster that passes through two or more nozzles, such as the 13th and subsequent rasters from the top, only the nozzle that passes through the last raster and the nozzle that passes through the raster immediately before that record dots. .

In the third embodiment, the image data D to be used for printing is set from the seventh raster from the upstream end in the sub-scanning direction, which is the upper end of the printable area. However, for the same reason as in the first embodiment, printing starts when the upper end of the printing paper P is at the 37th raster position from the upstream end in the sub-scanning direction. The position is shown as an assumed position of the upper end of the printing paper P in FIG. That is, in the third embodiment, the image data D is provided for 36 rasters beyond the assumed upper end position of the printing paper P. Therefore, even if an error occurs in the feeding of the printing paper P and the printing paper P is excessively fed, if the error is within 36 rasters, it is necessary to form an image up to the upper end of the printing paper P without any margin. Can be.

Further, in the third embodiment, 36 rasters set beyond the assumed upper end position of the printing paper P and 42 rasters from the upper end position are nozzles # 1 to # 12 on the downstream groove 26rb. Only recorded. Therefore, even if ink droplets are ejected to the 36 rasters set above the assumed position of the upper end of the printing paper P (that is, in a range where no printing paper exists), the ink droplets are ejected onto the platen 26a. There is no landing. Further, even if ink droplets are ejected to the raster assigned to the upper end of the printing paper P in a state where the printing paper P has not been sent to the expected position due to an error in the feeding of the printing paper P, If the error is within 42 rasters, ink droplets will not land on the platen 26b.

(2) Lower end processing of the third embodiment:
FIGS. 24 and 25 are explanatory views showing how each raster is recorded by which nozzle in the lower end processing of the third embodiment. The lower part of FIG. 24 leads to the upper part of FIG.

In the present embodiment, as shown in FIG. 24, after the regular feeding of 24 dots is repeated in the intermediate processing, the feeding of 6 dots is performed once in the transition processing. The nozzles used after the feed are # 19 to # 48. Thereafter, in the lower end processing, six dots are fed using only the nozzles # 37 to # 48. The nozzles used after the transfer of the transfer process are the nozzles shown as the nozzle group N4 in FIG. The nozzles used in the lower end processing are the nozzles shown as the nozzle group N5 in FIG.

In the third embodiment, as shown in FIG. 25, among the rasters on which the nozzles on the print head 28 can record dots, an image is recorded using the seventh or more rasters from the bottom (printable area). can do. However, in the third embodiment, an image is recorded using the ninth or more rasters from the bottom. That is, the ninth or more rasters from the bottom in FIG. 25 are print areas, and image data is set for those rasters.

In FIG. 25, the thirteenth or more rasters from the bottom are passed by two or more nozzles in the main scan during printing. For such a raster in which two or more nozzles pass in printing, the nozzle that first passes over the raster and the nozzle that subsequently passes through the raster record dots.

In the third embodiment, the image data D used for printing is set up to the ninth raster from the bottom. However, for the same reason as in the first embodiment, printing ends when the lower end of the printing paper P is not at the ninth position from the downstream end in the sub-scanning direction but at the 49th raster position. . FIG. 25 shows the assumed position of the lower end of the printing paper P with respect to each raster at the end of printing. Therefore, in the third embodiment, the image data D is provided for 40 rasters beyond the assumed lower end position of the printing paper P. For this reason, even if an error occurs in the feeding of the printing paper P and the printing paper P is not sent to the expected position, if the error is within 40 rasters, it is possible to form an image with no blank space at the lower end.

Further, in the third embodiment, 40 rasters set beyond the assumed lower end position of the printing paper P and 36 rasters upstream from the lower end position are nozzles # 37 to # 37 on the upstream groove portion 26fb. Recorded only in # 48. Therefore, even if an ink droplet is ejected to a raster set beyond the assumed position of the lower end of the printing paper P (that is, in a range where the printing paper does not exist), the ink droplet lands on the platen 26b. Nothing. Further, if an error occurs in the feeding of the printing paper P and the printing paper P is excessively fed, and ink droplets are ejected to the raster assigned to the lower end of the printing paper P, the feeding of the printing paper P is not performed. If the error is within 36 rasters, no ink droplet will land on the platen 26a.

