JP2010264721A - Adjusting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an adjusting method of fluid jetting apparatus which suppresses deterioration of image. <P>SOLUTION: The adjusting method of fluid jetting apparatus enables the following tasks to be performed: the first pattern is formed by the first operation for jetting a fluid from two or more heads 41 while moving a plurality of heads from one side to other side of the moving direction against a medium. The second pattern is formed by the second operation for jetting a fluid while moving the heads from other side to one side. Based on the first pattern, the first interval which is the interval of lines formed by two heads which have been arranged separately in the direction crossing a predetermined direction among two or more heads 41 is computed. Based on the second pattern, the second interval which is the interval of lines formed by two heads which have been arranged separately in the direction crossing a predetermined direction among two or more heads 41 is computed. Based on the first and second intervals, a nozzle train is inclined in the reverse direction against the direction crossing the moving direction at the time of the second operation at the angle inclining against the direction where the nozzle train crosses the moving direction at the time of the first operation. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an adjustment method.

  As one of fluid ejecting apparatuses, an ink jet printer (hereinafter referred to as a printer) having a head that ejects ink (fluid) onto a medium is known. The head is provided with a nozzle row in which a plurality of nozzles that eject ink are arranged in a predetermined direction, and an image is printed on the medium by ejecting ink while moving the head in the moving direction with respect to the medium. .

  In order to realize high-speed printing of a printer, a printer in which a plurality of heads are arranged in the nozzle row direction has been proposed. A plurality of heads arranged in the nozzle row direction may be arranged in a staggered pattern due to structural problems (for example, Patent Document 1).

JP 2008-18639 A

In the above printer, if a plurality of heads are inclined when printing is performed, the interval between the dot rows along the moving direction formed by each head is shifted, and the image is deteriorated. Even in the case of a single-head printer, if the head is tilted during printing, the image quality is similarly deteriorated.
Accordingly, an object of the present invention is to suppress image deterioration.

  The main invention for solving the above problems is: (1) Adjustment of a fluid ejecting apparatus in which a plurality of heads each having a nozzle row in which nozzles for ejecting fluid onto a medium are arranged in a predetermined direction are arranged at different positions in the predetermined direction. In the method, (2) in the moving direction by a first operation of ejecting fluid from the plurality of heads while moving the plurality of heads from one side of the moving direction to the other side with respect to the medium. Forming a first pattern in which a line along the line intersects the moving direction; and (3) moving the plurality of heads from the other side of the moving direction to the one side with respect to the medium. Forming a second pattern in which a line along the moving direction is arranged in a direction intersecting the moving direction by a second operation of ejecting fluid from the plurality of heads, and (4) the first pattern And calculating a first interval which is an interval between the lines formed by the two heads arranged apart from each other in a direction intersecting the predetermined direction among the plurality of heads. ) Based on the second pattern, a second interval that is an interval between the lines formed by the two heads arranged apart from each other in the direction intersecting the predetermined direction among the plurality of heads is calculated. (6) Based on the first interval and the second interval, the nozzle row is inclined at an angle with respect to the direction intersecting the moving direction during the first operation, and during the second operation. Tilting the nozzle row in a direction opposite to the direction intersecting the moving direction.

  Other features of the present invention will become apparent from the description of this specification and the accompanying drawings.

1 is a configuration block diagram of a printing system. 2A is a cross-sectional view of the printer, and FIG. 2B is a top view. It is a figure which shows arrangement | positioning of the some head in a head unit. It is a figure which shows a mode that a head unit inclines during a movement. 5A and 5B are diagrams showing lines formed when the head is tilted. It is a figure explaining the inclination adjustment mechanism of a baseplate. It is a figure for demonstrating the modification of the adjustment method of the inclination of a nozzle row. It is a figure for demonstrating the correction method of the dot formation position of a comparative example. FIG. 8A is a diagram showing a test pattern formed by a head unit that is tilted during movement, and FIG. 8B is a diagram showing lines corrected by the correction method of the comparative example. It is a flow of a dot formation position correction method in the present embodiment. It is a figure which shows a 1st test pattern. It is a figure which shows a mode that the outward path line of the 1st head and the outward path line of the 3rd head were correct | amended. It is a figure which shows the line formed by correct | amending the ejection timing of a head. It is a figure which shows the correction method of another comparative example of the dot formation position by each head. FIG. 12A shows a line when the inclination of the base plate is different between the outward trip and the return trip, and FIG. 12B shows a line when the inclination of the base plate is the same during the outward trip and the return trip. FIG. 13A is a diagram showing a second test pattern, and FIG. 13B is a diagram showing corrected forward and return path lines. It is a figure which shows another calculation method of a 2nd correction value. It is a figure which shows the modification of a test pattern. It is a figure which shows the modification of a test pattern.

=== Summary of disclosure ===
At least the following will become apparent from the description of the present specification and the accompanying drawings.

That is, (1) a method for adjusting a fluid ejecting apparatus in which a plurality of heads each having a nozzle row in which nozzles that eject fluid to a medium are arranged in a predetermined direction are arranged at different positions in the predetermined direction, and (2) A line along the moving direction intersects the moving direction by the first operation of ejecting fluid from the plurality of heads while moving the plurality of heads from one side of the moving direction to the other side with respect to the medium. Forming a first pattern arranged in a direction; and (3) ejecting fluid from the plurality of heads while moving the plurality of heads from the other side of the moving direction to the one side with respect to the medium. Forming a second pattern in which lines along the moving direction are arranged in a direction intersecting the moving direction by a second operation to be performed; and (4) based on the first pattern, the plurality of heads. Calculating a first interval that is an interval between the lines formed by the two heads arranged apart in a direction intersecting the predetermined direction, and (5) based on the second pattern, Calculating a second interval which is an interval between the lines formed by the two heads arranged apart from each other in a direction intersecting the predetermined direction among the plurality of heads; (6) the first Based on the interval of 1 and the second interval, the nozzle row intersects the moving direction during the second operation at an angle that the nozzle row is inclined with respect to the direction intersecting the moving direction during the first operation. And an inclining direction opposite to the direction of the adjustment.
According to such an adjustment method, the inclination of the nozzle row during the first operation and the second operation can be made as small as possible, and image deterioration can be suppressed.

In this adjustment method, in the fluid ejecting apparatus, the plurality of heads are attached to one plate, and based on the first interval and the second interval, the plate is moved in a direction intersecting the moving direction. Being to adjust the tilt.
According to such an adjustment method, the inclination of the nozzle row during the first operation and the second operation can be adjusted.

In this adjustment method, the nozzle rows of the plurality of heads attached to the plate are parallel.
According to such an adjustment method, the inclination of the nozzle row during the first operation and the second operation can be adjusted by adjusting the inclination of the plate.

In this adjustment method, the inclination of each head with respect to the direction intersecting the moving direction is adjusted based on the first interval and the second interval.
According to such an adjustment method, the inclination of the nozzle row during the first operation and the second operation can be adjusted.

In this adjustment method, a third pattern is formed by the first operation, a fourth pattern is formed by the second operation, and the plurality of heads are formed based on the third pattern and the fourth pattern. The landing position in the moving direction of the fluid ejected from the end nozzle on one side of the predetermined head of the certain head in the first operation, and the fluid ejected from the certain head in the first operation Landing position in the moving direction of the fluid ejected during the second operation from the head that ejects the fluid during the second operation to the landing position and the end nozzle on the other side of the head arranged on the one side in the predetermined direction And obtaining the correction value for aligning and storing the correction value in the storage unit of the fluid ejecting apparatus.
According to such an adjustment method, it is possible to suppress image deterioration by suppressing a shift between the edge of the image formed during the first operation and the edge of the image formed during the second operation. The inclination of the line formed by the whole of the plurality of heads can be reduced.

In this adjustment method, based on the third pattern and the fourth pattern, the landing position in the moving direction of the fluid ejected from the central nozzle of the certain head during the first operation, and the first pattern A landing position in the moving direction of the fluid ejected during the second operation from a central nozzle of the head that ejects the fluid during the second operation to a landing position of the fluid ejected from the certain head during the operation; To obtain another correction value for aligning and storing the other correction value in the storage unit.
According to such an adjustment method, it is possible to suppress image deterioration by suppressing a shift between an image formed during the first operation and an image formed during the second operation in the same region on the medium.

In this adjustment method, based on the third pattern and the fourth pattern, the movement direction of the fluid ejected from the end nozzle on one side of the certain head in the predetermined direction during the second operation is determined. A landing position of the fluid ejected from the certain head at the time of the second operation, and the other side of the head aligned with the one side in the predetermined direction at the landing position of the fluid ejected from the certain head at the first operation. Acquiring another correction value for aligning the landing position in the moving direction of the fluid ejected from the end nozzle in the first operation, and storing the other correction value in the storage unit.
According to such an adjustment method, it is possible to suppress image deterioration by suppressing a shift between the edge of the image formed during the first operation and the edge of the image formed during the second operation.

(1) A method for adjusting a fluid ejecting apparatus including a head having a nozzle row in which nozzles for ejecting fluid to a medium are arranged in a predetermined direction, wherein (2) the head is moved in a moving direction with respect to the medium. Forming a first line that is a line along the moving direction by a first operation of ejecting fluid from the nozzle while moving from one side to the other; and (3) the head on the medium. On the other hand, forming a second line that is a line along the moving direction by a second operation of ejecting fluid from the nozzle while moving from the other side to the one side in the moving direction; 4) Based on the position of the first line in the direction intersecting the moving direction and the position of the second line in the intersecting direction, the nozzle row is in the direction intersecting during the first operation. Lean At an angle, an adjustment method characterized by having a possible tilting in the opposite direction to the nozzle row with respect to the crossing direction when the second operation.
According to such an adjustment method, the inclination of the nozzle row during the first operation and the second operation can be made as small as possible, and image deterioration can be suppressed.

=== About the printing system ===
Hereinafter, an ink jet printer (hereinafter, printer 1) is taken as an example of the fluid ejecting apparatus, and a printing system in which the printer 1 and the computer 60 are connected will be described.

  FIG. 1 is a configuration block diagram of a printing system. 2A is a schematic cross-sectional view of the printer 1, and FIG. 2B is a schematic top view of the printer 1. The printer 1 that has received the print data from the computer 60, which is an external device, controls each unit (conveyance unit 20, drive unit 30, and head unit 40) by the controller 10, and the medium S (continuous paper) located in the print area. An image is formed on. Further, the detector group 50 monitors the situation in the printer 1, and the controller 10 controls each unit based on the detection result.

