JP2013022827A - Image recording device, image recording method, program, and program recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress liquid consumption due to maintenance.SOLUTION: An image recording device includes a control unit which can execute image recording processing by performing main scanning for injecting liquid from a nozzle while moving a recording unit having a plurality of nozzles arranged in a sub scanning direction in the main scanning direction in a plurality of recording modes having different combinations of nozzles for injecting liquid from each other, and a maintenance unit which performs maintenance of the nozzle while discharging the liquid from the nozzle before the image recording processing is started. The nozzle which injects the liquid in the image recording processing is selected from the plurality of nozzles in accordance with a recording mode selected from the plurality of recording modes as a mode for executing the image recording processing and the width of the recording medium, and maintenance is not performed with respect to the nozzle which does not inject the liquid in the image recording processing while executing the image recording processing by the selected nozzle.

Description

  The present invention relates to a technology for recording an image on a recording medium by ejecting liquid from a nozzle, and more particularly to a technology for performing maintenance of the nozzle.

  2. Related Art An ink jet printer that records an image on a recording medium by ejecting ink (liquid) from a nozzle is conventionally known. Further, in such a printer, in order to suppress nozzle clogging and dirt, it is common to perform nozzle maintenance as appropriate. For example, in the printer described in Patent Document 1, maintenance such as cleaning that forcibly sucks ink from the nozzles to prevent clogging of the nozzles, and wiping that wipes the nozzle formation surface with a wiper to suppress contamination of the nozzles is performed. Executed.

JP 2010-142981 A

  By the way, the above-described maintenance such as cleaning and wiping involves discharging the liquid from the nozzle. That is, the cleaning is performed by sucking the liquid from the nozzle. Further, the wiping can be performed while the liquid is flowing out from the nozzle in order to smoothly wipe the wiper. Therefore, from the viewpoint of suppressing liquid consumption, an increase in liquid consumption due to maintenance may be a problem.

  This invention is made | formed in view of the said subject, and aims at provision of the technique which can suppress the consumption of the liquid by a maintenance.

  In order to achieve the above object, an image recording apparatus according to the present invention includes a support member that supports a recording medium having a width in the sub-scanning direction, a recording unit that includes a plurality of nozzles arranged in the sub-scanning direction, and a recording unit. An image recording process for recording an image on a recording medium that performs main scanning for ejecting liquid from nozzles while moving in the main scanning direction and stops on a support member is performed in a plurality of recording modes in which combinations of nozzles for ejecting liquids are different from each other A control unit that can be executed and a maintenance unit that performs maintenance of the nozzle while discharging liquid before the image recording process is started, and the control unit executes the image recording process from a plurality of recording modes. According to the selected recording mode and the width of the recording medium, a nozzle for ejecting liquid in the image recording process is selected from a plurality of nozzles and selected. Executes the image recording process by the nozzle, the maintenance unit, the nozzle without ejecting the liquid in the image recording process is characterized by not performing maintenance.

  In order to achieve the above object, the image recording method according to the present invention performs main scanning in which liquid is ejected from nozzles while moving a recording unit having a plurality of nozzles arranged in the sub-scanning direction in the main scanning direction. An image recording process in which an image recording process for recording an image on a recording medium stopped on a support member can be performed in a plurality of recording modes in which combinations of nozzles for ejecting liquids are different from each other, and before the image recording process is started. A maintenance process for maintaining the nozzle while discharging liquid from the nozzle, and in the image recording process, according to the recording mode selected to execute the image recording process from a plurality of recording modes and the width of the recording medium, A nozzle for ejecting liquid is selected from a plurality of nozzles, and image recording processing is executed by the selected nozzle, and maintenance is performed. The extent, to the nozzle without ejecting the liquid in the image recording process is characterized in that the maintenance is not performed.

  Further, the program according to the present invention performs image scanning on a recording medium that stops a support member by performing main scanning in which liquid is ejected from nozzles while moving a recording unit having a plurality of nozzles arranged in the sub-scanning direction in the main scanning direction. A program for causing an image recording apparatus to execute image recording processing using a computer, wherein the image recording processing can be executed in a plurality of recording modes in which combinations of nozzles for ejecting liquids are different from each other, and Selecting a nozzle for ejecting liquid from a plurality of nozzles according to the recording mode selected to execute the image recording process from the recording mode and the width of the recording medium, and executing the image recording process by the selected nozzle; In the maintenance of the nozzle performed while discharging the liquid from the nozzle before the image recording process is started, For nozzles without ejecting the liquid in the recording process is characterized by to be executed by the image recording apparatus using a computer and a maintenance is not performed steps.

  A program recording medium according to the present invention is characterized in that the program is recorded.

  In the invention thus configured (image recording apparatus, image recording method, program, program recording medium), an image is recorded on a recording medium having a width in the sub-scanning direction using a recording unit having a plurality of nozzles in the sub-scanning direction. Record. Specifically, main scanning is performed by ejecting liquid from the nozzles while moving the recording unit in the main scanning direction, and an image is recorded on the recording medium (image recording processing). Incidentally, this image recording process can be executed in a plurality of recording modes in which combinations of nozzles for ejecting liquids are different from each other. Therefore, in the image recording process, nozzles are selected according to a recording mode selected from a plurality of recording modes as the image recording process, and these selected nozzles eject liquid to be used for the image recording process. . Furthermore, in order to cope with not only the recording mode but also the width of the recording medium, the selection of the nozzle for ejecting the liquid in the image recording process is executed according to the width of the recording medium.

  As described above, according to the present invention, the nozzle that ejects the liquid in the image recording process is selected according to the recording mode and the width of the recording medium. Therefore, the nozzle that actually ejects the liquid in the image recording process varies depending on the recording mode and the width of the recording medium. On the other hand, it is sufficient that the maintenance before the start of the image recording process is performed on the nozzle that ejects the liquid in the image recording process. Therefore, the present invention has a configuration in which maintenance is not performed for nozzles that do not eject liquid in the image recording process. Accordingly, it is possible to suppress the consumption of the liquid due to the maintenance by refraining from the maintenance of the nozzle that does not eject the liquid in the image recording process.

  Incidentally, the image recording apparatus may be configured to execute the following recording modes as a plurality of recording modes. That is, the control unit performs main scanning a plurality of times alternately with sub-scanning that moves the recording head in the sub-scanning direction, and generates a plurality of line images for one line extending in the main scanning direction formed by the nozzles in the sub-scanning direction. In an image recording apparatus formed side by side, a plurality of recording modes include a first recording mode in which two line images adjacent in the sub-scanning direction are continuously formed by the same nozzle, and two adjacent in the sub-scanning direction. The image recording apparatus may be configured to include a second recording mode in which line images are continuously formed with different nozzles.

  Further, in the image recording process, the image recording apparatus may be configured so that the recording unit is moved only in one direction of the sub-scanning direction and the sub-scan is executed one or more times. As described above, the movement control is simplified by configuring the image recording apparatus so that the recording head is moved only in one direction (not both directions) in the sub-scanning direction.

  At this time, when the line image formed first is the first line image and the line image formed later is the second line image of the two line images formed continuously, the second line image is the second line image. In the recording mode, the image recording apparatus is configured so that the line image is formed later by the nozzle provided upstream in one direction of the sub-scanning direction in the recording unit than the nozzle that formed the previous line image. Also good.