Also in the third embodiment, the number of rasters recorded by only the nozzles (# 37 to # 48) on the upstream groove 26fb at the lower end of the printing paper P is determined by the downstream groove at the upper end of the printing paper P. The number is set to be larger than the number of rasters recorded by only the nozzles (# 1 to # 12) on 26 rb. In the image data D, the number of rasters set above the lower end of the printing paper P is set larger than the number of rasters set above the upper end of the printing paper P.

E. FIG. Embodiment having side grooves:
In the above description, as shown in FIGS. 9 and 13, in the printer 22 having the upstream groove 26f and the downstream groove 26r on the platen 26, the image data D set beyond the upper and lower ends of the printing paper P (see FIG. 8). ), The aspect of performing printing has been described. Here, in the printer 22n having the left side groove 26na and the right side groove 26nb in the platen in addition to the upstream side groove 26f and the downstream side groove 26r, based on the image data Dn set over the upper and lower ends and the left and right ends of the printing paper P. Next, an aspect of performing printing will be described.

FIG. 26 is a plan view showing the relationship between the image data Dn and the printing paper P. In FIG. 26, the image data Dn is set not only to the upper end Pf and the lower end Pr of the printing paper P but also to the outside of the printing paper P beyond the left end Pa and the right end Pb. As a result, in the present embodiment, the relationship between the size of the image data Dn and the printing paper P, and the relationship between the assumed position of the image data Dn at the time of printing and the arrangement of the printing paper P are as shown in FIG. The width of the image that can be recorded by the image data Dn (the width of the extended area) has a width that exceeds the left and right ends of the printing paper P, and exceeds the interval between the outer side walls of the left groove 26na and the right groove 26nb. With no width. Since the left and right names of the left end Pa and the right end Pb correspond to the left and right names of the printer 22, the actual left and right, left and right ends Pa and right end Pb of the printing paper P are the same. It is upside down.

FIG. 27 is a plan view showing the periphery of the platen 26n of the printer 22n. The printer 22n includes guides 29a and 29b for guiding the printing paper P to maintain a predetermined position in the main scanning direction during the sub-scanning of the printing paper P. The platen 26n is provided with an upstream groove 26f and a downstream groove 26r, similarly to the platen 26 in FIG. Further, the platen 26n is provided with a left groove 26na and a right groove 26nb extending in the sub-scanning direction so as to connect both ends of the upstream groove 26f and the downstream groove 26r. The left groove portion 26na and the right groove portion 26nb are provided in a range in the sub-scanning direction longer than a landing range of the ink droplet from the nozzle row on the print head. Further, the left groove portion 26na and the right groove portion 26nb are provided such that the interval between the respective center lines (in the main scanning direction) is equal to the width of the printing paper P in the main scanning direction. Other configurations are the same as those of the printer 22 described above.

When the printing paper P is at a predetermined main scanning position guided by the guides 29a and 29b, one side end Pa of the printing paper P in the main scanning direction is formed by the left groove 26na and the right groove 26nb. It suffices if it is provided so as to be located on the opening of 26na and the other side end Pb is located on the opening of the right groove 26nb. Therefore, as described above, when the printing paper P is at the fixed position, the left and right grooves 26na and 26nb have the side edges on the center line of the left and right grooves 26na and 26nb. May be provided so as to be located inside or outside the center line of the left groove 26na and the right groove 26nb.

The upstream groove 26f, the downstream groove 26r, the left groove 26na, and the right groove 26nb are connected to each other to form a quadrilateral groove. An absorbing member 27 for receiving and absorbing the ink droplet Ip is provided at the bottom thereof.

