JP2010234599A - Liquid ejector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid ejector capable of adjusting an ejection time of a liquid ejection head according to the deviation of a carrier roller. <P>SOLUTION: A control section 180 for controlling the liquid ejector, (a) stores a correction value of an ejection cycle of a first head array 151 set according to the deviation of a first drive roller 111 in association with each of a plurality of outer peripheral sections of the first drive roller 111, (b) sequentially specifies the outer peripheral sections for delivering an ejection object in the first drive roller 111 under operation out of the plurality of outer peripheral sections of the first drive roller 111, (c) sequentially selects correction values corresponding to the sequentially specified outer peripheral sections out of the plurality of stored correction values, and (d) sequentially adjusts the ejection time of the first head array 151 according to the sequentially selected correction values. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a liquid ejection apparatus that ejects liquid onto an ejection target, and more particularly to a liquid ejection apparatus that can adjust the ejection timing of a liquid ejection head in accordance with the shake of a transport roller.

  2. Description of the Related Art Conventionally, inkjet printers, microdispensers, and the like are widely known as devices that discharge liquid onto discharge objects (hereinafter referred to as liquid discharge devices). In recent years, devices that discharge electrode materials and color materials to flat panel displays have been developed by applying these technologies. A wide variety of apparatuses exist as liquid ejection apparatuses.

  As one of such liquid ejection devices, liquid ejection heads for each color are arranged in a first direction in which an ejection target is transported, and transport rollers are arranged between the liquid ejection heads, so that a plurality of transports are performed. There is a liquid ejecting apparatus (hereinafter referred to as a first example liquid ejecting apparatus) in which a discharge target is conveyed from an upstream side to a downstream side by a roller (see, for example, Patent Document 1).

Here, the liquid discharge head of each color has a plurality of nozzles arranged in a second direction orthogonal to the first direction on the discharge target surface of the discharge target.
Further, in order to widen the width of the discharge area or to discharge at high speed, a liquid discharge apparatus (hereinafter referred to as a second example liquid discharge apparatus) in which the discharge area is shared by a plurality of liquid discharge heads arranged in a staggered arrangement. (Refer to Patent Document 2, for example).

JP 11-348313 A Japanese Patent Laid-Open No. 2002-210942

  However, in the first example of the liquid ejection device, when the transport roller is eccentric, the amount of the ejection target to be delivered increases or decreases. For this reason, even if the liquid is ejected at a constant cycle, the interval between the liquids that have landed on the surface to be ejected of the ejection target is not constant. That is, the landing position of the liquid on the discharge target surface is shifted.

  In view of this point, for example, in the second liquid ejection device, as in the first liquid ejection device, a plurality of transport rollers sandwich the row of liquid ejection heads arranged in the second direction, and the first Is arranged in the direction of. In this case, if each transport roller is decentered, the landing position shifts significantly in the ejection results for the partial areas handled by each liquid ejection head. Further, the connection of contents between adjacent partial areas on the surface to be ejected becomes unnatural.

  Therefore, in view of the above problems, the present invention provides a substantially constant interval with respect to the partial area that each liquid discharge head is responsible for even when the transport roller is eccentric when the discharge area is shared by a plurality of liquid discharge heads. An object of the present invention is to provide a liquid ejection apparatus capable of obtaining a ejection result in which liquid is landed and the contents of adjacent partial areas on the ejection target surface are naturally connected.

In order to achieve the above object, a liquid ejection apparatus according to the present invention has the following characteristics.
(CL1) A liquid discharge apparatus according to the present invention includes: (a) a liquid discharge head in which a plurality of nozzles for discharging liquid are arranged; a first transport roller disposed upstream of the liquid discharge head; A liquid discharge device that discharges liquid onto a discharge target that is transported from the first transport roller to the second transport roller, the second transport roller being disposed downstream of the liquid discharge head. And (b) a swing of the first transport roller in association with each of a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number with reference to the outer periphery reference position of the first transport roller. Storage means for storing a correction value of the discharge period of the liquid discharge head set in accordance with the above, (c) the first transport roller in operation from among a plurality of outer peripheral sections of the first transport roller The outer periphery for delivering the discharge object in A first outer peripheral section specifying means for sequentially specifying the interval, and (d) corresponding to the outer peripheral section sequentially specified by the first outer peripheral section specifying means from among a plurality of correction values stored in the storage means Selection means for sequentially selecting correction values to be performed, and (e) an adjustment means for sequentially adjusting the ejection timing of the liquid ejection head according to the correction values sequentially selected by the selection means.