1 is a schematic diagram illustrating an example of a printing system to which the present invention can be applied. The top view which shows the structure of a recording unit partially. The fragmentary sectional view which shows the structure of a maintenance unit typically. The partial top view which shows typically the structure of a maintenance unit. FIG. 2 is a block diagram schematically showing an electrical configuration included in the printing system of FIG. 1. The figure which shows the operation | movement of the printing mode of 4 and 6 pass performed by 1st printing mode. The figure which shows operation | movement of the 8-pass printing mode performed in 2nd printing mode. The figure which shows operation | movement of the 16-pass print mode performed in 2nd print mode. The figure which shows operation | movement of the 16-pass print mode performed in 2nd print mode. Explanatory drawing of the nozzle selection operation | movement in 1st printing mode. Explanatory drawing of the nozzle selection operation | movement in 2nd printing mode. The flowchart which shows an example of embodiment of this invention. The flowchart which shows the flow of a maintenance process.

First Embodiment FIG. 1 is a schematic diagram showing an example of a printing system to which the present invention is applicable. In FIG. 1 and the following drawings, XYZ orthogonal coordinates with the Z axis as the vertical axis are also shown as necessary in order to clarify the arrangement relationship of each part of the apparatus. In the following explanation, the direction in which each coordinate axis (the arrow) faces is a positive direction, the opposite direction is a negative direction, the positive side of the Z axis is the upper side, and the negative side of the Z axis is the lower side.

  The printing system 100 includes a host device 200 that generates print data based on image data received from an external device such as a personal computer, and a printer 300 that prints an image based on print data received from the host device 200. The printer 300 prints an image on the sheet S using an inkjet method while feeding out a long sheet S wound in a roll shape.

  As shown in FIG. 1, the printer 300 includes a main body case 1 having a substantially rectangular parallelepiped shape. In the main body case 1, a feeding unit 2 that feeds out the sheet S from a roll R 1 around which the sheet S is wound, a printing chamber 3 that performs printing by ejecting ink onto the fed sheet S, and a sheet S to which the ink has adhered are arranged. A drying unit 4 for drying and a winding unit 5 for winding the dried sheet S as a roll R2 are arranged.

  More specifically, the inside of the main body case 1 is partitioned vertically in the Z-axis direction by a flat base 6 arranged in parallel (that is, horizontally) to the XY plane, and the upper side of the base 6 is the printing chamber 3. It has become. A platen 30 is fixed to the upper surface of the base 6 at a substantially central portion in the printing chamber 3. The platen 30 has a rectangular shape, and supports the sheet S from below by its upper surface parallel to the XY plane. Then, the recording unit 31 performs printing on the sheet S supported on the platen 30.

  On the other hand, the feeding unit 2, the drying unit 4, and the winding unit 5 are disposed below the base 6. The feeding unit 2 is disposed below the platen 30 in the negative direction of the X axis (left obliquely lower in FIG. 1) and includes a rotatable feeding shaft 21. And the sheet | seat S is wound around this delivery axis | shaft 21, and roll R1 is supported. On the other hand, the winding unit 5 is disposed below the platen 30 in the positive X-axis direction (downwardly to the right in FIG. 1), and includes a rotatable winding shaft 51. The sheet S is wound around the winding shaft 51, and the roll R2 is supported. Further, the drying unit 4 is disposed directly below the platen 30 between the feeding unit 2 and the winding unit 5 in the X-axis direction. The drying unit 4 is slightly above the feeding unit 2 and the winding unit 5.

  Then, the sheet S conveyed from the feeding unit 2 to the winding unit 5 sequentially passes through the printing chamber 3 and the drying unit 4 while being guided by the seven rollers 71 to 77. That is, the roller 71 is arranged in the X-axis positive direction of the feeding shaft 21 provided in the feeding unit 2, and the sheet S fed out from the feeding shaft 21 in the X-axis positive direction is wound around the roller 71 and moved upward. It is guided.

  Above the roller 71 and inside the printing chamber 3, a ground electrode roller 81 and two rollers 72 and 73 of a corona treatment machine 8 to be described later are arranged in this order in the positive direction of the X axis. The ground electrode roller 81 is slightly below the two rollers 72 and 73. Therefore, the sheet S guided upward from the roller 71 is wound around the two rollers 72 and 73 after being wound around the ground electrode roller 81 and changing its direction obliquely upward.

  These rollers 72 and 73 are arranged in a straight line (that is, horizontally) in the X-axis direction so as to sandwich the platen 30, and each top has the same height as the upper surface of the platen 30 (surface that supports the sheet S). The position is adjusted so that Accordingly, the sheet S wound around the roller 72 moves horizontally (in the X-axis direction) while being in sliding contact with the upper surface of the platen 30 until reaching the roller 73. Then, the sheet S wound around the roller 73 is guided downward.

  Below the roller 73 (below the base 6), two rollers 74 and 75 are arranged in this order in the negative X-axis direction. The sheet S wound around the rollers 74 and 75 is guided between the rollers 74 and 75 in parallel (that is, horizontally) in the X-axis direction. A drying unit 4 is disposed between the rollers 74 and 75. Accordingly, the sheet S wound around the roller 74 changes its direction in the negative X-axis direction and passes through the inside of the drying unit 4 until reaching the roller 75.

  Below the roller 75, the two rollers 76 and 77 are arranged in this order in the positive direction of the X axis. Then, the sheet S wound around the roller 76 changes its direction in the X axis positive direction and reaches the roller 77. Further, the sheet S wound around the roller 77 is wound around the winding shaft 51 of the winding unit 5 arranged in the positive X-axis direction of the roller 77.

  In this way, the sheet S fed out from the feeding unit 2 passes through the printing chamber 3 and the drying unit 4 and is taken up by the winding unit 5. The sheet S is subjected to a printing process in the printing chamber 3 and a drying process in the drying unit 4.

  The printing process in the printing chamber 3 is executed by the recording unit 31 arranged on the upper side of the platen 30. The recording unit 31 uses an ink jet system to supply ink supplied by an ink supply mechanism (not shown) from an ink cartridge CR disposed at the end in the negative X-axis direction (the left end in FIG. 1) in the printing chamber 3 using a sheet S. To be printed. Specifically, the recording unit 31 includes a carriage 32, a flat support plate 33 attached to the lower surface of the carriage 32, and a plurality of recording heads 34 attached to the lower surface of the support plate 33.

  FIG. 2 is a plan view partially showing the configuration of the recording unit. As shown in FIG. 2, on the lower surface of the support plate 33, fifteen recording heads 34 are arranged in two rows in a staggered manner at an equal pitch in the Y-axis direction. These recording heads 34 eject ink from nozzles 35 and have the same configuration. Therefore, in the following, the details of the configuration will be described on behalf of one recording head 34.

  On the lower surface of the recording head 34, a plurality of (for example, 180) nozzles 35 are arranged in a straight line at an equal pitch (= P35) in the Y-axis direction to form one nozzle row 35L, and a plurality of nozzle rows 35L are formed. They are arranged at an equal pitch in the X-axis direction. The plurality of nozzle rows 35L arranged on the lower surface of the recording head 34 correspond to mutually different ink colors. For example, when eight colors of ink are used, eight nozzle rows 35L are arranged on the lower surface of the recording head 34. The nozzles 35 belonging to the same nozzle row 35L eject the same color ink, while the nozzles 35 belonging to different nozzle rows 35L eject different color inks. The nozzle 35 is of a piezo type that ejects ink out of the tube by applying a voltage to a piezo element attached to a fine tube filled with ink and deforming it.

  Three or four such recording heads 34 are collected to constitute one head unit 34u. As a result, one head unit 34u composed of three recording heads 34 and three head units 34u composed of four recording heads 34 are arranged in this order in the Y-axis positive direction.

  Returning to FIG. 1, the description will be continued. The carriage 32 of the recording unit 31 configured as described above is movable together with the support plate 33 and the recording head 34. Specifically, a first guide rail 36 extending in the X-axis direction is provided in the printing chamber 3, and the carriage 32 receives the driving force of the first CR motor Mx (FIG. 5) and receives the first guide. It moves along the rail 36 in the X-axis direction. Furthermore, a second guide rail (not shown) extending in the Y-axis direction is provided in the printing chamber 3, and the carriage 32 receives the driving force of the second CR motor My (FIG. 5) and receives the second guide. Move along the rail in the Y-axis direction.