When the sub-scanning feed is being performed by the upstream paper feed rollers 25a and 25b and the downstream paper feed rollers 25c and 25d, the printing paper P passes over the openings of the upstream groove 26f and the downstream groove 26r. . The printing paper P is positioned in the main scanning direction by the guides 29a and 29b so that the left end Pa is located on the left groove 26na and the right end Pb is located on the right groove 26nb on the platen 26n. Have been. Therefore, at the time of the sub-scan feed, the feed is performed while maintaining both ends of the printing paper P on the openings of the left groove 26na and the right groove 26nb.

27 also in the mode of FIG. 27, the sub-scan feed of the upper end processing and the lower end processing is performed according to the above-described B.D. in accordance with the relative positional relationship between each nozzle of the nozzle row and the platen 26n. The first embodiment (see FIGS. 6, 7, 9, and 11 to 13), C.I. Second embodiment (see FIGS. 15 to 19), D.E. Feeding of the third embodiment (see FIGS. 20 to 25) and the like can be performed. Therefore, the printing of the side edges Pa and Pb of the printing paper P will be described below.

FIG. 28 is an explanatory diagram showing printing on the left and right ends of the printing paper P. In the mode of FIG. 27, printing is performed so that no margin is provided at the left and right ends of the printing paper P throughout the entire recording of the image on the printing paper P, including the upper end processing and the lower end processing. At that time, in the main scanning, the print head 28 is sent to one end at which all the nozzles are located beyond the end of the printing paper P and located outside the printing paper P, and the other end is also sent. All the nozzles are sent to a position beyond the other end of the printing paper P and located outside the printing paper P. Then, not only when the nozzle Nz is on the printing paper P, but also when the nozzle Nz is at a position beyond the edge of the printing paper P and is on the left groove 26na or the right groove 26nb, The ink droplet is ejected from the nozzle Nz according to Dn. Note that the image area (extended area) of the image data Dn has a width that exceeds the left and right ends of the printing paper P and has a width that does not exceed the interval between the outer side walls of the left groove 26na and the right groove 26nb. . For this reason, even when the nozzle is located on the left groove 26na or the right groove 26nb outside the printing paper P, ink droplets can be ejected according to the image data Dn.

印刷 By performing such printing, even when the printing paper P slightly shifts in the main scanning direction, an image can be formed without creating margins on both left and right ends of the printing paper P. Since the nozzles that print both side edges of the printing paper are nozzles located on the left groove 26na or the right groove 26nb, even when the ink drops come off the printing paper P, the ink drops remain in the center of the platen 26. Landing on the left groove 26na or the right groove 26nb without landing on 26c. Therefore, the printing paper P is not contaminated by ink droplets that have landed on the central portion 26c of the platen 26.

F. Modification:
The present invention is not limited to the above-described examples and embodiments, but can be implemented in various modes without departing from the gist of the invention, and for example, the following modifications are possible.

E1. Modification 1
In the first embodiment, the regular feed of one dot is performed in the upper end process and the lower end process, and the regular feed of three dots is performed in the second embodiment, and the regular feed is performed in 6 dots in the third embodiment. However, the feed of the upper end process and the lower end process is not limited to this, and regular feed of 2 dots, 4 dots, and 5 dots can be performed according to the number of nozzles in the nozzle row and the nozzle pitch. That is, any feed may be used as long as the maximum sub-scan feed amount is smaller than the maximum sub-scan feed amount in the intermediate processing. However, the smaller the feed amount of the sub-scan feed in the upper end process, the more the nozzle on the downstream side in the sub-scan direction can record the upper end of the printing paper. Therefore, the downstream groove can be made narrower, and the upper surface of the platen supporting the printing paper can be made wider. Similarly, as the feed amount of the sub-scan feed in the lower end process is smaller, the upper end of the printing paper can be recorded by the nozzle on the upstream side. Therefore, the upstream groove can be made narrower, and the upper surface of the platen supporting the printing paper can be made wider.