  (CL2) In the liquid ejection device according to (CL1), (a) a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number based on the outer periphery reference position of the second transport roller. A second outer peripheral section specifying means for sequentially specifying an outer peripheral section for sending out the discharge target in the second transport roller in operation; and (b) the storage means is adapted to shake the second transport roller. The correction value of the discharge period of the liquid discharge head set accordingly is stored in association with each of the plurality of outer peripheral sections of the second transport roller, and (c) the selection means is stored in the storage means The correction value corresponding to the outer periphery section sequentially specified by the second outer periphery section specifying means is selected from the plurality of correction values.

  (CL3) The liquid discharge apparatus according to (CL2) includes (a) a transfer position specifying unit that sequentially specifies a transfer position of the discharge target during transfer, and (b) the selection unit is configured to transfer the transfer position. The correction value corresponding to the outer peripheral section sequentially specified by the first outer peripheral section specifying means and the second outer peripheral section specifying means are sequentially determined according to the transport position of the ejection target object sequentially specified by the specifying means. Any one of the correction values corresponding to the specified outer peripheral section is sequentially selected.

  (CL4) In the liquid ejection device according to any one of (CL1) to (CL3), (a) the second conveyance roller is separated from the first conveyance roller by a distance that is an integral multiple of the outer peripheral length of the first conveyance roller. (B) the first conveyance roller so that the phase of the fluctuation period related to the shake of the first conveyance roller matches the phase of the fluctuation period related to the vibration of the second conveyance roller. The outer peripheral reference position of the roller and the outer peripheral reference position of the second transport roller are adjusted.

  According to the present invention, it is possible to adjust the ejection cycle of the liquid ejection head using a correction value set according to the deflection of each transport roller. As a result, it is possible to obtain a discharge result in which liquid is landed on each partial area at a substantially constant interval, and the contents of the adjacent partial areas on the discharge target surface are naturally connected.

It is a side view which shows the liquid discharge apparatus in embodiment. It is a top view which shows the printing mechanism in embodiment. It is a schematic diagram which shows arrangement | positioning of the line-type inkjet head in embodiment. It is a schematic diagram which shows arrangement | positioning of the various sensors in embodiment. It is a schematic diagram which shows the function structure of the control part in embodiment. It is a schematic diagram which shows the fluctuation period regarding the conveyance amount of each drive roller in embodiment. (A)-(C) is a schematic diagram which shows the influence which appears in a printing result by eccentricity of a drive roller. It is a schematic diagram which shows the measuring jig in embodiment. It is a figure which shows the measurement result of the measuring object roller in embodiment. It is a figure which shows the 1st correction table in embodiment. It is a schematic diagram which shows the installation conditions of each drive roller in embodiment. It is a schematic diagram which shows the measuring method which measures the shake of each drive roller in the modification of embodiment.

(Embodiment)
Embodiments according to the present invention will be described below.
<Overview>
The liquid ejection device in the present embodiment has the following characteristics.

  (1) The liquid ejection apparatus includes: (a) a liquid ejection head in which a plurality of nozzles that eject liquid are arranged; a first transport roller disposed upstream of the liquid ejection head; and a downstream side of the liquid ejection head A liquid ejecting apparatus that ejects liquid onto an ejection target that is transported from the first transport roller to the second transport roller. The liquid discharge head of the liquid discharge head set in accordance with the deflection of the first transport roller is associated with each of a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number based on the outer periphery reference position of the transport roller. A storage function for storing a correction value of the discharge period; and (c) a first step of sequentially specifying an outer peripheral section for sending an ejection target object in the first transport roller in operation from a plurality of outer peripheral sections of the first transport roller. 1 peripheral section identification function and (d) storage function A selection function for sequentially selecting correction values corresponding to the outer peripheral sections sequentially specified by the first outer peripheral section specifying function from among the plurality of stored correction values, and (e) a correction selected sequentially by the selection function And an adjustment function for sequentially adjusting the discharge timing of the liquid discharge head according to the value.