  Then, printing is executed by moving the carriage 32 of the recording unit 31 two-dimensionally within the XY plane with respect to the sheet S stopped on the upper surface of the platen 30. Specifically, the recording unit 31 performs an operation (main scanning) of ejecting ink from each nozzle 35 of the recording head 34 to the sheet S while moving the carriage 32 in the X-axis direction (main scanning direction). In this main scanning, a two-dimensional image is printed by arranging a plurality of one-line images (line images) extending in the X-axis direction and spaced apart in the Y-axis direction, formed by ink ejected from one nozzle. Is done. Then, the main scan and the sub scan for moving the carriage 32 in the positive Y-axis direction (sub scan direction) are alternately executed, and a plurality of main scans are executed (lateral scan method).

  That is, when the recording unit 31 completes one main scan, the recording unit 31 performs sub-scanning to move the carriage 32 in the positive Y-axis direction. Subsequently, the recording unit 31 moves the carriage 32 in the X-axis direction (opposite to the previous main scanning) from the position moved by the sub-scanning. As a result, a new main scan line image is formed between each of the plurality of line images already formed by the previous main scan. Then, these main scanning and sub-scanning are executed alternately. That is, in this printer 300, the operation (main scanning) for forming an intermediate generation image including a plurality of line images by ejecting ink from the nozzles 35 while moving the carriage 32 in the X-axis direction is performed in the Y-axis direction. By changing the position (sub-scanning) and executing a plurality of times, an image in which the intermediate generation images are superimposed is formed.

  In this way, one printing is executed by executing a plurality of main scans. Here, one main scan is referred to as “pass”, and one printing executed by a plurality of passes is referred to as “frame”. Further, an intermediate generated image formed on the sheet S in one pass is referred to as “one pass image”.

  In this embodiment, four types of print modes for forming one frame in four passes, six passes, eight passes, and sixteen passes are prepared, and printing can be executed in one print mode selected from these. Of these, the 4- to 8-pass printing mode is provided mainly for resolution adjustment. That is, by executing M passes and superimposing M one-pass images, it is possible to obtain an image for one frame having a resolution M times that of the one-pass image. The 16-pass printing mode has the same resolution as the 8-pass printing mode, but realizes printing with higher image quality by executing printing in a mode different from the 8-pass printing mode. . Details of these printing modes will be described later with reference to FIGS.

  Incidentally, the carriage 32 can reciprocate in the X-axis direction. Therefore, the recording unit 31 efficiently executes a plurality of passes by executing passes on each of the forward path and the return path of the carriage 32. Similarly, the carriage 32 can reciprocate also in the Y-axis direction. However, in each sub-scan executed during printing for one frame, the carriage 32 moves only in the positive Y-axis direction. Thereby, the movement control of the carriage 32 is simplified.

  The printing of one frame as described above is repeatedly executed while the sheet S is moved intermittently in the X-axis direction. Specifically, a predetermined range over almost the entire upper surface of the platen 30 is a printing area. Then, the sheet S is intermittently conveyed in the X-axis direction in units of a distance (intermittent conveyance distance) corresponding to the length in the X-axis direction of the printing area, and stopped on the upper surface of the platen 30 during the intermittent conveyance. One frame is printed on the sheet S to be printed. Specifically, when printing of one frame is completed on the sheet S stopped on the platen 30, the sheet S is transported in the X-axis direction by the intermittent transport distance, and the unprinted surface of the sheet S stops on the platen 30. . Subsequently, printing of one frame is newly performed on this unprinted surface, and when this is completed, the sheet S is conveyed again in the X-axis direction by the intermittent conveyance distance. These series of operations are repeatedly executed.

  In order to keep the sheet S stopped on the upper surface of the platen 30 flat during intermittent conveyance, the platen 30 includes a mechanism for sucking the stopped sheet S on the upper surface thereof. Specifically, a large number of suction holes (not shown) are opened on the upper surface of the platen 30, and a suction portion 37 is attached to the lower surface of the platen 30. When the suction unit 37 operates, a negative pressure is generated in the suction hole on the upper surface of the platen 30, and the sheet S is sucked on the upper surface of the platen 30. The suction unit 37 sucks the sheet S while the sheet S is stopped on the platen 30 for printing, thereby keeping the sheet S flat. And the sheet S can be smoothly conveyed.

  Further, a heater 38 is attached to the lower surface of the platen 30. The heater 38 heats the platen 30 to a predetermined temperature (for example, 45 degrees). Accordingly, the sheet S is primarily dried by the heat of the platen 30 in parallel with receiving the printing process from the recording head 34. And the drying of the ink which landed on the sheet | seat S is accelerated | stimulated by this primary drying.

  In this way, on the upper surface of the platen 30, the sheet S that has received one frame of printing and is primarily dried moves along with the intermittent conveyance of the sheet S and reaches the drying unit 4. The drying unit 4 executes a drying process in which the ink landed on the sheet S is completely dried by air heated for drying. Then, the sheet S that has been subjected to the drying process reaches the winding unit 5 as the sheet S is intermittently conveyed, and is wound as a roll R2.

  As described above, the printing / drying process is performed on the sheet S by the recording unit 31 and the drying unit 4. In addition to the recording unit 31 and the drying unit 4 described above, the printer 300 includes functional units such as a corona processor 8 and a maintenance unit 9. Next, details of these configurations and operations will be described.

  The corona treatment machine 8 is disposed upstream of the platen 30 in the conveyance direction of the sheet S, and modifies the surface of the sheet S before entering the platen 30. Specifically, the corona treatment machine 8 includes a ground electrode roller 81 that winds the sheet S on the upstream side in the conveyance direction of the sheet S with respect to the roller 72, and a corona that faces the ground electrode roller 81 with the sheet S interposed therebetween. A discharge electrode 82 and an electrode cover 83 covering the corona discharge electrode 82 are provided. The corona discharge electrode 82 receives a discharge bias from the discharge bias generator 84 (FIG. 5) and causes corona discharge. By this corona discharge, the surface of the sheet S is modified, and the wettability of the sheet S with respect to ink is improved. In this way, by performing surface modification on the sheet S prior to the printing process, it is possible to improve the fixability of the ink on the sheet S in the printing process.

  The maintenance unit 9 is provided at a position deviating from the platen 30 in the negative X-axis direction, and performs maintenance on the recording head 34 that retreats to the home position (position directly above the maintenance unit) during non-printing. The maintenance unit 9 has a configuration similar to that of Japanese Patent Application Laid-Open No. 2010-142981. Specifically, the maintenance unit 9 has a configuration as shown in FIGS.

  FIG. 3 is a partial cross-sectional view schematically showing the configuration of the maintenance unit. FIG. 4 is a partial plan view schematically showing the configuration of the maintenance unit. In FIG. 3, the recording head 34 and the like are shown together with the maintenance unit 9 in order to show the relationship between the maintenance unit 9 and the recording head 34.

  The maintenance unit 9 includes a schematic configuration in which a movable plate 93 that supports a maintenance member 91 and a cam 95 that moves the movable plate 93 up and down are held in a maintenance cap 90. The maintenance cap 90 opens upward, and a moisturizing liquid is supplied to the bottom of the maintenance cap 90. In addition, the maintenance cap 90 is moved up and down by the operation of the lifting unit 97 provided in the lower portion thereof, so that the maintenance position closes to the recording head 34 at the home position and the retreat position away from the recording head 34. It is possible to move between. FIG. 3 shows a state where the maintenance cap 90 is in the maintenance position.