  The transport unit 20 transports the medium S from the upstream side to the downstream side in the direction in which the medium S continues (hereinafter referred to as the transport direction). The roll-shaped medium S before printing is supplied to the printing area by the conveyance roller 21 driven by a motor, and then the printed medium S is wound into a roll shape by a winding mechanism. In the printing area during printing, the medium S is vacuum-sucked from below, and the medium S is held at a predetermined position.

  The drive unit 30 freely moves the head unit 40 in an X direction corresponding to the transport direction and a Y direction corresponding to the width direction of the medium S. The drive unit 30 includes an X-axis stage 31 that moves the head unit 40 in the X direction (corresponding to the moving direction), a Y-axis stage 32 that moves the X-axis stage 31 in the Y direction, and a motor (not shown). ).

  The head unit 40 is for forming an image and has a plurality of heads 41. On the lower surface of the head 41, a plurality of nozzles which are ink ejecting portions are provided, and each nozzle is provided with an ink chamber containing ink.

  Next, a printing procedure will be described. First, the head unit 40 is moved in the X direction (transport direction) by the X-axis stage 31 with respect to the medium S supplied to the printing area by the transport unit 20, and ink is ejected from the nozzles during this movement, so that the medium S A dot row is formed along the X direction. Thereafter, the head unit 40 is moved in the Y direction (paper width direction) by the Y axis stage 32 via the X axis stage 31, and then printing is performed again while the head unit 40 is moved in the X direction. In this way, the dot formation operation by the movement of the head unit 40 in the X direction and the movement of the head unit 40 in the Y direction are alternately repeated, so that the positions of the dots formed by the previous dot formation operation are different. A dot can be formed at the position, and the image is completed (image forming operation). Thus, when the printing of the medium S supplied to the printing area is completed, the part of the medium S that has not yet been printed by the conveying unit 20 is supplied to the printing area (conveying operation), and again the medium S in the printing area. An image is formed. In the printer 1 of this embodiment, the image forming operation and the medium S transport operation are alternately repeated.

=== Regarding Arrangement of Head 41 ===
FIG. 3 is a diagram showing the arrangement of the plurality of heads 41 in the head unit 40. In practice, the nozzle surface is formed on the lower surface of the head unit 40, but FIG. 3 is a view of the nozzle virtually viewed from the upper surface (the same applies to the following drawings). By arranging a large number of nozzles in the paper width direction, an image having a large width can be printed by one movement of the head unit 40 in the transport direction. By doing so, the printing speed can be increased. However, a long head cannot be formed due to manufacturing problems. Therefore, in the printer 1, a plurality of short heads 41 (n) are arranged side by side in the paper width direction. As shown in the drawing, the plurality of heads 41 are attached to the base plate BP. In the manufacturing process of the printer 1, a base plate BP (corresponding to a plate) to which a plurality of heads 41 are attached is attached to the main body of the printer 1.

  On the nozzle surface of each head 41, a yellow nozzle row Y for ejecting yellow ink, a magenta nozzle row M for ejecting magenta ink, a cyan nozzle row C for ejecting cyan ink, and a black nozzle row for ejecting black ink. K is formed. Each nozzle row includes 180 nozzles, and the 180 nozzles are aligned at a constant interval (180 dpi) in the paper width direction. As shown in the figure, numbers are assigned in order from the nozzles on the back side in the paper width direction (# 1 to # 180).

  Of the two heads (for example, 41 (1) and 41 (2)) adjacent to each other in the paper width direction, the nozzle # 180 on the front side of the head 41 (1) on the back side and the head 41 (2 on the front side) ) With the innermost nozzle # 1 is also a constant interval (180 dpi). That is, on the lower surface of the head unit 40, the nozzles are arranged at a constant interval (180 dpi) in the paper width direction. Note that end nozzles of different heads 41 may overlap.

  As shown in FIG. 3, in order to set the interval between the end nozzles of the different heads 41 to 180 dpi, the heads 41 need to be arranged in a staggered manner due to structural problems of the heads 41. When a plurality of heads 41 are arranged in a staggered manner in this way, in order to form a straight line along the paper width direction, fluid from the head 41 (odd numbered head, for example, 41 (1)) on the downstream side in the transport direction. It is necessary to correct the timing at which the fluid is ejected and the timing at which the fluid is ejected from the upstream-side head 41 (even-numbered head, for example, 41 (2)) in the transport direction. Hereinafter, a method of correcting the ejection timing (dot formation position) from the head 41 whose position in the transport direction is shifted will be described.

=== About the inclination adjustment of the base plate BP ===
FIG. 4 is a diagram illustrating a state in which the head unit 40 of the present embodiment is tilted during movement in the transport direction. As shown in FIGS. 2B and 3, in the printer 1 of this embodiment, the head unit 40 is moved in the transport direction only by the X-axis stage 31 (the drive shaft to which the drive motor is attached) on the back side in the paper width direction. . That is, only one end of the head unit 40 in the paper width direction is driven. Further, since many heads 41 are arranged in the transport direction in the head unit 40, the head unit 40 is relatively heavy and has a structure that is long in the paper width direction. For this reason, when the head unit 40 is moved in the transport direction, a strong inertial force acts on the end of the head unit opposite to the X-axis stage 31 side (the front side in the paper width direction). It becomes easy to tilt.

  Further, in the printer 1 of the present embodiment, the head unit 40 moves from the upstream side in the transport direction to the downstream side when the head unit 40 moves from the downstream side in the transport direction to the upstream side (hereinafter referred to as the forward path). It is assumed that printing is also performed at the time (hereinafter referred to as a return pass) (bidirectional printing). As shown in FIG. 4, the head unit 40 tilts in the clockwise direction during the forward pass, and the head unit 40 tilts in the counterclockwise direction during the return pass. That is, the direction in which the head unit 40 tilts is different between the forward pass and the return pass. In FIG. 4, the head unit 40 is drawn with a large inclination for the sake of explanation.

  The phenomenon in which the head unit 40 is tilted with respect to the paper width direction while moving in the transport direction is likely to occur when only one side of the head unit 40 is driven. In particular, when the guide rail or the like is not provided on the opposite side of the X-axis stage 31 (drive shaft) as in the printer 1 of the present embodiment, the head unit 40 is more easily tilted.

  5A and 5B are diagrams illustrating lines formed when the nozzle row of the head 41 is tilted with respect to the paper width direction during printing. FIG. 6A is a diagram illustrating a tilt adjustment mechanism of the base plate BP. Here, in the manufacturing process of the printer 1, as shown in FIG. 6A, the plurality of heads 41 are mounted on the base plate BP so that the center line CL2 of the base plate BP and the nozzle row direction (corresponding to a predetermined direction) of the head 41 are parallel to each other. Attached to. In FIG. 6A, the number of heads 41 is four for the sake of simplicity. When the base plate BP with the plurality of heads 41 attached is incorporated into the main body of the printer 1 (main body of the head unit 40), the center line CL1 of the head unit 40 and the center line CL2 of the base plate BP are parallel to each other. To. That is, the components are assembled so that the paper width direction of the printing paper S, the center line CL1 of the head unit 40, the center line CL2 of the base plate BP, and the nozzle row direction of the head 41 are parallel.

  Even when the printer 1 is assembled so that the nozzle row direction of the head 41 and the paper width direction (corresponding to the direction intersecting the moving direction) are parallel, the head unit 40 is moving in the conveying direction (corresponding to the moving direction). As shown in FIG. 4, the head unit 40 (center line CL1 thereof) is inclined with respect to the paper width direction. That is, during the movement of the head unit 40 in the transport direction, as shown in FIG. 5, the center line CL2 of the base plate BP and the nozzle row of the head 41 are inclined with respect to the paper width direction. FIG. 5 shows lines (hereinafter referred to as raster lines) formed by ejecting ink droplets from the head 41 inclined during the movement of the head unit 40 at predetermined time intervals.

  When the head unit 40 is tilted with respect to the paper width direction during movement, the nozzle row of the head 41 is also tilted with respect to the paper width direction. The raster line that is formed when the nozzle row is tilted with respect to the paper width direction has a position in the paper width direction that is different from the raster line that is formed when the nozzle row is along the paper width direction (for example, the design raster line formation position). It will shift. Therefore, the inclination of the nozzle row (head 41) during printing with respect to the paper width direction, that is, the inclination of the base plate BP (center line CL2) during movement in the transport direction is preferably as small as possible.

  As shown in FIG. 3, in the printer 1 of the present embodiment, a plurality of heads 41 arranged in the paper width direction are arranged in a staggered manner. That is, the heads 41 arranged in the paper width direction are arranged apart in the transport direction. Therefore, when the head unit 40 is tilted while moving in the transport direction, as shown in FIG. 5, the raster line intervals D1 and D2 formed on the end nozzles of the heads 41 are set to predetermined raster line intervals (for example, nozzles). It becomes narrower or wider than (pitch = 180 dpi).

  When the head 41 during printing is inclined clockwise as shown in FIG. 5A during the forward path, the raster line formed by the end nozzles on the front side in the paper width direction of the first head 41 (1) and the paper width of the second head 41 (2). The raster line interval D1 (corresponding to the first interval) by the end nozzles on the far side in the direction is wider than the nozzle pitch. On the other hand, a raster line interval D2 between the raster line formed by the end nozzle on the near side in the paper width direction of the second head 41 (2) and the raster line formed by the end nozzle on the back side in the paper width direction of the third head 41 (3). Equivalent) is narrower than the nozzle pitch.

  On the other hand, when the head 41 during printing is tilted counterclockwise as shown in FIG. 5B during the return pass, the raster line formed by the end nozzle on the front side in the paper width direction of the first head 41 (1) and the second head 41 ( The raster line interval D1 (corresponding to the second interval) by the end nozzles on the back side in the paper width direction of 2) is narrower than the nozzle pitch. On the other hand, the raster line interval D2 (the second interval) between the raster line by the end nozzle on the near side in the paper width direction of the second head 41 (2) and the end line nozzle on the back side in the paper width direction of the third head 41 (3). Equivalent) is wider than the nozzle pitch. As the inclination of the head 41 during printing with respect to the paper width direction increases, the amount of deviation from the nozzle pitch of the raster line intervals D1, D2 formed in the end nozzles increases.