  (2) The liquid ejecting apparatus is configured such that (a) the second transport in operation from among a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number based on the outer periphery reference position of the second transport roller. A second outer peripheral section specifying function for sequentially specifying the outer peripheral section for sending the discharge target in the roller, and (b) the storage function of the discharge cycle of the liquid discharge head set in accordance with the shake of the second transport roller The correction value is stored in association with each of the plurality of outer peripheral sections of the second transport roller, and (c) the second outer peripheral section is selected from the plurality of correction values stored in the storage function by the selection function. A correction value corresponding to the outer peripheral section sequentially specified by the specific function is selected.

  (3) The liquid discharge apparatus includes (a) a transfer position specifying function that sequentially specifies the transfer position of the discharge target being transferred, and (b) a discharge target that is sequentially specified by the transfer position specifying function. The correction value corresponding to the outer peripheral section sequentially specified by the first outer peripheral section specifying function and the correction value corresponding to the outer peripheral section sequentially specified by the second outer peripheral section specifying function according to the transport position Select sequentially.

  (4) In the liquid ejection device, (a) the second conveyance roller is separated from the first conveyance roller by a distance that is an integral multiple of the outer peripheral length of the first conveyance roller, and (b) the first conveyance roller The outer periphery reference position of the first transport roller and the outer periphery reference position of the second transport roller are adjusted so that the phase of the variation period related to the shake and the phase of the change period related to the shake of the second transport roller are matched. Yes.

  Based on the above points, the liquid ejection apparatus according to the present embodiment will be described using an inkjet printing apparatus as an example. Note that in an inkjet printing apparatus, a discharge target is paper, and a liquid discharged to the discharge target is ink.

<Configuration>
Here, as an example, as shown in FIG. 1, the liquid ejecting apparatus 100 is a printing apparatus that ejects aqueous ink onto a sheet by an inkjet method. One or more sheets 50 stacked on the sheet feeding table 101 are supplied to the printing mechanism 103 by the sheet feeding mechanism 102 one by one. A raster image is printed on the paper 50 supplied to the printing mechanism 103. The paper 50 on which the raster image is printed is discharged to the paper receiving tray 105 via the paper discharge mechanism 104.

Hereinafter, the surface of the paper 50 is referred to as a printing surface. When the printing mechanism 103 is viewed from the paper discharge side, the left side is the front and the right side is the back.
<Printing mechanism 103>
As illustrated in FIG. 2, the printing mechanism 103 includes a first conveyance roller unit 110, a second conveyance roller unit 120, and a third conveyance roller unit 130 on the frame 106 of the printing mechanism 103 in order from the paper feeding side. Installed. A plurality of line-type inkjet heads 150 are installed above the conveyance guide unit 140. A single raster image is printed by a plurality of line-type inkjet heads 150 on a sheet conveyed from the sheet feeding side to the sheet discharging side.

<First conveying roller unit 110>
The first transport roller unit 110 includes a first drive roller 111 and a first driven roller 112 that forms a pair with the first drive roller 111. The first drive roller 111 is disposed on the back side of the paper being transported and actively rotates in the direction of feeding the paper in the paper transport direction. The first driven roller 112 is disposed on the front side of the paper being transported, and passively rotates in the direction of feeding the paper in the paper transport direction following the rotation of the first drive roller 111. .

<Second conveying roller unit 120>
The second conveying roller unit 120 includes a second driving roller 121 and a second driven roller 122 that forms a pair with the second driving roller 121. The second drive roller 121 is disposed on the back side of the sheet being conveyed and actively rotates in the direction of feeding the sheet in the sheet conveyance direction. The second driven roller 122 is disposed on the front surface side of the paper being transported, and passively rotates in the direction of feeding the paper in the paper transport direction following the rotation of the second drive roller 121. .

<Third conveying roller unit 130>
The third transport roller unit 130 includes a third drive roller 131 and a third driven roller 132 that forms a pair with the third drive roller 131. The third drive roller 131 is disposed on the back side of the sheet being conveyed, and actively rotates in the direction of feeding the sheet in the sheet conveyance direction. The third driven roller 132 is disposed on the front side of the sheet being conveyed, and passively rotates in the direction of feeding the sheet in the sheet conveyance direction following the rotation of the third drive roller 131. .