  As shown in FIG. 4, in the maintenance unit 9, 15 maintenance members 91 are arranged in a staggered manner in the Y-axis direction. Thus, the 15 maintenance members 91 are arranged in a one-to-one correspondence with the 15 recording heads 34. Each maintenance member 91 includes a cap 91a and a wiper 91b in order to perform maintenance on the corresponding recording head 34. Each maintenance member 91 rises integrally with the movable plate 93 from the position of FIG. 3 as the cam 95 rotates, and performs predetermined maintenance (cleaning, wiping) with the cap 91a and the wiper 91b.

  Specifically, the cap 91 a is used for cleaning the nozzle 35 of the recording head 34. In this cleaning, the cap 91a is lifted from the position shown in FIG. 3 and the recording head 34 is covered with the cap 91a, thereby generating a negative pressure inside the cap 91a and forcibly discharging the ink from the nozzle 35. It is. By this cleaning, ink with increased viscosity, bubbles in the ink, and the like can be removed from the nozzle 35.

  The wiper 91b is used for wiping to wipe the surface (nozzle opening forming surface) where the openings of the nozzles 35 are arranged in the recording head 34. In this wiping, the wiper 91b is lifted from the position shown in FIG. 3 and the carriage 32 is reciprocated in the X direction with the wiper 91b in contact with the nozzle opening forming surface. It is in sliding contact. By this wiping, dirt can be wiped from the opening of the nozzle 35 of the recording head 34. Note that the wiping is performed while causing the ink to flow out from the nozzles 35 in order to reduce the friction between the wiper 91b and the nozzle opening forming surface and smoothly perform wiping.

  By the way, as described above, in this embodiment, four head units 34u configured by collecting three to four recording heads 34 are arranged in the Y-axis direction. In this embodiment, maintenance is selectively performed for each head unit 34u.

  Specifically, 15 maintenance members 91 are allocated to four maintenance member groups 91G corresponding one-to-one to the four head units 34u. As a result, four maintenance member groups 91G including three to four maintenance members 91 are arranged in the Y-axis direction. Specifically, four movable plates are provided side by side in the Y-axis direction, and three to four maintenance members 91 constituting the maintenance member group 91G are arranged on each movable plate 93.

  A cam 95 is provided below each of the four movable plates 93. Thus, the four cams 95 corresponding to the four movable plates 93 on a one-to-one basis are arranged side by side in the Y-axis direction. Each of the four cams 95 is attached to a common cam rotation shaft 95A while being inclined at a predetermined angle (for example, 45 degrees). Therefore, one of the four movable plates 93 can be selectively raised by adjusting the rotation angle of the cam rotation shaft 95A. The maintenance of the head unit 34u can be performed by the maintenance member group 91G provided on the raised movable plate 93. In this way, it is possible to selectively perform maintenance for each head unit 34u.

  The above is the outline of the apparatus configuration included in the printing system 100. Next, FIG. 5 is added to FIG. 1 described above, and the electrical configuration of the printing system of FIG. 1 will be described in detail. Here, FIG. 5 is a block diagram schematically showing the electrical configuration of the printing system of FIG.

  As described above, the printing system 100 includes the printer 300 and the host device 200 that controls the printer 300. The host device 200 is configured by, for example, a personal computer, and includes a printer driver 210 that controls the operation of the printer 300 and a transfer control unit 220 that manages a communication function with the printer 300. The printer driver 210 is constructed by a CPU (Central Processing Unit) included in the host device 200 executing a program for the printer driver 210.

  In addition, the host device 200 includes a media drive unit 240 that accesses a medium 230 that stores a printer driver program and reads the program. As this medium 230, various media such as a CD (Compact Disc), a DVD (Digital Versatile Disc), a USB (Universal Serial Bus) memory, and the like can be used.

  Furthermore, the host device 200 includes a monitor 250 configured with a liquid crystal display or the like and an operation unit 260 configured with a keyboard, a mouse, or the like as an interface with the worker. Note that a touch panel display may be used as the monitor 250, and the operation unit 260 may be configured by the touch panel of the monitor 250. In addition to the image to be printed, a menu screen is displayed on the monitor 250. Therefore, the operator operates the operation unit 260 while confirming the monitor 250 to open the print setting screen from the menu screen, and various types such as the type of the print medium, the size of the print medium, the print quality, and the plate number are displayed. Printing conditions can be set.

  The type of print medium (that is, sheet S) is broadly classified into paper and film. Specific examples include high-quality paper, cast paper, art paper, coated paper, and the like for paper, and synthetic paper, PET (Polyethylene terephthalate), PP (polypropylene), and the like for film. As the size of the print medium, the width of the sheet S (width in the Y-axis direction) is set. The print quality can be set by selecting one print mode from the plurality of print modes (4, 6, 8, and 16 passes) described above. The number of plates is set when a plurality of plates (images) are printed in the same area of the print medium. Specifically, the number of plates to be printed is set. Incidentally, when a plurality of versions are set, an image for each version can be displayed on the monitor 250.

  The printer driver 210 includes a host control unit 211 that controls display on the monitor 250 and input processing from the operation unit 260 as described above. That is, the host control unit 211 displays various screens such as a menu screen and a print setting screen on the monitor 250 and performs processing according to the contents input from the operation unit 260 on the various screens. Accordingly, the host control unit 211 generates a control signal necessary for controlling the printer 300 in accordance with an input from the worker.

  Further, the printer driver 210 includes an image processing unit 213 that performs image processing on image data received from an external device and generates print data. Specifically, image processing such as resolution conversion processing, color conversion processing, and halftone processing is executed.

  The control signal generated by the host control unit 211 and the print data generated by the image processing unit 213 are transferred to the printer control unit 400 provided in the main body case 1 of the printer 300 via the transfer control unit 220. Is done. The transfer control unit 220 can perform bi-directional serial communication with the printer control unit 400. The transfer control unit 220 transfers control signals and print data to the printer control unit 400, and sends response signals to the printer control unit 400. Are transmitted to the host control unit 211.

  The printer control unit 400 includes a head controller 410, a mechanical controller 420, and a memory 430. The memory 430 functions to store various information such as the program 440 read from the medium 230. Therefore, the head controller 410 and the mechanical controller 420 can read out necessary information from the memory 430 and perform various controls. Details of these controllers 410 and 420 are as follows.

  The head controller 410 controls the recording head 34 based on the print data transmitted from the printer driver 210. Specifically, the head controller 410 controls ink ejection from the nozzles 35 of the recording head 34 based on print data. At this time, the timing of ejecting ink from the nozzles 35 is controlled based on the movement of the carriage 32 in the X-axis direction. That is, a linear encoder E32 that detects the position of the carriage 32 in the X-axis direction is provided in the printing chamber 3. Then, the head controller 410 refers to the output of the linear encoder E32 to eject ink from the nozzles 35 at a timing according to the movement of the carriage 32 in the X-axis direction.

  On the other hand, the mechanical controller 420 mainly controls a function of controlling the intermittent conveyance of the sheet S and the driving of the carriage 32. Specifically, the mechanical controller 420 outputs the conveyance motor Ms that drives the sheet conveyance system including the feeding unit 2, the rollers 71 to 77, and the winding unit 5 to the output of the encoder Emc that detects the rotation of the conveyance motor Ms. Based on the control, the sheet S is intermittently conveyed. The mechanical controller 420 controls the first CR motor Mx to cause the carriage 32 to move in the X-axis direction for main scanning, and controls the second CR motor Mx to perform sub-scanning. Is moved in the Y-axis direction by the carriage 32.

  The head controller 410 and the mechanical controller 420 synchronize with each other and appropriately execute these controls to execute a pass corresponding to the set print mode for the intermittently conveyed sheet S. Printing for one frame is executed. As a result, an image for one frame is printed on the sheet S.