The feed in the intermediate processing is not limited to the irregular feed in which the feed of 5 dots, 2 dots, 3 dots, and 6 dots is repeated in that order, the regular feed of 11 dots, and the regular feed of 24 dots. For example, in the configuration shown in the first embodiment, a 5-dot, 3-dot, 2-dot, or 6-dot feed may be used. Further, other combinations of the feed amounts may be employed in accordance with the number of nozzles, the nozzle pitch, and the like, and regular feed of other feed amounts may be performed. That is, as long as the maximum sub-scan feed amount is larger than the maximum sub-scan feed amount in the upper end processing or the lower end end processing, any sub-scan feed may be performed.

E2. Modified example 2:
In the above embodiment, the image set beyond the edge of the printing paper is two rasters on both the upper side and the lower side in the first embodiment, and the upper end side is 16 rasters and the lower end side is 30 rasters in the second embodiment. It was a raster. In the third embodiment, the upper end side has 30 rasters and the lower end side has 40 rasters. However, the size of the image set beyond the edge of the printing paper is not limited to this. For example, the width of the portion of the image data D set beyond the upper end Pf of the printing paper P to the outside of the printing paper P can be set to half the width of the downstream groove 26r. Similarly, the width of the portion of the image data D set beyond the lower end Pr of the printing paper P to the outside of the printing paper P can be set to a half of the width of the upstream groove 26f. That is, the width of the part of the image data set beyond the edge of the printing paper to the outside of the printing paper may be smaller than the width of the downstream groove 26r on the upper end side, and may be smaller than the width of the upstream groove 26f on the lower end side. It should just be smaller than the width of. By doing so, even when the edge of the printing paper P is not at the expected position, the ink droplet Ip for recording the image set beyond the printing paper P may land on the upper surface of the platen 26. Absent. However, if the width of the groove is set to ２, the same amount of deviation can be permitted both when the printing paper P shifts to the upstream side and when it shifts to the downstream side.

Similarly, for the left and right side edges, the width of the portion of the image data set beyond the edge of the printing paper to the outside of the printing paper may be smaller than the width of the left groove 26na and the right groove 26nb. If the width of the groove is set to も, the same amount of deviation can be permitted both when the printing paper P shifts to the upstream side and when it shifts to the downstream side.

E3. Modification 3:
In the above embodiment, both the upper end processing and the lower end processing are executed, but only one of them may be executed as necessary. Further, the printing apparatus of the present embodiment includes the upstream groove portion 26f and the downstream groove portion 26r on the upstream side and the downstream side of the platen 26 in the sub-scanning direction, respectively, but may include only one of them. .

E4. Modification 4:
In the above embodiment, a part of the configuration realized by hardware may be replaced with software, and conversely, a part of the configuration realized by software may be replaced with hardware. For example, a part of the functions of the CPU 41 (FIG. 4) may be executed by the host computer 90.

(4) A computer program for realizing such functions is provided in a form recorded on a computer-readable recording medium such as a floppy disk or a CD-ROM. The host computer 90 reads the computer program from the recording medium and transfers it to an internal storage device or an external storage device. Alternatively, a computer program may be supplied from the program supply device to the host computer 90 via a communication path. When implementing the functions of the computer program, the computer program stored in the internal storage device is executed by the microprocessor of the host computer 90. Further, the host computer 90 may directly execute the computer program recorded on the recording medium.

<< In this specification, the host computer 90 is a concept including a hardware device and an operation system, and means a hardware device operating under the control of the operation system. The computer program causes the host computer 90 to realize the functions of the above-described units. Some of the functions described above may be realized by an operation system instead of the application program.

In the present invention, the “computer-readable recording medium” is not limited to a portable recording medium such as a flexible disk or a CD-ROM, but may be an internal storage device in a computer such as various RAMs and ROMs, An external storage device such as a hard disk fixed to the computer is also included.