  As described above, when the head 41 during printing is inclined with respect to the paper width direction due to the inclination of the head unit 40 in the transport direction, the raster line interval formed on the end nozzles of the heads 41 is widened. Or narrow and overlap. If it does so, an image will deteriorate. However, in order to move the head unit 40 smoothly in the transport direction, a slight gap is required between the moving axis of the X-axis stage 31 and the head unit 40. Therefore, it is not possible to completely prevent the head unit 40 from being tilted during movement.

  Therefore, an object of the present embodiment is to reduce the inclination of the head 41 (nozzle row) during printing with respect to the paper width direction as much as possible. In other words, an object is to reduce the inclination of the base plate BP (center line CL2) with respect to the paper width direction during the movement of the head unit 40 as much as possible. In the manufacturing process, the inclination of the base plate BP (nozzle row) is not limited to adjustment. Even when maintenance of the printer 1 is performed after the printer 1 is shipped to the user, the inclination of the base plate BP may be adjusted by the following adjustment method.

  In addition, since the printer 1 of the present embodiment performs bidirectional printing, it is necessary to make the inclination of the base plate BP with respect to the paper width direction as small as possible during both the forward pass and the return pass. Due to the characteristics of the head unit 40 and the X-axis stage 31, the inclination of the head unit 40 with respect to the paper width direction is not always constant during the forward path and the backward path. Further, the printer 1 may be assembled by tilting the center line CL2 of the base plate BP with respect to the center line CL1 of the head unit 40. That is, the inclination of the base plate BP with respect to the paper width direction during the forward pass may be different from the inclination of the base plate BP with respect to the paper width direction during the return pass. In this case, the inclination of the base plate BP with respect to the paper width direction is increased in one of the forward pass and the return pass, and the image is deteriorated.

  Therefore, in the present embodiment in which bidirectional printing is performed, an object is to equalize the inclination of the base plate BP with respect to the paper width direction during the forward pass and during the return pass. In other words, the base plate BP (nozzle row) is inclined with respect to the paper width direction during the forward pass (first operation), and the base plate BP (nozzle row) is reversed with respect to the paper width direction during the return pass (second operation). Tilt in the direction.

  By doing so, even if the base plate BP is tilted and attached to the head unit 40, or the head unit 40 has a different inclination with respect to the paper width direction during the forward path and the backward path, the base plate BP ( The inclination of the nozzle row) with respect to the paper width direction can be minimized. As a result, it is possible to suppress the deterioration of the images formed during the forward pass and the return pass in the same manner.

  For this purpose, the head unit 40 of this embodiment has an adjustment mechanism for adjusting the inclination of the base plate BP with respect to the paper width direction, as shown in FIG. 6A. The adjustment mechanism is a compression provided between the micrometer 60 in contact with the end surface BPa on the back side in the paper width direction of the base plate BP, the end surface BPb on the near side in the paper width direction of the base plate BP, and the casing 42 of the head unit 40. A spring 63 and a rotation shaft 64 are provided. The micrometer 60 and the compression spring 63 are located downstream of the center line CL1 of the base plate BP in the transport direction, and face each other with the base plate BP interposed therebetween.

  The spindle 62 expands and contracts by rotating the operation unit 61 of the micrometer 60. When the spindle 62 extends, the end surface BPa of the base plate BP is pushed, and the compression spring 63 contracts toward the front side in the paper width direction. Then, the base plate BP tilts counterclockwise with the rotation shaft 64 as a fulcrum. When the operation unit 61 is rotated in the reverse direction, the spindle 62 contracts, and the compression spring 63 extends to the back side in the paper width direction. Then, the base plate BP tilts clockwise with the rotation shaft 64 as a fulcrum. Thus, by adjusting the expansion and contraction of the spindle 62 of the micrometer 60, the inclination of the base plate BP with respect to the paper width direction can be adjusted. In other words, the inclination of the center line CL2 of the base plate BP with respect to the center line CL1 of the head unit 40 can be adjusted by the micrometer 60.

  In the present embodiment, in order to equalize the inclination of the base plate BP with respect to the paper width direction during the forward path and during the backward path, the tilt adjustment of the center line CL2 of the base plate BP with respect to the center line CL1 of the head unit 40 during the manufacture of the printer 1 is performed. I do. For this purpose, first, after the base plate BP to which the head 41 is attached is assembled in the main body of the printer 1, the printer 1 is caused to print a test pattern. As a test pattern, as shown in FIG. 5, ink droplets are ejected from the head unit 40 moving in the transport direction at a predetermined time interval, and a raster line (corresponding to a raster line along the movement direction) is provided to each nozzle of the head 41. To form. In FIG. 5, in order to eject ink droplets from all nozzles of the head 41, raster lines are formed side by side in the paper width direction as test patterns. In addition, a test pattern for the forward path (corresponding to the first pattern) and a test pattern for the backward path (corresponding to the second pattern) are formed.

  Next, based on the printed test pattern (collection of raster lines arranged in the paper width direction), the interval (D1, D2 in FIG. 5) of the raster lines formed by the end nozzles of the heads 41 adjacent in the paper width direction is calculated. To do. For this purpose, the printed test pattern should be read with a scanner. Further, when printing the test pattern, the raster line formed on the end nozzles of each head 41 may be longer than the raster line formed on the other nozzles. By doing so, it is possible to correctly recognize the raster line formed on the end nozzle from the test pattern result. In addition, the ink droplets are not necessarily ejected from all the nozzles of the head 41, and at least the ink droplets may be ejected from the end nozzles of the head 41.

  Raster line intervals D1 and D2 by the end nozzles of the heads 41 arranged in the paper width direction change according to the magnitude of the inclination θ of the base plate BP with respect to the paper width direction during movement of the head unit. During the forward pass (FIG. 5A), the first line of the raster line by the end nozzle on the near side in the paper width direction of the odd-numbered head 41 (1) and the raster line by the end nozzle on the back side in the paper width direction of the even-numbered head 41 (2). The interval D1 becomes wider than the nozzle pitch. On the other hand, during the return pass (FIG. 5B), the raster line formed by the end nozzle on the front side in the paper width direction of the even-numbered head 41 (2) and the raster line formed by the end nozzle on the back side in the paper width direction of the odd-numbered head 41 (3). The second line interval D2 becomes wider than the nozzle pitch. For this reason, the first line interval D1 (corresponding to the first interval) during the forward pass and the second line interval D2 (corresponding to the second interval) during the return pass are preferably made equal. Similarly, the second line interval D2 during the forward pass and the first line interval D1 during the return pass are made equal. By doing so, the inclination of the base plate BP with respect to the paper width direction during the forward pass and the inclination of the base plate BP with respect to the paper width direction during the return pass can be made equal.

  For example, it is assumed that the second line interval D2 in the test pattern (FIG. 5B) during the return path is wider than the first line interval D1 in the test pattern during the forward path (FIG. 5A). In this case, the inclination of the base plate BP with respect to the paper width direction during the return path is larger than the inclination of the base plate BP during the forward path. Therefore, it is preferable that the spindle 62 is contracted to the back side in the paper width direction by adjusting the micrometer 60 and the base plate BP is tilted clockwise. By doing so, the inclination of the base plate BP with respect to the paper width direction (or the center line CL1 of the head unit 40) during the return path is reduced, and conversely, the inclination of the base plate BP with respect to the paper width direction during the outward path can be increased. As a result, it is possible to equalize the inclination of the base plate BP with respect to the paper width direction during the forward pass and during the return pass.

  By doing so, even if the head unit 40 tilts while moving in the transport direction, the tilt of the head 41 (nozzle row) during printing with respect to the paper width direction can be minimized. As a result, during the forward pass and the return pass, it is possible to reduce the deviation between the raster line intervals D1 and D2 formed in the end nozzles of each head 41 and the nozzle pitch, and to suppress image deterioration.

  Further, even if the inclination of the base plate BP with respect to the paper width direction is adjusted, if the nozzle rows of the plurality of heads 41 attached to the base plate BP are not parallel and are inclined relatively, the effect of suppressing image deterioration is reduced. . Therefore, the mutual inclination of each head 41 (nozzle row) may be adjusted. Therefore, each head 41 attached to the base plate BP may be provided with a micrometer 60, a compression spring 63, and a rotating shaft 64, similarly to the tilt adjustment mechanism of the base plate BP. Then, after the heads 41 are attached to the base plate BP, for example, ink droplets are simultaneously ejected from the heads 41 to form lines along the nozzle row direction of the heads 41. Based on the line, the inclination of each head 41 may be adjusted so that the directions of the nozzle rows of the plurality of heads 41 attached to the base plate BP are parallel. Thereafter, the test pattern shown in FIG. 5 may be printed to adjust the inclination of the base plate BP with respect to the paper width direction.

  When each head 41 has an inclination adjustment mechanism, the base plate BP inclination adjustment mechanism may not be provided. That is, the inclination θ with respect to the paper width direction of the center line CL2 of the base plate BP is not necessarily equal in the forward path and the backward path. In the forward pass and the return pass, the inclinations of the nozzle rows of the plurality of heads 41 with respect to the paper width direction may be made equal. In this case, after the test pattern shown in FIG. 5 is printed, the inclination of each head 41 (nozzle row) with respect to the paper width direction may be adjusted based on the raster line intervals D1 and D2 by the end nozzles of each head 41.

  Moreover, it is not restricted to the inclination adjustment mechanism of the baseplate BP shown to FIG. 6A. For example, a piezoelectric actuator may be used instead of the micrometer 60. A piezoelectric actuator has a piezoelectric element that expands and contracts in accordance with an applied drive voltage when a drive voltage is applied. Then, the inclination of the base plate BP may be adjusted by pushing or returning the end surface BPa of the base plate BP by expansion and contraction of the piezoelectric element.

=== Modification ===
FIG. 6B is a diagram for explaining a modification of the method for adjusting the inclination of the nozzle row (head 41). Up to this point, the printer 1 (FIG. 3) in which the head unit 40 has a plurality of heads 41 is taken as an example, but the present invention is not limited to this. The head unit 40 may be a printer including one head 41. In a printer that includes one head 41 and performs bidirectional printing, the inclination of the nozzle row (head 41) during the forward pass and the return pass with respect to the paper width direction (direction intersecting the moving direction of the head unit 40) is preferably equal. In other words, it is preferable that the nozzle row is inclined at an angle with respect to the paper width direction during the forward pass (first operation) and tilted in the opposite direction with respect to the paper width direction during the return pass (second operation).