  The mechanical controller 420 can execute various controls in addition to the above-described control for the printing process. Specifically, the mechanical controller 420 detects the on / off state of the power switch SW, and executes the activation process of each unit of the printer 300 when the power switch SW is turned on. Further, the mechanical controller 420 feedback-controls the heater 38 based on the output of the temperature sensor S30 that detects the temperature of the upper surface of the platen 30, and based on the output of the temperature sensor S4 that detects the temperature inside the drying unit 4. Then, temperature control such as feedback control of the drying unit 4 is executed. Further, the mechanical controller 420 controls the suction part 37 to adjust the negative pressure generated in the suction hole of the platen 30, or to adjust each part of the maintenance unit 9 (the lifting part 97, the cam rotation shaft 95 </ b> A, the negative pressure in the cap 91. It is possible to execute predetermined operations by controlling the generating mechanism and the like, or by adjusting the discharge bias value by controlling the discharge bias generator 84.

  The above is the outline of the electrical configuration of the printing system of FIG. Next, details of each printing mode (4, 6, 8, and 16 passes) executed in this embodiment will be described. These four types of passes are common in that printing is performed for one frame by forming a plurality of line images arranged in the Y-axis direction by alternately executing main scanning and sub-scanning. It is roughly divided into two points. That is, the 4-pass and 6-pass print modes are print modes (first print mode) in which line images adjacent in the Y-axis direction are continuously formed by the same nozzle 35. On the other hand, the 8- and 16-pass printing modes are printing modes (second printing mode) in which line images adjacent in the Y-axis direction are continuously formed by different nozzles 35.

  FIG. 6 is a schematic diagram showing the operation in the 4-pass and 6-pass print modes executed in the first print mode. In the drawing, the symbol Er indicates the upstream edge in the positive Y-axis direction of the printing region IR of the sheet S, and the lower side of the drawing is the printing region IR from the broken line with the symbol Er. Further, in the drawing, a plurality of nozzles 35 constituting one nozzle row 35L are shown in the parenthesized number “n” in order from the Y axis positive direction. In each of the left and right columns (“first pass” and “second pass”) in the same figure, the position of the nozzle 35 at the time of starting the indicated pass is described, and the pass in which each nozzle 35 is indicated from this position. Is started to form line images LI (1) and LI (2) shown by one-dot and two-dot chain lines. For convenience of illustration, only one row of nozzles 35 is shown in FIG. Each line image LI (1), LI (2) is assigned the number (“n” or the like) of the nozzle 35 that forms the line image.

  As shown in the “first pass” column of FIG. 6, at the start of the “first pass”, the carriage 32 is positioned at the upstream end of the print region IR in the positive X-axis direction. At the same time, among all the nozzles 35 provided on the carriage 32, the nozzle 35 located on the most downstream side in the Y-axis positive direction is positioned with respect to the downstream edge in the Y-axis positive direction of the print region IR. The range where the nozzles 35 are provided in the carriage 32 is wider than the range of the print region IR of the sheet S in the Y-axis direction. Therefore, in the example shown in the column “first pass” in FIG. 6, the nozzle 35 (n−1) and the like (nozzle in the region RP) located upstream in the Y axis positive direction from the nozzle 35 (n) Projecting upstream of IR in the positive direction of the Y axis. On the other hand, the nozzle 35 (n) and the nozzles 35 (n + 1), 35 (n + 2),... On the downstream side in the positive Y-axis direction face the print region IR. Then, the “first pass” is started from this state. Specifically, the nozzles 35 (n), 35 (n + 1),... Move along the X axis positive direction along with the carriage 32 to eject ink (main scanning), and the first pass line image LI. (1) is formed.

  In the sub-scan following this main scan, the nozzles 35 (n), 35 (n + 1),... Are distanced according to the resolution along with the carriage 32, as shown in the “second pass” column of FIG. Move in the positive direction of the Y axis by Pi. The distance Pi according to the resolution is a pitch between line images formed adjacent to each other in the Y-axis direction. In the second pass, the nozzles 35 (n), 35 (n + 1),... Move along the carriage 32 in the negative direction of the X axis to eject ink (main scanning). A line image LI (2) is formed. Thus, each of the nozzles 35 (n), 35 (n + 1),... Continuously forms line images LI (1), LI (2) adjacent in the Y-axis direction in this order. Then, the same operation is repeated, and printing for one frame constituted by four passes or six passes is completed. As described above, in the 4-pass or 6-pass print mode, line images adjacent in the Y-axis direction are continuously formed by the same nozzle 35.

  FIG. 7 is a schematic diagram illustrating an operation in an 8-pass print mode executed in the second print mode. The notation in the figure is the same as in FIG. As shown in the column “First Pass” in FIG. 7, even in the 8-pass print mode, at the start of “First Pass”, the carriage 32 is positioned at the upstream end of the print region IR in the positive X-axis direction. To position. At the same time, among the nozzles 35 provided on the carriage 32, the nozzle 35 located on the most downstream side in the positive Y-axis direction is positioned with respect to the downstream edge in the positive Y-axis direction of the print region IR. As a result, in the example shown in the “first pass” column of FIG. 7, the nozzles 35 (n−1) and the like (nozzles in the region RP) located upstream in the Y axis positive direction from the nozzles 35 (n) are printed. It protrudes upstream of the region IR in the positive Y-axis direction. On the other hand, the nozzle 35 (n) and the nozzles 35 (n + 1), 35 (n + 2),... On the downstream side in the positive Y-axis direction face the print region IR. Then, the “first pass” is started from this state. Specifically, the nozzles 35 (n), 35 (n + 1),... Move along the X axis positive direction along with the carriage 32 to eject ink (main scanning), and the first pass line image LI. (1) is formed.

  In the sub-scan following this main scan, the nozzles 35 (n), 35 (n + 1),... Move in the Y-axis direction along with the carriage 32. However, in the 8-pass print mode, the movement amount of the nozzles 35 (n), 35 (n + 1),... Is different from the 4-pass and 6-pass print modes. In other words, as shown in the “second pass” column of FIG. 7, the amount of movement is a distance ΔP32 (= P35 + Pi) obtained by adding the arrangement pitch P35 of the nozzles 35 to the distance Pi according to the resolution. Then, the second pass is executed following this sub-scan, and the nozzles 35 (n), 35 (n + 1),... scanning). Thus, the second pass line image LI (2) is formed.

  Thus, in the 8-pass printing mode, the movement distance ΔP32 of the carriage 32 in the sub-scan is obtained by adding the arrangement pitch P35 of the nozzles 35 to the distance Pi corresponding to the resolution. As a result, when attention is paid to two line images LI (1) and LI (2) that are successively formed in a state adjacent to each other, the nozzle 35 that forms the line image LI (1) of the first pass is used. The second pass line image LI (2) is formed by the upstream nozzle 35 in the positive Y-axis direction. For example, the (n-1) th nozzle 35 (n-1) is adjacent to the line image LI (1) formed by the nth nozzle 35 (n) in the first pass. A line image LI (2) is formed. Then, the same operation is repeated, and printing for one frame composed of eight passes is completed.

  Here, paying attention to the vicinity of the upstream edge Er in the positive Y-axis direction of the print region IR, at the start of the first pass, the nozzles 35 (n-1) that protrude from the print region IR and have not been used for printing are 2 After the pass, the printing area IR is subjected to printing (ink is ejected). Further, the nozzles 35 (n-2), 35 (n-3),... That protrude from the print region IR and have not been used for printing are sequentially opposed to the print region IR and used for printing each time sub-scanning is performed. become. Thus, at the start of the first pass, the nozzles 35 (n-1), 35 (n-2),... That protrude from the printing region IR and have not been used for printing eject liquid after the second pass. The 8-pass print mode is also different from the 4-pass and 6-pass print modes in that it is used for printing.