FIG. 2 is an enlarged plan view showing the structure of a part of the left side of a platen of the inkjet printer according to the embodiment of the present invention. FIG. 1 is a block diagram illustrating a configuration of an image processing apparatus and a printing apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a software configuration of the printing apparatus. FIG. 2 is a diagram illustrating a configuration of a mechanical part of the printing apparatus. FIG. 4 is a plan view showing an example of an arrangement of nozzle units for each color in a print head unit 60. FIG. 3 is a plan view showing the periphery of a platen 26. FIG. 4 is an explanatory diagram showing how each raster is recorded by which nozzle near the upper end (leading end) of a print sheet. FIG. 3 is a plan view showing the relationship between image data D and printing paper P. FIG. 4 is a side view showing the relationship between the print head and the printing paper at the start of printing. FIG. 7 is a side view illustrating a relationship between a print head and a print sheet at the start of printing in a comparative example. FIG. 7 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process. FIG. 9 is a plan view showing a relationship between the upstream groove 26f and the printing paper P when printing the lower end Pr of the printing paper P. FIG. 6 is a side view illustrating a relationship between the print head and the print paper when printing the lowermost end of the print paper. FIG. 9 is a side view showing the relationship between the print head and the printing paper P when printing the lowermost end of the printing paper in the comparative example. FIG. 10 is a side view showing the relationship between the print head 28a and the upstream groove 26fa and the downstream groove 26ra in the second embodiment. FIG. 13 is an explanatory diagram showing how each raster is recorded by which nozzle in the upper end process of the second embodiment. FIG. 13 is an explanatory diagram showing how each raster is recorded by which nozzle in the upper end process of the second embodiment. FIG. 9 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process of the second embodiment. FIG. 9 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process of the second embodiment. FIG. 14 is a side view showing the relationship between the print head 28b, the upstream groove 26fb, and the downstream groove 26rb in the third embodiment. FIG. 13 is an explanatory diagram showing an arrangement of inkjet nozzles Nz in ink ejection heads 61b to 66b in a third embodiment. FIG. 11 is an explanatory diagram showing how each raster is recorded by which nozzle in the upper end process of the third embodiment. FIG. 11 is an explanatory diagram showing how each raster is recorded by which nozzle in the upper end process of the third embodiment. FIG. 13 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process of the third embodiment. FIG. 13 is an explanatory diagram showing how each raster is recorded by which nozzle in the lower end process of the third embodiment. FIG. 3 is a plan view showing a relationship between image data Dn and printing paper P. FIG. 5 is a plan view illustrating a periphery of a platen 26n of the printer 22n. FIG. 3 is an explanatory diagram illustrating printing of left and right end portions of a printing sheet P. FIG. 6 is a side view showing the periphery of a print head of a conventional printer.

Explanation of reference numerals

12 Scanner 14 Keyboard 15 Flexible drive 16 Hard disk 18 Modem 21 CRT
22, 22n printer 23 paper feed motor 24 carriage motor 25a, 25b upstream paper feed roller 25c, 25d downstream paper feed roller 25p, 25q upstream paper feed roller 25r, 25s downstream paper feed roller 26, 26a, 26b, 26n, 26o Platen 26c Central portion 26f, 26fa, 26fb Upstream groove 26na Left groove 26nb Right groove 26r, 26ra, 26rb Downstream groove 27, 27f, 27r Absorbing member 28 , 28a, 28b, 28o Printhead 29a, 29b Guide 31 Carriage 32 Operation panel 34 Sliding shaft 36 Drive belt 38 Pulley 39 Position detection sensor 40 Control circuit 41 CPU
42 ... PROM
43 ... RAM
44 ... Drive buffer 45 ... PC interface 60 ... Print head unit 61-66 ... Ink ejection head 61b-66b ... Ink ejection head 67 ... Introduction pipe 68 ... Ink passage 71 ... Cartridge 72 ... Color ink cartridge 80 ... Bus 81 ... CPU
82 ROM
83 ... RAM
84 input interface 85 output interface 86 CRTC
88 ... SIO
90 host computer 91 video driver 95 application program 96 printer driver 97 resolution conversion module 98 color correction module 99 halftone module 100 rasterizer A arrow D, Dn image data DT dot formation pattern table FD ... Flexible disk Ip ... Ink droplets L31 ... Distance printed and printed by only the upstream paper feed roller L41 ... Distance printed and printed by only the downstream paper feed roller L32 ... Only by the upstream paper feed roller Distance for sub-scan feed and printing L42 Distance for sub-scan feed and printing only by downstream paper feed roller LUT Color correction table MS Arrow N1 Nozzle group used in upper end processing N2 Used for transition processing Nozzle group N3 ... Nozzle group used in intermediate processing N4 ... Nozzle group used in transition processing N5 ... Nozzle group used in lower end processing Nf ... Upstream nozzle group Nr ... Downstream nozzle group Nz ... Inkjet nozzle ORG: Original color image data P: Printing paper PD: Printing data PE: Piezo element PNT: Public telephone line Pa: Left end (part)
Pb: Right end (part)
Pf: Upper end (part)
Pr: Lower end (part)
R26: A range where the center of the platen is provided Rf: A range where the upstream groove is provided Rr: A range where the downstream groove is provided SS: Arrow SV: Server k: Nozzle pitch