  By doing so, it is assumed that the head 41 (nozzle row) is attached with an inclination with respect to the direction intersecting the moving direction of the head unit 40, or that the inclination of the head unit 40 with respect to the paper width direction is different during the forward pass and the return pass. In addition, it is possible to minimize the inclination of the nozzle row with respect to the paper width direction during the forward pass and the return pass. As a result, it is possible to suppress the deterioration of the images formed during the forward pass and the return pass in the same manner.

  In the printer 1 having a plurality of heads 41, as shown in FIG. 5, the inclination is adjusted based on the intervals D1 and D2 of the raster lines (lines along the transport direction) formed by the end nozzles of each head 41. Is going. On the other hand, in this modified example, as shown in FIG. 6B, the nozzle # 11 of the head 41 is formed with a line (raster line) along the transport direction at the time of the forward pass and the return pass to adjust the inclination. Do.

  The upper diagram of FIG. 6B shows a case where the inclination θ1 of the nozzle row with respect to the paper width direction during the forward pass is equal to the slope θ1 with respect to the paper width direction of the nozzle row during the return pass (when the nozzle rows are tilted symmetrically). In this case, the position in the paper width direction of the first line (first line) formed at the nozzle # 11 during the forward pass and the paper width direction of the second line (second line) formed at the same nozzle # 11 during the return pass. Is equal to the position of. That is, the two lines overlap.

  On the other hand, the lower diagram of FIG. 6B shows a case where the inclination θ2 of the nozzle row during the backward pass is larger than the inclination θ1 of the nozzle row during the forward pass. In this case, the second line during the return path is located on the far side in the paper width direction than the first line during the forward path. Therefore, when a line as shown in the lower diagram of FIG. 6B is formed, the head 41 (nozzle) is moved with respect to the head unit 40 (direction intersecting the moving direction) by an inclination adjustment mechanism (not shown) of the head 41. It is good to make adjustments to tilt the column) clockwise.

  Thus, the position in the paper width direction of the raster line formed on a certain nozzle (# 11) during the forward path, and the position in the paper width direction of the raster line formed on a certain nozzle (# 11) during the backward path, Based on the above (by acquiring the position by visual observation or a scanner), it is possible to determine the inclination of each nozzle row during the forward pass and the return pass. Then, it is preferable to adjust so that the inclination (angle) of the nozzle row (head 41) with respect to the paper width direction in the forward pass and the return pass is equal and inclines in the opposite direction.

  In FIG. 6B, a raster line is formed on one nozzle # 11, but the present invention is not limited to this, and a raster line may be formed on a plurality of nozzles. In FIG. 6B, a raster line is formed at the end nozzle # 11 closest to the paper width direction in the nozzle row. This is because the nozzle # 11 is located on the most opposite side with respect to the X-axis stage 31 (drive shaft) and is most affected by the tilt during the movement of the head unit 40, so that the tilt can be accurately determined. However, the raster line may be formed not only at the nozzle # 11 at the end but also at other nozzles. However, it is preferable to form raster lines in at least half of the nozzle rows on the opposite side of the drive shaft.

  Further, in a printer having a plurality of heads as shown in FIG. 3, as shown in FIG. 6B, the nozzles of the plurality of heads 41 are moved in the transport direction (the moving direction of the head unit 40) during the forward path and the multiple paths. The inclination can be adjusted by forming a raster line along.

=== Comparative Example: Correction Method of Dot Forming Position ===
FIG. 7 is a diagram for explaining a dot formation position correction method according to a comparative example. Hereinafter, to simplify the description, the number of heads 41 included in the head unit 40 is four. In the printer 1 of the present embodiment, the heads 41 are arranged in a staggered manner in the head unit 40 (FIG. 3). The shift amount in the transport direction in the design of the heads 41 (1) (3) on the downstream side in the transport direction and the heads 41 (2) (4) on the upstream side in the transport direction is known in advance. Here, as shown in the drawing, the difference between the transport direction mounting position of the downstream head 41 and the transport direction mounting position of the upstream head 41 is defined as “deviation amount ΔX”.

  For example, when the head unit 40 moves from the downstream side in the transport direction to the upstream side, when the ink is ejected from the upstream head 41 and the downstream head 41 to the same position in the transport direction on the medium S, the upstream head 41 (2) (4) faces the target injection position earlier than the downstream heads 41 (1) (3). After the upstream heads 41 (2) (4) face the target position, the downstream heads 41 (1) (3) are moved to the target after the head unit 40 has moved by the “deviation amount ΔX” in the transport direction. Opposite the position.

  Therefore, by design, the downstream head 41 (1) is ejected after the time required for the head unit 40 to move by ΔX in the transport direction after the fluid is ejected from the upstream head 41 (2) (4). The fluid is ejected from (3). By doing so, it is possible to align the dot formation positions in the transport direction in the upstream heads 41 (2) and (4) and the dot formation positions in the transport direction in the downstream heads 41 (1) and (3). Then, a straight line along the paper width direction can be formed by the plurality of heads 41 arranged in a zigzag shape included in the head unit 40.

  However, in reality, the dots may be formed out of the target position at the designed ejection timing due to an attachment error that occurs when the head 41 is attached to the base plate BP or a difference in the ejection characteristics of each head 41. is there. Therefore, in the manufacturing process of the printer 1 and the like, each printer 1 is actually printed with a test pattern, and a dot formation position correction value in the transport direction of each head 41 is calculated based on the test pattern.

  Hereinafter, a method for obtaining a correction value of the dot formation position in the comparative example will be described. FIG. 7 shows a test pattern formed on the medium S located in the printing area. In order to form such a test pattern, first, a target position is set on the medium S. Then, the ink is ejected from each head 41 at the designed ejection timing so that the ink droplets ejected from the respective heads 41 arranged in a staggered pattern land on the target position. Here, as test patterns, ink droplets are ejected from all 180 nozzles of each head 41. However, the present invention is not limited to this. For example, ink droplets may be ejected from every other nozzle. As a result, as shown in FIG. 7, a dot row along the paper width direction (nozzle row direction) is formed by the heads 41 (1) to 41 (4).

When the test pattern is specifically seen, the line formed by the first head 41 (1) is formed without deviating from the target position. From this, it is understood that the ejection timing of the first head 41 does not need to be corrected from the designed ejection timing.
On the other hand, the line formed by the second head 41 (2) and the fourth head 41 (4) is formed to be shifted to the upstream side in the transport direction from the target position and beyond the target position. From this, it can be seen that the second head 41 (2) and the fourth head 41 (4) need to eject ink droplets at a timing earlier than the designed ejection timing.
On the contrary, the line formed by the third head 41 (3) is shifted to the downstream side in the transport direction from the target position, and is formed in front of the target position. From this, it can be seen that the third head 41 (3) needs to eject ink droplets at a timing later than the designed ejection timing.

  Then, from the test pattern result, it is possible to know how much the injection timing should be corrected by acquiring the deviation amount between the target position and the actually formed line. For example, the line of the fourth head 41 (4) in FIG. 7 is formed so as to be shifted to the upstream side in the transport direction by “ΔY” from the target position. Therefore, it is preferable that the ejection timing of the fourth head 40 (4) is advanced from the designed ejection timing by the time during which the head unit 40 moves the “deviation amount ΔY”. By doing so, a line by the fourth head 40 (4) can be formed at the target position.

  How much the time required for the head unit 40 to move this “deviation amount ΔY (difference between the position of the line formed as a test pattern and the target position)” is advanced or delayed from the designed ejection timing. It corresponds to the correction value. In order to obtain the deviation amount ΔY, the printed test pattern may be read by the scanner, and the difference between the target position and the line position on the read data may be calculated. Alternatively, the target position and line may be calculated from the test pattern. You may measure the difference with this position.

  In this comparative example, when the deviation amount ΔY between the target position and the position of the line formed by each head 41 is acquired, the center portion of the line formed by each head 41 is used as a reference. That is, the ejection timing of the head 41 is determined by the deviation amount ΔY in the transport direction between the target portion and the line portion (the portion circled in FIG. 7) formed by the central portion (for example, nozzle # 90) of the nozzle row. adjust. Thus, the dot formation position of each head 41 can be corrected according to the ejection characteristics and mounting errors. When bidirectional printing is performed, it is preferable to form a test pattern for the forward pass and a test pattern for the return pass.

  FIG. 8A is a diagram showing a test pattern formed by the head unit 40 tilted during movement in the transport direction, and FIG. 8B shows a line corrected by the correction method of the comparative example based on the test pattern result of FIG. 8A. FIG. FIG. 8A shows a test pattern result in the forward path. As shown in FIG. 4, in the printer 1 of this embodiment, the head unit 40 is tilted with respect to the paper width direction while the head unit 40 is moving in the transport direction.

  In the dot forming position correction method in the comparative example, the amount of deviation in the transport direction (deviation from the target position) is based on the center part of the line (circled in the figure) formed on each head 41 as a test pattern. Amount) is corrected. For example, the central portion of the line formed in the second head 41 (2) is located on the upstream side in the transport direction. Therefore, as a result of correcting the ejection timing so that the center of the line of the second head 41 (2) is located at the target position, the entire line by the second head 41 (2) is downstream in the transport direction as shown in FIG. 8B. It is formed shifted to the side. Therefore, according to the correction method of the comparative example, as shown in FIG. 8B, the central portion of the line formed by each head 41 is positioned on a straight line at the target position.

  However, the line formed by the head 41 inclined with respect to the paper width direction has a different position in the transport direction depending on the location of the line, and the amount of deviation from the target position also differs. For example, in FIG. 8B, the center portion of the line by the first head 41 (1) is located at the target position, but the upper end portion (back end portion) of the line is located upstream in the transport direction from the target position. The lower end (front end) of the line is located downstream of the target position in the transport direction.

  For this reason, when the lines formed side by side in the paper width direction are inclined in the same direction, the joint portion of the lines is greatly displaced in the transport direction. For example, the end of the line of the first head 41 (1) on the second head 41 (2) side is located downstream of the target position in the transport direction, whereas the line of the second head 41 (2) The end of the first head 41 (1) side is located upstream of the target position in the transport direction. The fact that the line joints of the different heads 41 are shifted in the transport direction in this way means that the image formed on each head 41 is shifted in the transport direction, and the image quality is deteriorated.