<Conveyance guide unit 140>
The conveyance guide unit 140 guides the paper supplied from the paper supply side to the paper discharge side. It is installed on the frame 106 of the printing mechanism 103 and is arranged below each line-type inkjet head 150 during printing to support the paper conveyed in the paper conveyance direction.

<Line-type inkjet head 150>
Further, in the printing mechanism 103, three line-type inkjet heads 150 are installed in a portion (hereinafter referred to as a pre-stage portion) between the first conveyance roller unit 110 and the second conveyance roller unit 120. . Three line-type inkjet heads 150 are installed in a portion between the second conveyance roller unit 120 and the third conveyance roller unit 130 (hereinafter referred to as a subsequent portion). The maximum printable range is shared and printed by a total of six line-type inkjet heads 150.

  Here, the maximum printable range is the maximum range that can be printed by the printing mechanism 103. For each of the front part and the rear part, the length (size in the paper conveyance direction) is longer than the length (size in the paper conveyance direction) of the smallest size paper (hereinafter referred to as the smallest paper that can be conveyed). short. The width (size in the paper width direction) is wider than the width (size in the paper width direction) of the maximum size paper that can be carried (hereinafter referred to as the maximum carryable paper).

  Each line type inkjet head 150 ejects a plurality of colors by one. A plurality of nozzles (not shown) of the same color are arranged above the conveyance guide unit 140 so that a plurality of nozzles (not shown) of each color are arranged in the paper conveyance direction. During printing, it is used in a state of being fixed above the conveyance guide section 140. Here, as an example, it is assumed that the maximum printable range is divided in the paper width direction in units of partial print areas as viewed from the paper discharge side.

  In this case, as shown in FIG. 3, three line-type ink jet heads 150 (hereinafter referred to as first head rows 151) installed in the front stage are individually arranged above the odd-numbered areas. Responsible for printing odd areas. Three line-type inkjet heads 150 (hereinafter referred to as second head rows 152) installed in the rear stage are individually arranged above the even area and are responsible for printing the even area.

  Here, the partial printing region is a range that can be printed by one line-type inkjet head 150 on the printing surface. The odd area is an odd-numbered partial print area (partial print area 1, partial print area 3, partial print area 5, etc. in the figure) of the maximum printable range counted from the front. The even-numbered area is an even-numbered partial print area (partial print area 2, partial print area 4, partial print area 6, etc. in the figure) of the maximum printable range counted from the front.

<Various sensors>
As shown in FIG. 4, the printing mechanism 103 is provided with a paper leading edge detection sensor 170 above the paper feed side. A first outer reference position detection sensor 171 is installed in the vicinity of the first drive roller 111. A second outer reference position detection sensor 172 is installed in the vicinity of the second drive roller 121. A third outer reference position detection sensor 173 is installed in the vicinity of the third drive roller 131.

<Paper leading edge detection sensor 170>
The paper leading edge detection sensor 170 is a sensor that detects the leading edge of the paper being conveyed. Here, as an example, a reflective photosensor including a light emitting element 170a and a light receiving element 170b. A light emitting element 170a and a light receiving element 170b are arranged so as to face the surface of the sheet supplied from the sheet feeding mechanism 102. Light is emitted from the light emitting element 170a. The light is reflected by a reflector (not shown) installed below the light emitting element 170a and the light receiving element 170b. Light reflected by a reflecting plate (not shown) is received by the light receiving element 170b. When paper is supplied from the paper feed mechanism 102 and the leading edge of the paper passes between the light emitting element 170a and a reflector (not shown), the light emitted from the light emitting element 170a is scattered at the leading edge of the paper. When the light is scattered at the leading edge of the sheet and no longer receives light at the light receiving element 170b, a detection signal indicating that the leading edge of the sheet has been detected is output to the control unit 180.