  Incidentally, as described above, in the 8-pass printing mode, line images adjacent in the Y-axis direction are formed continuously by different nozzles 35. As a result, in the 8-pass printing mode, for example, even when the direction of ejecting the liquid varies between the nozzles 35, the same nozzle 35 does not form a line image adjacently. It is possible to suppress the influence of variations in the liquid ejection direction between the nozzles 35 on the image.

  FIG. 8 and FIG. 9 are schematic diagrams showing the operation in the 16-pass print mode executed in the second print mode. The notation in FIG. 8 is the same as that in FIG. In the 16-pass printing mode, similarly to the 8-pass printing mode, line images adjacent in the Y-axis direction are continuously formed by different nozzles 35. However, in the 16-pass printing mode, one line image is formed by two main scans, and a plurality of line images are obtained by repeatedly executing the two main scans alternately with one sub-scan. Are arranged side by side in the Y-axis direction, and this is different from the 8-pass printing mode. The 16-pass print mode will be described in detail below.

  As shown in the “first pass + second pass” column of FIG. 8, even in the 16-pass print mode, the carriage 32 moves upstream of the print region IR in the positive X-axis direction at the start of the “first pass”. Located at the end. At the same time, among the nozzles 35 provided on the carriage 32, the nozzle 35 located on the most downstream side in the positive Y-axis direction is positioned with respect to the downstream edge in the positive Y-axis direction of the print region IR. As a result, in the example shown in the column “first pass + second pass” in FIG. 8, the nozzle 35 (n−1) and the like on the upstream side in the positive Y-axis direction from the nozzle 35 (n) (nozzle in the region RP) However, it protrudes upstream of the print region IR in the positive direction of the Y-axis. On the other hand, the nozzle 35 (n) and the nozzles 35 (n + 1), 35 (n + 2),... On the downstream side in the positive Y-axis direction face the print region IR.

  From this state, the “first pass” and the “second pass” are continuously executed without interposing the sub-scan (the column “first pass + second pass” in FIG. 8). Specifically, in the first pass, the nozzles 35 (n), 35 (n + 1),... Are ejected while moving in the positive direction of the X-axis along the carriage 32 (main scanning). However, in the first pass, a plurality of dots dt (1) are formed every other dot (the column of “first pass” in FIG. 9). Then, in the second pass, the nozzles 35 (n), 35 (n + 1),... Move along the carriage 32 in the negative direction of the X axis to eject ink (main scanning), and in the first pass. A dot dt (2) is formed between each of the formed dots dt (1) (column “second pass” in FIG. 9). In this way, the line image LI (1) composed of the dots dt (1) and dt (2) is formed by two main scans (the column “first pass + second pass” in FIG. 8).

  When the line image LI (1) is formed, sub-scanning is performed, and the nozzles 35 (n), 35 (n + 1),... Move in the Y-axis direction along with the carriage 32. The amount of movement at this time is the same as that in the 8-pass print mode. Subsequent to this sub-scan, the third and fourth passes are executed in the same manner as the first and second passes (in the columns “3rd pass” and “4th pass” in FIG. 9), and the line image LI ( 2) is formed (in the column “third pass + fourth pass” in FIG. 8). Thus, also in the 16-pass print mode, line images LI (1) and LI (2) adjacent in the Y-axis direction are continuously formed by different nozzles 35, as in the 8-pass print mode. Then, the same operation is repeated, and printing for one frame composed of 16 passes is completed.

  Here, when attention is paid to the vicinity of the upstream edge Er in the Y-axis positive direction of the print region IR, the nozzle 35 (n-1) that protrudes from the print region IR and has not been used for printing, as in the 8-pass print mode. 35 (n-2),... Are sequentially supplied to the printing area IR each time the sub-scan is executed. Thus, even in the 16-pass print mode, at the start of the first pass, the nozzles 35 (n-1), 35 (n-2),... This is different from the 4-pass and 6-pass printing modes in that liquid is subsequently ejected and used for printing.

  Incidentally, even in the 16-pass printing mode, the line images adjacent in the Y-axis direction are continuously formed by different nozzles 35, and thus the liquid ejection direction variation between the nozzles 35 is the same as in the 8-pass printing mode. The influence on the image can be suppressed. In the 16-pass printing mode, adjacent dots are formed at intervals. Accordingly, it is possible to form a dot adjacent to this dot in a state where the ink constituting the previously formed dot is sufficiently absorbed by the sheet S. As a result, it is possible to record an image with higher image quality.

  Thus, the printer 300 can execute the first print mode (4 passes, 6 passes) and the second print mode (8 passes, 16 passes). As can be seen from the above description, in the first printing mode and the second printing mode, the combination of nozzles 35 that eject ink is different from each other when printing for one frame is performed. Accordingly, the head controller 410 (FIG. 5) selects the nozzles 35 that eject ink in printing based on the printing mode in order to control the recording head 34 in accordance with the printing mode.

  At this time, since it is necessary to execute printing within a range corresponding to the width of the sheet S in the Y-axis direction, the head controller 410 selects the nozzle 35 for ejecting ink in printing in consideration of the width of the sheet S. To do. That is, the head controller 410 confirms the print mode selected and set by the operator and the width of the sheet S, and selects the nozzle 35 that ejects ink in printing according to these. This operation will be described with a specific example as follows.

  FIG. 10 is an explanatory diagram of the nozzle selection operation in the first print mode. FIG. 11 is an explanatory diagram of the nozzle selection operation in the second print mode. In these drawings, the case where a nozzle is selected for a narrow sheet S having a narrow width and the case where a nozzle is selected for a wide sheet S having a wide width are shown in the columns in the drawings. Each column shows the positional relationship between each recording head 34 and the sheet S when the first pass is started. Actually, these are indicated by broken lines in consideration of the fact that each recording head 34 is hidden behind the carriage 32 in a plan view. For the convenience of illustration, reference numeral 34 is given only to a part of the recording heads.

  When the print mode is the first print mode, the nozzle 35 that faces the print region IR of the sheet S at the start of the first pass is selected as the nozzle 35 that ejects ink in printing. As can be seen from the comparison of the columns “Narrow Sheet” and “Wide Sheet” in FIG. 10, the selected nozzle 35 differs depending on the difference in the width of the sheet S. Then, the selected nozzle 35 ejects ink onto the printing area IR of the sheet S, and printing is executed on the printing area IR of the sheet S.

  On the other hand, as described above, in the second printing mode, the nozzle 35 that protrudes from the printing region IR at the start of the first pass and has not been used for printing, ejects liquid after the second pass to be used for printing. . Therefore, when the print mode is the second print mode, not only the nozzles 35 that face the print region IR at the start of the first pass, but also some of the nozzles 35 that are located in the region RP that protrudes from the print region IR ( The nozzle 35) in the region α is also selected as the nozzle 35 that ejects ink by printing. As can be seen from the comparison between the “narrow sheet” and “wide sheet” columns in FIG. 11, the selected nozzles 35 differ depending on the width of the sheet S also in the second print mode. Then, the selected nozzle 35 ejects ink onto the printing area IR of the sheet S, and printing is executed on the printing area IR of the sheet S.

  Thus, the nozzles 35 that eject ink for printing differ depending on the printing mode and the width of the sheet S. Therefore, in the maintenance process before printing, it is sufficient to perform maintenance on the nozzles 35 that actually eject ink in the subsequent printing. Therefore, in this embodiment, maintenance is efficiently performed as follows.

  FIG. 12 is a flowchart showing an example of the embodiment of the present invention. The operation of the flowchart of FIG. 12 is executed by the head controller 410 and the mechanical controller 420 in cooperation with each other according to the program 440 stored in the memory 430.