As shown in FIG. 4, when the entire head unit 40 is tilted during movement in the transport direction, or the head 41 is tilted and attached in the same direction, the lines formed side by side in the paper width direction are in the same direction. Will be inclined to. In this case, in the dot formation position correction method of the comparative example, the image of the joint portion of the head 41 is deteriorated.
Therefore, an object of the present embodiment is to suppress a shift in dot formation position in the transport direction due to a joint (end nozzle) of the heads 41 arranged in the nozzle row direction (paper width direction), thereby suppressing image deterioration.

=== This Embodiment: Dot Forming Position Correction Method ===
FIG. 9 is a flow of a dot formation position correction method in this embodiment. As described above, in order to obtain a correction value for correcting the ejection timing from each head 41 of the head unit 40 in accordance with the characteristics of each printer 1, the printer 1 is actually tested in the manufacturing process of the printer 1. Print the pattern. Depending on the correction value, the dot formation positions in the transport direction of the heads 41 arranged in a zigzag manner and having different ejection characteristics are aligned. The correction value is not limited to the manufacturing process. For example, the correction value may be acquired at the time of maintenance under the user after the printer 1 is shipped.

  Assume that the printer 1 of the present embodiment performs bidirectional printing and performs a printing method in which the head unit 40 does not move in the paper width direction during the forward pass and the return pass. In the head unit 40 shown in FIG. 3, a head (for example, 41 (1)) disposed on the downstream side in the transport direction is referred to as an “odd head”, and a head (for example, 41 (1) (for example, 41 (1)) disposed on the upstream side in the transport direction. 2)) is called an “even number head”. Further, the correction value Ha of the odd-numbered head 41 during the forward pass and the correction value Hb of the even-numbered head 41 during the return pass are collectively referred to as “first correction value”. The correction value Ha at the time of the forward path is collectively referred to as a “second correction value”. Further, for the sake of simplicity of explanation, the case where four heads 41 are provided in the head unit 40 will be described as an example, as in the comparative example (FIG. 7).

<Acquisition of first correction value>
FIG. 10A is a diagram illustrating a first test pattern for calculating the first correction value (the forward path correction value Ha for the odd-numbered head and the backward path correction value Hb for the even-numbered head). As shown in FIG. 10A, ink droplets are ejected from the odd-numbered heads 41 at the designed ejection timing during the forward path so that a line is formed at the target position on the paper S. Then, in order to form a line at the same target position on the paper S, ink droplets are ejected from the even-numbered head 41 at the designed ejection timing during the return path. As a result, the forward line (corresponding to the third pattern) of the odd-numbered head 41 and the return line (corresponding to the fourth pattern) of the even-numbered head 41 are formed as the first test pattern (S001). Then, the first test pattern is read by the scanner (S002). In the printer 1 of the present embodiment, the head unit 40 during the forward pass is easily inclined clockwise with respect to the paper width direction, and the head unit 40 during the return pass is easily inclined counterclockwise with respect to the paper width direction. Therefore, the line formed during the forward pass is inclined in the clockwise direction, and the line formed during the return pass is inclined in the counterclockwise direction.

  And in the correction method of the above-mentioned comparative example (FIG. 8B), it correct | amends on the basis of the center part of the line formed by each head 41. FIG. On the other hand, in the correction method of the present embodiment, correction is performed with reference to the end portion of the line formed by the heads 41 adjacent in the paper width direction. Further, among the heads 41 adjacent to each other in the paper width direction, correction is performed to align the dot formation position by the end nozzle when the one head 41 is in the forward path and the dot formation position by the end nozzle when the other head 41 is in the backward path. Calculate the value. In summary, transport of ink droplets ejected from an end nozzle on the near side of a certain head (for example, the first head 41 (1)) among a plurality of heads arranged in the paper width direction during the forward path (first operation). Direction (moving direction) landing position, and a head (for example, the first head 41 (1)) that ejects fluid to the landing position of an ink droplet ejected from a certain head during the outward path (during the second operation) A landing position in the transport direction of the ink droplets ejected from the end nozzle on the back side (the other side) of another head (for example, the second head 41 (2)) arranged on the near side (one side) in the paper width direction; The correction value for aligning, is acquired. By doing so, the joint of the image formed on one head 41 during the forward pass and the image formed on the other head 41 during the return pass can be aligned, and image degradation can be suppressed.

  Therefore, as a result of reading the first test pattern by the scanner, the position in the transport direction of the end of the forward path line by the odd-numbered head 41 and the position in the transport direction of the end of the return line by the even-numbered head 41 are acquired (S003). The “position of the line end in the carrying direction” is the average position of the positions in the carrying direction of the dots formed on the plurality of end nozzles of the nozzle row. Here, the average position of the positions in the transport direction of the dots formed on the ten nozzles (# 1 to # 10 or # 171 to # 180) including the outermost nozzles (# 1 and # 180) in the nozzle row is calculated. To do. The first test pattern is not limited to being read by the scanner. For example, the position of each line end in the transport direction on the paper S may be measured. In addition, the correction value is not calculated based on the average position of the dot formation positions by the plurality of end nozzles (10), but the dot formation position of the outermost nozzles (# 1, # 180) in the nozzle row is used as a reference. A correction value may be calculated.

  Of the heads 41 (1) to 41 (4) arranged in the paper width direction, the reference head 41 is determined. Here, the second head 41 (2) located at the center in the paper width direction is used as a reference head. In the return line of the second head 41 (2) serving as the reference, the position in the transport direction of the line end formed on the end nozzles (# 1 to # 10) on the back side in the paper width direction is “2f”. Then, in the forward line of the first head 41 (1) aligned with the second head 41 (2) on the back side in the paper width direction, the line end formed on the end nozzles (# 171 to # 180) on the front side in the paper width direction The position in the transport direction is “1b”. In the correction method of the present embodiment, the position “1b” in the transport direction of the front end in the paper width direction of the forward path line by the first head 41 (1) and the back side in the paper width direction of the return path by the second head 41 (2). The ejection timings of the first head 41 (1) and the second head 41 (2) are corrected so that the position “2f” in the transport direction of the end portion is aligned.

  As shown in FIG. 10A, the forward line of the first head 41 (1) is formed on the downstream side in the transport direction as compared to the backward line of the second head 41 (2) serving as a reference. Therefore, only a difference “Δx1” between the position “2f” of the back end of the return path line of the second head 41 (2) and the position “1b” of the front end of the forward line of the first head 41 (1). The ejection timing of the first head 41 (1) is corrected so that the line of the first head 41 (1) is formed on the upstream side in the transport direction. That is, the ejection of the first head 41 (1) is longer than the designed ejection timing (the ejection timing of the reference second head 41 (2)) by the time required for the head unit 41 to move the “difference Δx1”. Slow timing. As a result, the dot formation position in the transport direction during the forward pass by the end nozzle on the front side in the paper width direction of the first head 41 (1) (that is, the end nozzle on the second head side) and the second head 41 (2) It is possible to align the dot formation position in the transport direction during the return pass by the end nozzle on the back side in the paper width direction (that is, the end nozzle on the first head side).

  Similarly, the position in the transport direction of the end portion on the front side in the paper width direction on the return line of the reference second head 41 (2) is “2b”, and the second head 41 (2) is aligned with the front side in the paper width direction. In the forward line of the three heads 41 (3), the position in the transport direction at the end on the far side in the paper width direction is “3f”. Then, the ejection timing of the third head 41 (3) is delayed from the designed ejection timing by the time required for the head unit 40 to move the difference “Δx2” between the line ends 2b and 3f. By doing so, the dot formation position in the transport direction during the return pass of the end nozzle on the front side in the paper width direction of the second head 41 (2) (that is, the end nozzle on the third head side) and the third head 41 (3 ) In the paper width direction depth side end nozzle (that is, the second head side end nozzle) can be aligned with the dot formation position in the transport direction during the forward path.

  FIG. 10B is a diagram illustrating a state in which the forward path line of the first head 41 (1) and the forward path line of the third head 41 (3) are corrected based on the return path line of the second head 41 (2). As described above, the line end formed from the first head 41 (1) to the third head 41 (3) by correcting the ejection timing of the first head 41 (1) and the third head 41 (3). The positions in the transport direction are aligned. Thus, after calculating the ejection timing of the first head 41 (1) and the third head 41 (3) aligned in the paper width direction with the reference second head 41 (2), the remaining fourth head 41 (4) is ejected. Timing is also calculated.

  The ejection timing of the fourth head 41 (4) so that the dot formation position of the front end nozzle of the third head 41 (3) and the dot formation position of the rear end nozzle of the fourth head 41 (4) are aligned. To decide. The position in the transport direction of the end on the back side in the paper width direction of the return path line by the fourth head 41 (4) is set to “4f”. On the other hand, the forward line by the third head 41 (3) is formed to be shifted to the upstream side in the transport direction, as shown in FIG. 10B, in accordance with the return line of the reference second head 41 (2). Therefore, the position “3b ′” of the front side end portion of the forward path line corrected by the third head 41 (3) and the position “4f” of the back side end portion of the return path line by the fourth head 41 (4) are aligned. In this way, the ejection timing of the fourth head 41 (4) is determined.

  In this way, in the heads 41 adjacent in the paper width direction, the dot formation position during the forward pass by the end nozzle of one head 41 and the dot formation position during the return pass by the end nozzle of the other head 41 are aligned. A correction value (injection timing adjustment amount) for the designed injection timing is calculated. As a result, the position in the transport direction of the end of the forward line by the odd-numbered heads 41 (1) (3) and the position in the transport direction of the end of the return path by the even-numbered heads 41 (2) (4) may be aligned. it can.

  Further, as shown in FIG. 10B, the return path line formed by the second head 41 (2) is formed on the upstream side in the transport direction from the target position. Therefore, the ejection timings of the heads 41 (1) to 41 (4) may be further corrected so that the center of the return line of the second head 41 (2) is formed at the target position. For example, suppose that the injection timing of the second head 41 (2) is delayed by a time α from the designed injection timing in order to form the central portion of the return line by the second head 41 (2) at the target position. The time α for delaying the ejection timing of the second head 41 (2) corresponds to the return correction value Hb of the second head 41 (2).