<First outer reference position detection sensor 171>
The first outer periphery reference position detection sensor 171 is a sensor that detects the outer periphery reference position of the rotating first drive roller 111. Here, as an example, a reflective photosensor including a light emitting element 171a, a light receiving element 171b, and a reflecting plate 171c. A reflecting plate 171c is attached to the side surface of the driven gear 113 attached to one end of the first driving roller 111 in accordance with the outer peripheral reference position (black triangle in the figure). The light emitting element 171a and the light receiving element 171b are arranged so as to face the lower part of the side surface (side surface part in the 6 o'clock direction) of the driven gear 113 to which the reflecting plate 171c is attached. Light is emitted from the light emitting element 171a to the side surface of the rotating driven gear 113. When the reflecting plate 171c rotating together with the driven gear 113 is positioned in the 6 o'clock direction, the light emitted from the light emitting element 171a is reflected by the reflecting plate 171c. When the light reflected by the reflecting plate 171c is received by the light receiving element 171b, a detection signal indicating that the outer peripheral reference position has been detected is output to the control unit 180.

<Second outer periphery reference position detection sensor 172>
The second outer reference position sensor 172 is a sensor that detects the outer reference position of the rotating second drive roller 121. Here, as an example, a reflective photosensor including a light emitting element 172a, a light receiving element 172b, and a reflecting plate 172c. A reflecting plate 172c is attached to the side surface of the driven gear 123 attached to one end of the second drive roller 121 in accordance with the outer peripheral reference position (black triangle in the figure). The light emitting element 172a and the light receiving element 172b are arranged so as to face the lower side surface (side surface portion in the 6 o'clock direction) of the driven gear 123 to which the reflecting plate 172c is attached. Light is emitted from the light emitting element 172a to the side surface of the rotating driven gear 123. When the reflecting plate 172c rotating together with the driven gear 123 is positioned in the 6 o'clock direction, the light emitted from the light emitting element 172a is reflected by the reflecting plate 172c. When the light reflected by the reflecting plate 172c is received by the light receiving element 172b, a detection signal indicating that the outer peripheral reference position has been detected is output to the control unit 180.

<Third outer peripheral reference position detection sensor 173>
The third outer circumference reference position detection sensor 173 is a sensor that detects the outer circumference reference position of the rotating third drive roller 131. Here, as an example, a reflective photosensor including a light emitting element 173a, a light receiving element 173b, and a reflecting plate 173c. A reflecting plate 173c is attached to the side surface of the driven gear 133 attached to one end of the third drive roller 131 in accordance with the outer peripheral reference position (black triangle in the figure). The light emitting element 173a and the light receiving element 173b are arranged so as to face the lower side surface (side surface portion in the 6 o'clock direction) of the driven gear 133 to which the reflecting plate 173c is attached. Light is emitted from the light emitting element 173a to the side surface of the rotating driven gear 133. When the reflecting plate 173c rotating together with the driven gear 133 is positioned in the 6 o'clock direction, the light emitted from the light emitting element 173a is reflected by the reflecting plate 173c. When the light reflected by the reflecting plate 173c is received by the light receiving element 173b, a detection signal indicating that the outer peripheral reference position has been detected is output to the control unit 180.

<Control unit 180>
Next, the control unit 180 that controls the printing mechanism 103 will be described.
As shown in FIG. 5, the control unit 180 includes an image storage unit 181, a correction value storage unit 182, and a discharge adjustment unit 183.

<Image storage unit 181>
The image storage unit 181 includes a first partial image storage unit 181a and a second partial image storage unit 181b.

<First Partial Image Storage Unit 181a>
The first partial image storage unit 181a is an odd area (the partial print area 1, the partial print area 3, the partial print area 5 and the like in FIG. 3) in one raster image that the first head row 151 is responsible for printing. The image data is stored.

<Second Partial Image Storage Unit 181b>
The second partial image storage unit 181b is an even area (the partial print area 2, the partial print area 4, the partial print area 6 and the like in FIG. 3) that the second head row 152 is responsible for printing in one raster image. The image data is stored.

<Correction value storage unit 182>
The correction value storage unit 182 includes a first correction table storage unit 182a, a second correction table storage unit 182b, and a third correction table storage unit 182c.

<First Correction Table Storage Unit 182a>
The first correction table storage unit 182a stores a first correction table. The first correction table is a table in which correction values for correcting the ejection cycle of the line-type inkjet head 150 are registered in association with the outer peripheral section of the first drive roller 111. Here, the outer peripheral section of the first drive roller 111 is a section obtained by dividing the outer periphery of the first drive roller 111 by a predetermined number with the outer reference position as a reference.