  When the operator commands the printer 300 to start printing via the operation unit 260, the flow of FIG. 12 starts. Specifically, the head controller 410 (FIG. 5) confirms the print mode and the width of the sheet S set by the operator (step S100), and based on the confirmation results, the ink is printed in the subsequent printing. Is selected (step S200). These operations by the head controller 410 are as described above.

  In the following step S300, the count values C1 and C2 of the counter are reset to “0” (step S100). Here, the count value C1 counts the number of times printing for one frame has been executed. The count value C2 counts the number of times printing for one frame has been performed after the latest maintenance process.

  If it is determined in step 400 that the count value C2 is not equal to the predetermined count value Ct2 (in the case of “NO” in step S400), the process proceeds to step S700. In step S700, the nozzle 35 selected in step S200 ejects ink, and printing for one frame is executed. On the other hand, when it is determined in step 400 that the count value C2 is equal to the predetermined count value Ct2 (in the case of “YES” in step S400), the maintenance process S500 is executed. That is, in this flow, by performing the determination in step S400, the maintenance process is executed every time a certain number of frames are printed.

  FIG. 13 is a flowchart showing a flow of maintenance processing. In step S501, the mechanical controller 420 (FIG. 5) confirms the print mode and the width of the sheet S. In subsequent step S502, mechanical controller 420 identifies a nozzle that ejects ink in the subsequent printing based on the confirmation result in step S501. Then, the mechanical controller 420 selectively performs maintenance (cleaning and wiping) on the head unit 34u having the nozzle 35 identified in step S502 by controlling the maintenance unit 9 and the like (step S503). .

  The operations in steps S501 to S503 will be specifically described with reference to the examples of FIGS. 10 and 11 described above. When the print mode is the first print mode as shown in FIG. 10, the nozzle 35 facing the print region IR is identified as the nozzle 35 that ejects ink in the subsequent printing. Therefore, when the sheet S is a narrow sheet S, the nozzles 35 of the two head units 34u on the downstream side in the positive Y-axis direction face the print region IR, and therefore only for these two head units 34u. Maintenance is performed, and no maintenance is performed on the other head units 34u. On the other hand, when the sheet S is a wide sheet S, the nozzles 35 of the three head units 34u on the downstream side in the positive direction of the Y axis face the printing region IR, so only the three head units 34u are maintained. Is performed, and no maintenance is performed on the other head unit 34u. The mechanism for performing selective maintenance for each head unit 34u is as described above with reference to FIGS.

  When the print mode is the second print mode as shown in FIG. 11, the nozzle 35 facing the print region IR and the region α is identified as the nozzle 35 that ejects ink in the subsequent printing. Therefore, when the sheet S is a narrow sheet S, the nozzles 35 of the three head units 34u on the downstream side in the Y-axis positive direction are opposed to the printing region IR and the region α. Maintenance is executed only for the head unit 34u, and no maintenance is executed for the other head units 34u. On the other hand, when the sheet S is a wide sheet S, the nozzles 35 of the four head units 34u are opposed to the printing area IR and the area α, so that maintenance is performed on all the four head units 34u. The above is the content of the maintenance process executed in step S500 of FIG.

  When the maintenance process is completed, the process proceeds to step S600, and the count value C2 is reset to “0”. In subsequent S700, printing for one frame is executed by the nozzle 35 selected in step S200.

  As described above, based on the determination result of step S400, after necessary maintenance processing is executed as appropriate, printing for one frame is executed (step S700). When the printing for one frame is completed, the count values C1 and C2 are incremented by “1” (step S800). In the subsequent step S900, it is determined whether printing of the necessary number of frames is completed by determining whether the count value C1 is equal to the predetermined count value Ct1. If the count value C1 is less than the predetermined count value Ct1 and the necessary number of frames have not been printed (“NO” in step S900), the process returns to step S400. On the other hand, if the count value C1 is equal to the predetermined count value Ct1 and printing of the required number of frames is completed (in the case of “YES” in step S900), the flow of FIG.

  As described above, in this embodiment, an image is recorded on the sheet S having a width in the Y-axis direction using the plurality of nozzles 35 arranged in the Y-axis direction and held by the carriage 32. Specifically, main scanning is performed by ejecting ink from the nozzles 35 while moving the carriage 32 in the X-axis direction, and an image is recorded on the sheet S (step S700, image recording processing). Incidentally, this image recording process can be executed in the first printing mode and the second printing mode in which the combinations of the nozzles 35 that eject ink are different from each other. Therefore, in the image recording process, the nozzle 35 is selected according to the print mode selected to execute the image recording process (steps S100 and S200), and the selected nozzle ejects ink to perform the image recording process. (Step S700). Furthermore, in order to deal with not only the print mode but also the width of the sheet S, the selection of the nozzles that eject ink in the image recording process is executed according to the width of the sheet S (steps S100 and S200).

  Thus, in this embodiment, the nozzle 35 that ejects ink in the image recording process is selected according to the print mode and the width of the sheet S. Accordingly, the nozzles 35 that actually eject ink in the image recording process differ depending on the print mode and the width of the sheet S. On the other hand, it is sufficient to perform maintenance before the start of the image recording process on the nozzles 35 that eject ink in the image recording process. Therefore, this embodiment includes a configuration in which maintenance is not performed for the nozzles 35 that do not eject ink in the image recording process (step S503). Accordingly, it is possible to suppress maintenance of the nozzle 35 that does not eject ink in the image recording process, and to suppress ink consumption due to maintenance.

Others As described above, in the above embodiment, the printer 300 corresponds to the “image recording apparatus” of the invention, the sheet S corresponds to the “recording medium” of the invention, and the ink corresponds to the “liquid” of the invention. The platen 30 corresponds to the “support member” of the present invention, the carriage 32 and the recording head 34 held by the carriage 32 correspond to the “recording unit” of the present invention, and the head controller 410 and the mechanical controller 420 cooperate. The mechanical controller 420 and the maintenance unit 9 cooperate to function as the “maintenance unit” of the present invention. The first printing mode (4 pass, 6 pass) corresponds to the “first recording mode” of the present invention, and the second printing mode (8 pass, 16 pass) corresponds to the “second recording mode” of the present invention. doing. Further, printing for one frame corresponds to the “image recording process” of the present invention, the X-axis direction corresponds to the “main scanning direction” of the present invention, and the Y-axis direction corresponds to the “sub-scanning direction direction” of the present invention. The Y-axis positive direction corresponds to “one direction of the sub-scanning direction” of the present invention. The head controller 410 and the mechanical controller 420 cooperate to function as a “computer” of the present invention, the program 440 corresponds to the “program” of the present invention, and the medium 230 serves as the “program recording medium” of the present invention. Equivalent to.

  The present invention is not limited to the above-described embodiment, and various modifications can be made to the above-described one without departing from the spirit of the present invention. For example, in the above-described embodiment, the ink jet printer 300 is employed as the image recording apparatus, but a fluid ejecting apparatus that ejects or ejects fluid other than ink may be employed. In addition, the present invention can be applied to various liquid ejecting apparatuses including a liquid ejecting head that ejects a minute amount of liquid droplets. In this case, the droplet refers to a state of the liquid ejected from the liquid ejecting apparatus, and includes a liquid that is tailed in a granular shape, a tear shape, or a thread shape. The liquid mentioned here may be any material that can be ejected by the liquid ejecting apparatus. For example, liquid phase substances are contained in the liquid, such as high or low viscosity liquid state, sol, gel water, other inorganic solvents, organic solvents, solutions, liquid resins, and liquid metals (metal melts). Liquid is contained in the liquid. In addition, liquids include those in which particles of a functional material made of a solid such as pigments and metal particles are dissolved, dispersed, or mixed in a solvent. Further, typical examples of the liquid include ink and liquid crystal as described in the above embodiment. Here, the ink includes various liquid compositions such as general water-based ink, oil-based ink, gel ink, and hot-melt ink.