Claims (10)

In a dot recording apparatus that records dots on the surface of a printing medium using a dot recording head provided with a plurality of dot forming elements that eject ink droplets, at least one of the dot recording head and the printing medium is driven. While performing main scanning, at least a part of the plurality of dot forming elements is driven to form dots, and the printing medium is driven in a direction intersecting with the main scanning direction during the main scanning. A dot recording method for performing sub-scanning,
The dot recording device,
At least a part of the main scanning path is provided to extend in the main scanning direction so as to face the dot forming element, and at least an upstream end of the plurality of dot forming elements in the sub scanning direction is provided. An upstream groove provided at a position facing the located dot forming element, and a downstream provided at a position facing the dot forming element located at least at the downstream end in the sub-scanning direction among the plurality of dot forming elements. A side groove portion; and a platen having:
The dot recording method comprises:
(A) preparing print data including image data for recording an image in an extended area having a length exceeding at least the upper and lower ends of the print medium;
(B) ejecting ink droplets to the extended area based on the print data;
Dot recording method comprising: The dot recording method according to claim 1, wherein
The step (b) comprises:
(B1) when ejecting ink droplets to the upper end of the print medium, the print medium is supported by the platen, and the upper end of the print medium is above the opening of the downstream groove, and the upper end is Setting a position of the print medium in the sub-scanning direction so as to be located at a position downstream of the dot forming element in the sub-scanning direction in the sub-scanning direction,
(B2) when ejecting ink droplets to the lower end of the print medium, the print medium is supported by the platen, and the lower end of the print medium is above the opening of the upstream groove; and Setting the position of the print medium in the sub-scanning direction such that the lower end of the print medium is located at a position downstream of the dot forming element at the upstream end in the sub-scanning direction in the sub-scanning direction. And a dot recording method comprising: The dot recording method according to claim 1, wherein
The platen is further provided in a range including at least a landing range of ink droplets from the plurality of dot forming elements in the sub-scanning direction, and a pair of the platens are provided at intervals substantially equal to the width of the print medium. It has a side groove,
The step (a) comprises:
(A1) The image for recording an image in the extension area having a width exceeding the left and right ends of the print medium and having a width not exceeding the interval between the outer side walls of the pair of side grooves. A dot recording method including a step of preparing print data including data. The dot recording method according to claim 3, wherein
The step (b) comprises:
(B3) The position of the print medium in the main scanning direction is adjusted such that the print medium is supported by the platen and both ends of the print medium are located above the openings of the side grooves. A dot recording method including a setting step. The dot recording method according to any one of claims 1 to 4, wherein
The step (a) comprises:
(A2) A dot recording method, comprising a step of preparing the print data having, as the image data, information of a dot recording state in each pixel in the extended area. A dot recording apparatus that records dots on the surface of a print medium using a dot recording head provided with a plurality of dot forming elements that eject ink droplets,
A main scanning drive unit that performs main scanning by driving at least one of the dot recording head and the printing medium;
A head driving unit that drives at least a part of the plurality of dot forming elements to form dots during the main scanning;
A platen provided extending in the main scanning direction so as to face the dot forming element in at least a part of a path of the main scanning;
A sub-scanning drive unit that performs sub-scanning by driving the print medium in a direction intersecting with the main scanning direction during the main scanning;
A control unit for controlling each of the units,
The platen is