  Therefore, the ejection timing of the other head 41 determined based on the second head 41 (2) is also shifted by the time α. For example, as shown in FIG. 10A, the difference ΔX1 between the front side end portion of the forward path line by the first head 41 (1) and the back side end portion of the return path line by the second head 41 (2) is represented by the head unit 40 so far. It is assumed that the ejection timing of the first head 41 (1) is made later than the designed ejection timing by the “time T” at which the movement of the first head 41 moves. Here, when the central portion of the return line of the second head 41 (2) is shifted to the target position, the forward line of the first head 41 (1) is also shifted to the downstream side in the transport direction. For this reason, the ejection timing of the first head 41 (1) during the forward path is made to be later than the designed ejection timing by the difference “T−α” between the time T and the time α. A time T-α for delaying the ejection timing of the first head 41 (1) from the designed ejection timing corresponds to the forward path correction value Ha of the first head 41 (1). The forward path correction value Ha for the other odd-numbered heads 41 and the backward path correction value Hb for the even-numbered heads 41 are similarly calculated.

  The position of the return line of the second head 41 (2) does not have to be corrected, but the center of the return line of the second head 41 (2) serving as the reference is not limited to the target position. In this case, the “time T” for the head unit 40 to move the difference ΔX1 between the front end of the forward line by the first head 41 (1) and the back end of the return line by the second head 41 (2) is This corresponds to the forward path correction value Ha of the first head 41 (1). Further, for example, the center portion of the return line of the second head 41 (2) may be aligned with the average position in the transport direction of the center portion of the line formed in each head 41. Further, after the data corresponding to the return line by the second head 41 (2) is shifted to the target position on the data obtained by reading the first test pattern shown in FIG. 10A with the scanner, the ejection timing of the other head 41 is determined. May be.

  FIG. 10C is a diagram illustrating lines formed by correcting the ejection timing of the heads 41 (1) to 41 (4). Based on the forward path correction value Ha of the odd-numbered head 41 and the backward path correction value Hb of the even-numbered head 41 calculated in this way, the transport-direction position of the forward-line end of the odd-numbered head 41 and the transport-direction position of the backward-line end of the even-numbered head 41 Can be aligned. By doing so, it is possible to prevent a shift in the conveyance direction between the end of the image formed on the odd-numbered head 41 during the forward pass and the end of the image formed on the even-numbered head 41 during the return pass. Therefore, when the line formed in each head 41 is inclined with respect to the paper width direction due to the inclination of the head unit 40 during movement, the end of each line is shifted in the transport direction in the correction method of the comparative example (FIG. 8B). In contrast, the correction method of the present embodiment can prevent the end of each line from shifting in the transport direction. Therefore, in this embodiment, image deterioration can be suppressed as compared with the comparative example.

  FIG. 11 is a diagram illustrating a correction method of another comparative example of the dot formation position by each head 41. In another comparative example, the correction value is calculated with reference to the end of the forward line by the heads 41 (1) to 41 (4). For example, the first head 41 so that the end of the forward line of the forward line by the first head 41 (1) in the paper width direction and the end of the forward line of the forward line by the second head 41 (2) are aligned. (1) and the ejection timing of the second head 41 (2) are corrected. Similarly, the other heads 41 also correct the ejection timing of each head 41 so that the ends of the lines formed during the forward path are aligned by the heads 41 arranged in the paper width direction. In the printer 1 of the present embodiment, the head unit 40 is tilted while moving in the transport direction, and the line formed by each head 41 is tilted in the same direction (clockwise direction) during the forward path. Therefore, when the end portions of the lines in the forward path are aligned, the line formed by the entire head unit 40 is inclined clockwise with respect to the paper width direction as shown in FIG. In particular, the deviation in the transport direction between the dot formation position by the first head 41 (1) on the back side in the paper width direction and the dot formation position by the fourth head 41 (4) on the front side in the paper width direction becomes large.

  On the other hand, in the correction method of this embodiment, among the heads 41 arranged in the paper width direction, the end of the forward line of one head 41 and the end of the return line of the other head 41 are aligned. Further, as shown in FIG. 4, in the printer 1 of the present embodiment, the head unit 40 is inclined in different directions during the forward path and during the backward path, and the inclinations of the forward path line and the backward path line are different. Therefore, according to the correction method of the present embodiment, the line formed in the entire head unit 40 as shown in FIG. 10C is compared with the line (FIG. 11) formed in the entire head unit 40 according to another comparative example. Along the paper width direction. For example, even if the dot formation position of the front end nozzle of the first head 41 (1) is shifted downstream in the conveyance direction, the dot formation position of the second head 41 (2) is gradually increased in the conveyance direction. Therefore, it is possible to prevent the line formed by the entire head unit 40 from being greatly inclined with respect to the paper width direction. That is, according to the correction method of the present embodiment, the forward path line or the backward path line formed in each head 41 (1) to 41 (4) is formed at a position closer to the target position than in another comparative example. be able to. Therefore, according to the correction method of the present embodiment, image deterioration can be suppressed as compared with another comparative example.

  FIG. 12A shows lines formed when the inclination of the base plate BP with respect to the paper width direction is different between the forward pass and the return pass, and FIG. 12B is formed when the inclination with respect to the paper width direction of the base plate BP is the same during the forward pass and the return pass. Indicates the line to be played. As described above, in this embodiment, before the dot formation position is corrected by each head 41, the base plate BP adjustment mechanism shown in FIG. 6A causes the base plate BP to have the same inclination in the paper width direction during the forward pass and the return pass. is doing.

  Temporarily, without adjusting the inclination of the base plate BP, as shown in FIG. 12A, the base plate BP in the forward path is inclined at an angle θ1 in the clockwise direction with respect to the paper width direction, whereas the base plate BP in the backward path is the paper width. Suppose that it does not tilt with respect to the direction. Then, the line formed during the forward pass is inclined in the clockwise direction, and the line formed during the return pass is along the paper width direction. Then, according to the dot formation position correction method of the present embodiment, the ends of the forward path line inclined in the clockwise direction and the return path line along the paper width direction are aligned. As a result, as shown in FIG. 12A, the line formed by the entire head unit 40 is inclined relatively in the clockwise direction. This is because the forward line by the odd-numbered heads 41 is shifted downstream in the transport direction, but the return line by the even-numbered heads 41 is not inclined in the reverse direction, so the line formed by the entire head unit 40 is in the clockwise direction. It will tilt.

  On the other hand, as shown in FIG. 12B, when adjustment is made so that the inclination of the base plate BP with respect to the paper width direction in the forward pass and the return pass is equal to the opposite direction, a line formed during the forward pass and a line formed during the return pass Tilts in the opposite direction. As a result, even if the forward path line by the odd-numbered head 41 is shifted downstream in the transport direction, the backward path line by the even-numbered head 41 returns the shift. Even if the even line 41 shifts to the upstream side in the transport direction of the return line, the forward line of the odd head returns the shift. As a result, the line formed in the entire head unit 40 in FIG. 12B is less inclined with respect to the paper width direction than the line formed in the entire head unit 40 in FIG. 12A. Furthermore, in the present embodiment, the inclination θ2 with respect to the paper width direction of the base plate BP in the forward path and the backward path is equalized, so that the deviation in the transport direction downstream due to the forward path line and the shift in the transport direction upstream due to the backward path line are caused. As a result, the inclination of the line formed in the entire head unit 40 with respect to the paper width direction can be further reduced.

  That is, when the dot formation position of each head 41 is corrected so that the end of the forward path line and the end of the backward path line are aligned as in the correction method of the present embodiment, the forward path line and the backward path line are in the paper width direction. And tilt in the opposite direction. By doing so, the inclination with respect to the paper width direction of the line formed in the entire head unit 40 can be reduced, and image deterioration can be suppressed. Therefore, before acquiring the dot formation position correction value in the transport direction of each head 41, adjustment is made so that the inclination of the base plate BP with respect to the paper width direction during the forward pass and the backward pass is reversed. In addition, the inclination of the base plate BP in the paper width direction during the forward pass and the return pass is made equal, and the inclination is made as small as possible, so that the inclination of the line formed in the entire head unit 40 with respect to the paper width direction can be further reduced. .

<Acquisition of second correction value>
FIG. 13A is a diagram illustrating a second test pattern for calculating the second correction value. After calculating the first correction value that is the forward path correction value Ha of the odd-numbered head 41 and the backward path correction value Hb of the even-numbered head 41, the second correction that is the backward path correction value Hb of the odd-numbered head 41 and the forward path correction value Ha of the even-numbered head 41. In order to calculate the value, a second test pattern is formed (S005 in FIG. 9). As the second test pattern, during the forward path, the ejection timing is corrected from the odd-numbered head 41 by the forward path correction value Ha, and ink droplets are ejected to the target position on the paper S. Ink droplets are ejected to the target position. Then, during the return pass, ink droplets are ejected from the odd-numbered heads 41 to the same target position at the designed ejection timing, and the ejection timings are corrected from the even-numbered heads 41 by the return path correction value Hb to Inject. It is assumed that the head unit 40 does not move in the paper width direction between the forward path and the return path when forming the second test pattern.

  As a result, as shown in FIG. 13A, each head 41 forms a forward line (corresponding to the third pattern) and a backward line (corresponding to the fourth pattern). Then, the printed second test pattern is read by the scanner, and read data is acquired (S006). The forward line of the odd-numbered head 41 and the return line (thin line) of the even-numbered head 41 have the same line end position in the transport direction, and the deviation from the target position is small. On the other hand, the return line of the odd-numbered head 41 and the forward line (thick line) of the even-numbered head 41 are formed so as to be shifted in the transport direction.

  By the way, in the printing method of the present embodiment, the head unit 40 does not move in the paper width direction between the forward path and the backward path. Therefore, for a certain area on the medium, the head 41 that ejects ink droplets in the forward path and the head 41 that ejects ink droplets in the backward path are the same head 41. If the line formed during the forward pass and the line formed during the return pass are shifted in the transport direction in the same area on the medium, the image is deteriorated. Therefore, based on the second test pattern shown in FIG. 13A, the second correction value is determined so that the positions of the lines formed in the forward path and the backward path by the same head 41 are aligned. Here, the second correction value is determined so that the central portion of the line formed by the same head 41 in the forward path and the backward path is aligned. For this purpose, the position in the transport direction at the center of the line is acquired as a result of reading the second test pattern with the scanner (S007). In summary, an ink droplet is ejected to the dot formation position in the transport direction of the central nozzle of a certain head (for example, the first head 41 (1)) during the forward pass and to the dot formation position of a certain head during the forward pass. A second correction value (corresponding to another correction value) for aligning the dot formation position in the transport direction of the central nozzle of the head (for example, the first head 41 (1)) is calculated.