  Moreover, in the said embodiment, it is comprised so that the maintenance of the nozzle 35 may be performed for every head unit 34u. However, the unit for executing the maintenance is not limited to the head unit 34u. Accordingly, the maintenance of the nozzles 35 may be executed for each recording head 34. This will be specifically described with reference to FIGS. 10 and 11 described above.

  When the print mode is the first print mode as shown in FIG. 10, the nozzle 35 facing the print region IR is identified as the nozzle 35 that ejects ink in the subsequent printing. Therefore, when the sheet S is a narrow sheet S, the nozzles 35 of the seven recording heads 34 on the downstream side in the Y-axis positive direction are opposed to the printing region IR, and therefore only for these seven recording heads 34. Maintenance is performed, and maintenance is not performed on the other recording heads 34. On the other hand, when the sheet S is a wide sheet S, the nozzles 35 of the eleven recording heads 34 on the downstream side in the positive direction of the Y axis face the print region IR. Only the maintenance is performed, and the maintenance is not performed on the other recording heads 34.

  When the print mode is the second print mode as shown in FIG. 11, the nozzle 35 facing the print region IR and the region α is identified as the nozzle 35 that ejects ink in the subsequent printing. Therefore, when the sheet S is a narrow sheet S, the nozzles 35 of the nine recording heads 34 on the downstream side in the Y-axis positive direction are opposed to the printing area IR and the area α. Maintenance is performed only on the recording head 34, and no maintenance is performed on the other recording heads 34. On the other hand, when the sheet S is a wide sheet S, since the nozzles 35 of the 13 recording heads 34 are opposed to the printing area IR and the area α, maintenance is performed only for the 13 recording heads 34. Maintenance is not performed on the other recording heads 34.

  As described above, even in the configuration in which the maintenance is selectively performed in units of the recording head 34, the nozzle 35 that does not eject ink in the image recording process is performed by performing no maintenance on the nozzle 35 that does not eject ink in the image recording process. It is possible to suppress the consumption of ink due to the maintenance in advance of maintenance.

  In the above-described embodiment, in the 8-pass and 16-pass print modes, the movement amount ΔP32 of the nozzles 35 in the sub-scan is a distance obtained by adding the arrangement pitch P35 of the nozzles 35 to the distance Pi according to the resolution. However, the movement amount ΔP32 may be a distance obtained by multiplying the arrangement pitch P35 of the nozzles 35 by an arbitrary integer and adding the distance Pi (ΔP32 = P35 × k + Pi, k is a positive integer). Even in such a configuration, it is possible to suppress the influence of variations in the liquid ejection direction between the nozzles 35 on the image.

  In the above embodiment, printing for one frame is configured by 4, 6, 8, and 16 passes. However, the number of passes constituting printing for one frame is not limited to this, and can be changed as appropriate.

  In the above-described embodiment, 4 and 6 passes are executed in the first print mode, and 8 and 16 passes are executed in the second print mode. It is possible to appropriately change whether or not to execute the operation. Therefore, 6 passes may be executed in the second print mode, or 8 passes may be executed in the first print mode.

  In the above embodiment, selective maintenance such as performing maintenance on a recording head selected from among the plurality of recording heads 34 using the configuration shown in FIGS. 3 and 4 can be performed. . However, the configuration for realizing this selective maintenance is not limited to that shown in FIGS. 3 and 4 and can be changed as appropriate.

  In the above-described embodiment, maintenance is performed every time a predetermined number of frames are printed. However, the maintenance timing is not limited to this.

  Various modifications can be made to the number and arrangement of the recording heads 34 mounted on the carriage 32.

  Further, in the above-described embodiment, the case where the present invention is applied to an inkjet printer using a piezo method has been described. However, it goes without saying that the present invention can also be applied to an ink jet printer using a thermal method.

  DESCRIPTION OF SYMBOLS 100 ... Printing system 200 ... Host apparatus 300 ... Printer 400 ... Printer control part 410 ... Head controller 420 ... Mechanical controller 30 ... Platen 31 ... Recording unit 32 ... Carriage 33 ... Support plate 34 ... Recording head, 35 ... Nozzle, 35L ... Nozzle row, 9 ... Maintenance unit, 91a ... Cap, 91b ... Wiper, IR ... Printing area, LI (1), LI (2) ... Line image, S ... Sheet, X ... Main Scanning direction, Y ... sub-scanning direction

Claims (7)

A support member for supporting a recording medium having a width in the sub-scanning direction;
A recording unit having a plurality of nozzles arranged in the sub-scanning direction;
A combination of the nozzles for ejecting liquid for image recording processing for recording an image on the recording medium that performs main scanning for ejecting liquid from the nozzles while moving the recording unit in the main scanning direction and stops on the support member A control unit that can be executed in a plurality of different recording modes,
A maintenance unit that performs maintenance of the nozzle while discharging liquid from the nozzle before the image recording process is started;
The control unit includes the plurality of nozzles that eject liquid in the image recording process according to the recording mode selected to execute the image recording process from the plurality of recording modes and the width of the recording medium. And performing the image recording process with the selected nozzle,
The image recording apparatus according to claim 1, wherein the maintenance unit does not perform the maintenance on the nozzles that do not eject liquid in the image recording process. The control unit performs the main scanning a plurality of times alternately with sub-scanning for moving the recording head in the sub-scanning direction, and generates a line image for one line formed by the nozzle in the main scanning direction. The image recording apparatus according to claim 1, wherein the image recording apparatus is formed side by side in the sub-scanning direction.
The plurality of recording modes are different from the first recording mode in which two line images adjacent in the sub-scanning direction are continuously formed by the same nozzle, and the two line images adjacent in the sub-scanning direction. An image recording apparatus including a second recording mode continuously formed by the nozzles.   The image recording apparatus according to claim 2, wherein in the image recording process, the recording unit is moved only in one direction of the sub-scanning direction to perform the sub-scanning one or more times. Of the two line images formed successively, the line image formed first is the previous line image, and the line image formed later is the subsequent line image.
In the second recording mode, the subsequent line image is formed by the nozzle provided upstream in one direction of the sub-scanning direction in the recording unit with respect to the nozzle that has formed the previous line image. Item 4. The image recording apparatus according to Item 3. An image recording process for recording an image on a recording medium that performs main scanning for ejecting liquid from the nozzles and stops on a support member while moving a recording unit having a plurality of nozzles arranged in the sub-scanning direction in the main scanning direction. An image recording step that can be performed in a plurality of recording modes in which the combination of the nozzles for ejecting is different from each other;
A maintenance process for maintaining the nozzle while discharging liquid from the nozzle before the image recording process is started,
In the image recording step, the nozzle for ejecting liquid is selected from the plurality of nozzles according to the recording mode selected to execute the image recording processing from the plurality of recording modes and the width of the recording medium. And the image recording process is executed by the selected nozzle,
In the maintenance step, the maintenance is not performed on the nozzles that do not eject liquid in the image recording process. An image recording process for recording an image on a recording medium that performs a main scan in which liquid is ejected from the nozzles while moving a recording unit having a plurality of nozzles arranged in the sub-scanning direction in the main scanning direction and stops on a support member. In the program to be executed by the image recording apparatus using
The recording mode selected to execute the image recording process from the plurality of recording modes, and the image recording process can be performed in a plurality of recording modes in which combinations of the nozzles for ejecting liquids are different from each other. Selecting the nozzle for ejecting liquid from the plurality of nozzles according to the width of the recording medium, and executing the image recording process by the selected nozzle;
In the maintenance of the nozzle that is performed while discharging the liquid from the nozzle before the image recording process is started, the maintenance is not performed for the nozzle that does not eject the liquid in the image recording process. For causing the image recording apparatus to execute the program using the computer.   A program recording medium on which the program according to claim 6 is recorded.

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