An upstream groove portion provided in the main scanning direction at a position facing the dot forming element located at least at the upstream end in the sub-scanning direction of the plurality of dot forming elements,
A downstream groove portion extending in the main scanning direction at a position facing a dot forming element positioned at least at a downstream end in the sub-scanning direction among the plurality of dot forming elements, Yes,
The control unit includes:
A print data storage unit that stores print data including image data for recording an image in an extended area having a length exceeding at least the upper and lower ends of the print medium,
An edge printing unit that ejects ink droplets to the extended area based on the print data,
Dot recording device comprising: The dot recording apparatus according to claim 6, wherein
The control unit further includes:
When ejecting ink droplets to the upper end of the print medium, the print medium is supported by the platen, and the upper end of the print medium is above the opening of the downstream groove, and the upper end is the sub-scan. An upper end positioning unit that sets the position of the print medium in the sub-scanning direction so as to be located at a position upstream of the dot forming element at the downstream end of the direction in the sub-scanning direction.
When ejecting ink droplets to the lower end of the print medium, the print medium is supported by the platen, and the lower end of the print medium is above the opening of the upstream groove, and the lower end of the print medium is A lower end positioning unit that sets the position of the print medium in the sub-scanning direction so as to be located at a position downstream of the dot forming element at the upstream end in the sub-scanning direction in the sub-scanning direction;
Dot recording device comprising: The dot recording apparatus according to claim 7, wherein
The platen is further provided in a range including at least a landing range of ink droplets from the plurality of dot forming elements in the sub-scanning direction, and a pair of the platens are provided at intervals substantially equal to the width of the print medium. It has a side groove,
The dot recording apparatus may further include: the print medium is supported by the platen; and the main scanning direction is such that both side edges of the print medium are respectively located on the openings of the side grooves. Equipped with a guide portion for positioning the print medium,
The print data has a width exceeding the left and right ends of the print medium, and for recording an image in the extension area having a width not exceeding the interval between the outer side walls of the pair of side groove portions. A dot recording device including the image data. The dot recording apparatus according to any one of claims 6 to 8, wherein
The dot recording apparatus, wherein the print data is data having, as the image data, information on a dot recording state of each pixel in the extended area. A computer including a dot recording device that records dots on the surface of a print medium using a dot recording head provided with a plurality of dot forming elements that eject ink droplets, wherein at least one of the dot recording head and the printing medium is provided. While driving and performing main scanning, at least a part of the plurality of dot forming elements is driven to form dots, and the print medium is interposed between the main scanning in a direction intersecting with the main scanning direction. A computer-readable recording medium that records a computer program for driving and performing sub-scanning,
The dot recording device is provided to extend in the main scanning direction so as to face the dot forming element in at least a part of the main scanning path, and at least the sub-scanning direction of the plurality of dot forming elements is provided. An upstream groove provided at a position facing a dot forming element located at an upstream end of the plurality of dot forming elements, and a dot forming element located at least at a downstream end of the plurality of dot forming elements in the sub-scanning direction. A downstream groove provided at the position, and a platen having:
The recording medium,
A function of preparing print data including image data for recording an image in an extended area having a length exceeding at least the upper and lower ends of the print medium,
A function of ejecting ink droplets to the extended area based on the image data;
And a computer-readable recording medium recording a computer program for causing the computer to realize the above.

Images