  For example, as shown in FIG. 13A, the line center formed by the second head 41 (2) during the forward pass is corrected with respect to the line center formed by the second head 41 (2) during the return pass. It is located on the downstream side in the transport direction by a distance of “Δx3”. Therefore, it is preferable to delay the ejection timing of the second head 41 (2) during the forward path from the designed ejection timing by the time required for the head unit 40 to move the distance Δx3. By doing so, the second head 41 (2) can align the position in the transport direction between the line center formed during the forward path and the line center formed during the return path. The time for delaying the ejection timing of the second head 41 during the forward path from the designed ejection timing corresponds to the forward path correction value Ha of the second head 41 (2) (S008). Similarly, with respect to the other heads 41, the second correction value (the odd-numbered head return correction value Hb and the even-numbered head return value Hb are set so that the positions in the transport direction of the central portion of the line formed by each head 41 during the forward pass and the return pass are aligned. The head forward path correction value Ha) is calculated.

  FIG. 13B is a diagram showing the forward path line and the backward path line corrected by the first correction value and the second correction value. According to the correction method of this embodiment, the positions of the end of the forward path of the odd head and the end of the return path of the even head are aligned in the transport direction, and the forward line and the backward line formed by the same head 41. The positions in the transport direction at the center of the are aligned. The first correction value and the second correction value calculated in this way are stored in the memory 13 (storage unit) of the printer 1.

  In summary, according to the dot formation position correction method of the present embodiment, in the heads 41 arranged in the paper width direction, the conveyance of the end of the forward line of one head 41 and the end of the return line of the other head 41 is performed. Align directions. Therefore, it is possible to prevent the image end portion formed on the odd-numbered head 41 during the forward pass and the image end portion formed on the even-numbered head 41 during the forward pass from being shifted in the transport direction. And the position of the conveyance direction of the center part of the outward path line by each head 41 and the center part of a return path line is arrange | equalized. For this reason, it is possible to prevent the image formed in the forward path and the image formed in the backward path in the same area on the paper S from being shifted in the transport direction. As a result, as compared with the correction method of the comparative example (FIG. 8B), the shift amount of the line end portion in the transport direction by each head 41 can be reduced.

  However, in the present embodiment, since the base plate BP is adjusted so as to incline in the opposite direction with respect to the paper width direction during the forward pass and the return pass, the forward pass line and the return pass line formed on the same head 41 are crossed as shown in FIG. 13B. Resulting in. This is the same for the lines formed by the correction method of the comparative example (FIG. 8B). However, according to the correction method of the present embodiment, the end of the forward path line of the odd-numbered head 41 and the end of the return path line of the even-numbered head 41 can be aligned, so image degradation is reduced compared to the correction method of the comparative example. Can be suppressed.

  FIG. 14 is a diagram illustrating another method for calculating the second correction value. As shown in FIG. 10C described above, after aligning the end of the forward path line of the odd-numbered head 41 and the end of the return path line of the even-numbered head 41, the second correction value (return path correction value Hb of odd-numbered head / forward path of even-numbered head) When calculating the correction value Ha), as shown in FIG. 13B, the center of the forward line and the backward line by each head 41 is not necessarily aligned. For example, when calculating the second correction value, as in the case of calculating the first correction value, the end of the line formed in the heads 41 adjacent in the paper width direction may be used as a reference. As shown in FIG. 14, a second correction value for correcting the ejection timing of each head 41 so that the positions of the return line end of the odd-numbered head 41 and the forward line end of the even-numbered head 41 in the transport direction are aligned. May be calculated). In this case, an odd-numbered head corresponds to a certain head, and an even-numbered head is a head aligned with one side in a predetermined direction with a head that ejects ink droplets during the first operation at a dot formation position of a certain head during the second operation. Equivalent to.

  By doing so, even if the head unit 40 is tilted while moving in the transport direction, the positions in the transport direction of the end of the forward line of the odd head 41 and the end of the return line of the even head 41 are aligned. The positions in the transport direction of the end of the return line of the odd-numbered head 41 and the end of the forward-line of the even-numbered head 41 are aligned. Therefore, compared with the correction method of the comparative example (FIG. 8B), according to the correction method shown in FIG. 14, among the heads 41 arranged in the paper width direction, the end portion of the image formed by one head 41 during the forward pass and the other The head 41 can prevent the edge of the image formed during the return path from shifting in the transport direction, and can suppress image deterioration.

  Heretofore, the position of the end of the forward line of the odd-numbered head 41 and the position of the end of the return-line of the even-numbered head 41 are aligned, but this is not restrictive. Conversely, the ejection timing of each head 41 may be corrected so that the position of the end of the return path line of the odd-numbered head 41 is aligned with the position of the end of the outbound path line of the even-numbered head 41.

  In the printer 1 of the present embodiment, the head unit 40 does not move in the paper width direction between the forward pass and the return pass. However, the present invention is not limited to this, and the head unit 40 may be finely fed in the paper width direction between the forward pass and the return pass. For example, the high resolution image may be printed by finely feeding the head unit 40 in the paper width direction by a half pitch of the nozzle pitch 180 dpi between the forward pass and the return pass. In this case as well, the same head 41 is used as the head that ejects ink droplets to the same region during the forward pass and the return pass. For this reason, when calculating the correction value at the time of the return pass, it is preferable to use the central portion of the line formed by the same head 41 at the time of the forward pass and the return pass as a reference.

  Also, depending on the printing method, for a certain area on the medium S, the head 41 that ejects ink droplets in the forward path and the head 41 that ejects ink droplets in the backward path may be different. For example, ink is ejected from the third head 41 (3) and the fourth head 31 (4) during a forward path to a certain area on the medium S, and then the head unit 40 moves by two heads in the paper width direction. Assume that ink droplets are ejected from the first head 41 (1) and the second head 41 (2) when returning to a certain area on the medium. In this case, the line end formed by the third head 41 (3) during the forward pass and the line end formed by the second head 41 (2) during the return pass are aligned and the third head 41 (3) during the forward pass. The correction value may be calculated so that the formed line center and the line center formed by the first head 41 (1) during the return pass are aligned.

  Further, the correction values H1 and H2 for the forward pass and the return pass may be calculated for each nozzle row YMCK (for each color) or may be calculated for each head 41. Since the color ink YMC is particularly formed by overlapping dots, even if different correction values are used for each nozzle row, dots of each color are formed in the same pixel. Further, when forming a test pattern as shown in FIG. 10A in order to calculate a correction value for each head 41, only a representative color (for example, black) may be used, or a line is formed with a plurality of colors of ink. You may do it. By forming a test pattern with a plurality of colors of ink, it is possible to calculate a correction value that takes into account the ejection characteristics of each color of ink.

=== Test Pattern Variation ===
In the test pattern described above, first, as shown in FIG. 10A, only the forward line of the odd-numbered head 41 and the return line of the even-numbered head 41 are printed, and the first correction value is set so that the positions of the line ends are aligned. Is calculated. After that, as shown in FIG. 13A, the second correction value is calculated by forming the corrected forward path line and the corrected backward line by the odd-numbered head 41 and forming the corrected forward path line by the even-numbered head 41. However, it is not limited to this. When the test pattern for calculating the second correction value is formed, only the return line by the odd-numbered head 41 and the forward line by the even-numbered head 41 may be printed without printing the line whose ejection timing is corrected. When calculating the first correction value, the position of the odd-numbered head 41 relative to the target position of the forward path line and the position of the even-numbered head 41 relative to the target position of the return path line can be grasped. Therefore, if the position of the odd-numbered head 41 with respect to the target position of the return path line and the position of the even-numbered head 41 with respect to the target position of the forward path line are acquired, the position in the transport direction of the center of the line formed by the same head 41 during the forward path and the return path Can be aligned.

  15A and 15B are diagrams showing a modification of the test pattern. A test pattern in which the forward line and the backward line of each head 41 are formed in the same printing area may be used. However, if many lines are formed with respect to the same target position on the paper S, the lines may overlap and the line position with respect to the target position may not be acquired. Therefore, two target positions 1 and 2 are provided on the sheet S. Out of the heads 41 aligned in the paper width direction with respect to the target position 1, the forward path line 1 is formed by the head 41 on the back side, and the return line 2 is formed by the head 41 on the near side. Further, with respect to the target position 2, the backward line 1 is formed by the head 41 on the back side, and the forward line 2 is formed by the head 41 on the near side.

  Based on the printed test pattern, the position in the transport direction of the end of the reference return path 2 and the end of the outbound path 1 by the back head 41 is based on the return path 2 by the head 41 on the near side. In order to align, the correction value of the ejection timing during the forward path of the head 41 on the back side is calculated. Specifically, the head 41 on the back side is formed so that the forward line 1 is formed to be shifted downstream in the transport direction by an amount d1 in the transport direction between the end of the forward line 1 and the end of the return line 2. The injection timing during the forward path is corrected. As a result, as shown in FIG. 15B, the positions of the end portions of the forward path line 1 and the backward path line 2 by the heads 41 arranged in the paper width direction are aligned, so that image deterioration can be suppressed.

  Then, the ejection timing of the back head 41 during the return pass is corrected so that the positions of the center of the forward pass line 1 corrected by the back head 41 and the center of the return pass line 1 are aligned. The corrected forward path line 1 is formed with respect to the target position 1 by being shifted to the downstream side in the transport direction by “distance d 1 -d 2”. Therefore, the ejection timing of the head 41 on the back side is set so that the return line 1 by the head 41 on the back side is formed to be shifted from the target position 2 by “distance d1-d2” to the downstream side in the transport direction. It is good to correct. Similarly, the ejection timing of the head 41 on the forward path may be corrected so that the position of the center of the return path 2 by the head 41 on the front side and the center of the forward line 2 are aligned. In addition, you may adjust so that the center part of the reference | standard return path line 2 may be located in a target position.

  In this way, by forming a test pattern on the paper S located in the same printing area and grasping the position of each line with respect to the target position, the number of times the test pattern is printed and the scanner are compared with the test pattern of the above-described embodiment. The number of readings can be reduced.

  16A and 16B are diagrams showing a modification of the test pattern. In the test pattern of FIG. 16A, the line of the head 41 on the back side and the line of the head 41 on the near side are formed in the paper width direction with respect to the same target position. First, in the forward path, the forward path line 1 by the end nozzle of the head 41 on the back side and the forward line 2 by the center nozzle of the head 41 on the near side are formed for the same target position. Then, during the return pass, the return pass line 1 by the central nozzle of the back head 41 and the return pass line 2 by the end nozzle of the front head 41 are formed for the same target position.

  Based on the printed test pattern, the correction value is calculated so that the position in the transport direction of the end of the forward path line 1 by the head 41 on the back side and the end of the return line 2 by the head 41 on the near side are aligned. . FIG. 16B is a diagram illustrating a state in which the end of the forward path line 1 and the end of the return path line 2 are aligned. Then, a correction value at the time of the return path of the head 41 on the back side is calculated so that the return path line 1 is positioned between the forward path lines 1, and the forward side line 2 is positioned between the return path lines 2. It is preferable to calculate a correction value when the head 41 travels forward.

  Thus, when aligning the end of the forward line by one head 41 of the heads 41 arranged in the paper width direction with the end of the backward line by the other head 41, the end nozzles of one head 41 are used during the forward path. Ink droplets are ejected, and ink droplets are ejected from the central nozzle of the other head 41 (that is, ink droplets are ejected from an end nozzle of a certain head, and are moved to the dot formation position of another head during the second operation). Ink droplets are ejected from the central nozzle of the head that ejects ink droplets during the first operation). Then, during the return pass, ink droplets are ejected from the central nozzle of one head 41 and ink droplets are ejected from the end nozzle of the other head 41 (that is, at the dot formation position of a certain head during the first operation). Ink droplets are ejected from the central nozzle of the head that ejects ink droplets and the end nozzle of the other head during the second operation).

  According to such a test pattern, it is possible to reduce the number of times the test pattern is printed and the number of times the scanner is read as compared with the test pattern of the above-described embodiment. Further, since the position of the forward path line and the position of the backward path line can be acquired with respect to the same target position, the correction value calculation process is facilitated. Further, the ink consumption for printing the test pattern can be reduced.

=== Other Embodiments ===
Each of the above embodiments is described mainly for a printing system having an ink jet printer, but includes disclosure of a dot formation position adjustment method and the like. The above-described embodiments are for facilitating understanding of the present invention, and are not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof. In particular, the embodiments described below are also included in the present invention.

<Adjustment of dot formation position>
As shown in FIG. 3, since the plurality of heads 41 belonging to the head unit 40 are arranged in a staggered manner, in the above-described embodiment, the heads 41 having different positions in the transport direction in consideration of the ejection characteristics of each head 41. Although the correction value for aligning the dot formation positions is calculated, the present invention is not limited to this. As shown in FIG. 5, if the inclination of the nozzle row in the forward pass with respect to the paper width direction is opposite to the inclination of the nozzle row in the return pass with respect to the paper width direction and the inclination angles are equal, Since the effect of suppressing the deviation of the raster line intervals D1 and D2 is obtained, it is not necessary to calculate a correction value for correcting the ejection timing of each head 41 by printing the test pattern shown in FIG.

  In the above-described embodiment, in the heads 41 arranged in the paper width direction, the correction value for aligning the dot formation positions of the end nozzles of one head 41 and the dot formation positions of the end nozzles of the other head 41 is calculated. However, it is not limited to this. For example, a correction value for aligning the dot formation positions of the central nozzles of each head 41 may be calculated as in the correction method of the comparative example shown in FIG. 7, or as in the correction method of another comparative example shown in FIG. In addition, a correction value that aligns the dot formation positions of the end nozzles of the heads 41 aligned in the paper width direction during the forward path (or during the backward path) may be calculated. However, in the present invention, the inclination of the nozzle row in the forward direction with respect to the paper width direction and the inclination of the nozzle row in the return pass with respect to the paper width direction are adjusted to be opposite to each other at an equal angle. Therefore, as in the correction method of the above-described embodiment, in the heads 41 arranged in the paper width direction, a correction value that aligns the dot formation positions of the end nozzles of the forward path line and the end nozzles of the return path line is calculated, and FIG. As shown, the lines formed by the entire head unit 40 are formed relatively along the paper width direction, and image deterioration can be further suppressed.

<Other printers>
In the above-described embodiment, in order to form an image on the continuous paper transported to the printing area, the head 41 intersects the transport direction with the operation of ejecting ink while the head 41 moves along the transport direction of the continuous paper. An example of a printer that repeats an operation of moving in the paper width direction and then transports continuous paper in the transport direction and transports a new paper portion to the print area is described as an example.
For example, a printer having a head in which nozzles are arranged over the width of continuous paper and the head does not move in the paper width direction may be used. In this printer, the operation of moving the head in the transport direction to form an image and the operation of transporting continuous paper in the transport direction are alternately repeated.
Further, a serial printer that alternately repeats the operation of forming a band image while moving the head in the movement direction intersecting the nozzle row direction and the operation of conveying paper in the nozzle row direction may be used.

<About fluid ejection device>
In the above-described embodiment, the ink jet printer is exemplified as the fluid ejecting apparatus, but the present invention is not limited thereto. If it is a fluid ejecting apparatus, it can be applied to various industrial apparatuses, not a printer (printing apparatus). For example, a textile printing apparatus for applying a pattern to a fabric, a display manufacturing apparatus such as a color filter manufacturing apparatus or an organic EL display, a DNA chip manufacturing apparatus for manufacturing a DNA chip by applying a solution in which DNA is dissolved to a chip, and the like. Also, the present invention can be applied. Further, not only fluid such as ink but also a fluid ejecting apparatus that ejects powder or the like may be used.
The fluid ejection method may be a piezo method in which fluid is ejected by applying a voltage to the drive element (piezo element) to expand and contract the ink chamber, or bubbles are generated in the nozzle using a heating element. It is also possible to use a thermal method in which liquid is ejected by the bubbles.

1 Printer, 10 Controller, 11 Interface section,
12 CPU, 13 memory, 14 unit control circuit,
20 transport units, 21 transport rollers,
30 drive unit, 31 X-axis stage, 32 Y-axis stage,
40 head units, 41 heads,
50 detector groups, 60 computers

Claims (8)

(1) A method for adjusting a fluid ejecting apparatus, wherein a plurality of heads each having a nozzle row in which nozzles that eject fluid to a medium are arranged in a predetermined direction are arranged at different positions in the predetermined direction,
(2) A line along the moving direction is moved by the first operation of ejecting fluid from the plurality of heads while moving the plurality of heads from one side of the moving direction to the other side with respect to the medium. Forming a first pattern aligned in a direction intersecting the direction;
(3) A line along the moving direction by a second operation of ejecting fluid from the plurality of heads while moving the plurality of heads from the other side of the moving direction to the one side with respect to the medium. Forming a second pattern arranged in a direction crossing the moving direction;
(4) A first interval that is an interval between the lines formed by two of the plurality of heads arranged apart from each other in a direction intersecting the predetermined direction based on the first pattern. Calculating
(5) A second interval that is an interval between the lines formed by two of the plurality of heads arranged apart from each other in a direction intersecting the predetermined direction based on the second pattern. Calculating
(6) Based on the first interval and the second interval, the nozzle row is inclined at an angle with respect to a direction intersecting the moving direction at the time of the first operation, and the nozzle row at the time of the second operation. Tilting in a direction opposite to the direction intersecting the moving direction;
The adjustment method characterized by having. The adjustment method according to claim 1,
In the fluid ejecting apparatus, the plurality of heads are attached to one plate,
Adjusting the inclination of the plate with respect to the direction intersecting the moving direction based on the first interval and the second interval;
Adjustment method. The adjustment method according to claim 2,
An adjustment method in which the nozzle rows of the plurality of heads attached to the plate are parallel. The adjustment method according to claim 1,
Adjusting the inclination of each head with respect to the direction intersecting the moving direction based on the first interval and the second interval;
Adjustment method. It is the adjustment method as described in any one of Claims 1-4, Comprising:
Forming a third pattern by the first operation, forming a fourth pattern by the second operation;
Based on the third pattern and the fourth pattern, the landing in the moving direction of the fluid ejected from the end nozzle on one side of the predetermined direction of a certain head among the plurality of heads in the first operation And an end on the other side of the head aligned with the one side in the predetermined direction with the head that ejects the fluid during the second operation at the position and the landing position of the fluid ejected from the certain head during the first operation A correction value for aligning the landing position in the moving direction of the fluid ejected from the part nozzle during the second operation,
Storing the correction value in a storage unit of the fluid ejection device;
Adjustment method. The adjustment method according to claim 5,
Based on the third pattern and the fourth pattern, the landing position in the moving direction of the fluid ejected from the central nozzle of the certain head during the first operation, and the certain head during the first operation Another correction for aligning the landing position of the fluid ejected during the second operation from the central nozzle of the head that ejects the fluid during the second operation at the landing position of the fluid ejected from the head Get the value
Storing the another correction value in the storage unit;
Adjustment method. The adjustment method according to claim 5,
Based on the third pattern and the fourth pattern, the landing position in the moving direction of the fluid ejected during the second operation from one end nozzle in the predetermined direction of the certain head, and the second From the head that ejects fluid during the first operation to the landing position of the fluid ejected from the certain head during operation, and the end nozzle on the other side of the head aligned on the one side in the predetermined direction, the first Obtain another correction value for aligning the landing position of the fluid ejected during operation in the movement direction,
Storing the another correction value in the storage unit;
Adjustment method. (1) A method for adjusting a fluid ejecting apparatus including a head having a nozzle row in which nozzles that eject fluid to a medium are arranged in a predetermined direction,
(2) A first line that is a line along the moving direction is formed by a first operation of ejecting fluid from the nozzle while moving the head from one side of the moving direction to the other side with respect to the medium. Forming,
(3) A second line along the moving direction by a second operation of ejecting fluid from the nozzle while moving the head from the other side of the moving direction to the one side with respect to the medium. Forming a line of
(4) Based on the position of the first line in the direction intersecting the moving direction and the position of the second line in the intersecting direction, the nozzle row in the intersecting direction during the first operation. Tilting the nozzle row in an opposite direction with respect to the intersecting direction at the angle of tilting with respect to the second operation;
The adjustment method characterized by having.

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