<Second Correction Table Storage Unit 182b>
The second correction table storage unit 182b stores a second correction table. The second correction table is a table in which correction values for correcting the ejection cycle of the line-type inkjet head 150 are registered in association with the outer peripheral section of the second drive roller 121. Here, the outer peripheral section of the second drive roller 121 is a section obtained by dividing the outer periphery of the second drive roller 121 by a predetermined number with respect to the outer reference position.

<Third Correction Table Storage Unit 182c>
The third correction table storage unit 182c stores a third correction table. The third correction table is a table in which correction values for correcting the ejection cycle of the line-type inkjet head 150 are registered in association with the outer peripheral section of the third drive roller 131. Here, the outer peripheral section of the third drive roller 131 is a section obtained by dividing the outer periphery of the third drive roller 131 by a predetermined number with reference to the outer reference position.

<Discharge adjustment unit 183>
The discharge adjustment unit 183 includes a first outer periphery section specifying unit 183a, a second outer periphery section specifying unit 183b, a third outer periphery section specifying unit 183c, a first correction value search unit 183d, and a second correction. Value search unit 183e, third correction value search unit 183f, transport position specifying unit 183g, first correction value selection unit 183h, second correction value selection unit 183i, and first head row adjustment unit 183j and a second head row adjustment unit 183k.

<First outer circumference section specifying unit 183a>
The first outer periphery section specifying unit 183a sequentially determines the outer periphery section that contributes to sending out the sheet by contacting the back surface of the sheet in the plurality of outer periphery sections of the first drive roller 111. Specifically, a pulse signal supplied to a stepping motor 115 (for example, see FIG. 4) that drives the first drive roller 111 via the drive gear 114 and the first outer reference position detection sensor 171. From the output detection signal, the outer peripheral position located in the 12 o'clock direction is calculated. The outer circumference section to which the calculated outer circumference position belongs is specified. The identification code assigned to the identified outer peripheral section is output to the first correction value search unit 183d.

<Second outer periphery section specifying unit 183b>
The second outer peripheral section specifying unit 183b sequentially specifies the outer peripheral sections that contribute to sending out the paper in contact with the back surface of the paper in the plurality of outer peripheral sections of the second drive roller 121. Specifically, a pulse signal supplied to a stepping motor 125 (see, for example, FIG. 4) that drives the second drive roller 121 via the drive gear 124 and the second outer reference position detection sensor 172. From the output detection signal, the outer peripheral position located in the 12 o'clock direction is calculated. The outer circumference section to which the calculated outer circumference position belongs is specified. The identification code assigned to the identified outer peripheral section is output to the second correction value search unit 183e.

<Third outer peripheral section specifying unit 183c>
The third outer peripheral section specifying unit 183c sequentially specifies the outer peripheral sections that contribute to sending out the paper in contact with the back surface of the paper in the plurality of outer peripheral sections of the third drive roller 131. Specifically, a pulse signal supplied to a stepping motor 135 (see, for example, FIG. 4) that drives the third drive roller 131 via the drive gear 134 and the third outer reference position detection sensor 173. From the output detection signal, the outer peripheral position located in the 12 o'clock direction is calculated. The outer circumference section to which the calculated outer circumference position belongs is specified. The identification code assigned to the identified outer peripheral section is output to the third correction value search unit 183f.

<First Correction Value Search Unit 183d>
The first correction value search unit 183d sequentially corresponds to the identification code (outer peripheral section) output from the first outer peripheral section specifying unit 183a from among a plurality of correction values registered in the first correction table. Select the correction value attached. The selected correction value is output to the first correction value selection unit 183h.

<Second Correction Value Search Unit 183e>
The second correction value search unit 183e sequentially corresponds to the identification code (outer peripheral section) output from the second outer peripheral section specifying unit 183b from among a plurality of correction values registered in the second correction table. Select the correction value attached. The selected correction value is output to the first correction value selection unit 183h and the second correction value selection unit 183i.

<Third Correction Value Search Unit 183f>
The third correction value search unit 183f sequentially corresponds to the identification code (outer peripheral section) output from the third outer peripheral section specifying unit 183c from among a plurality of correction values registered in the third correction table. Select the correction value attached. The selected correction value is output to the second correction value selection unit 183i.

<Conveying position specifying unit 183g>
The transport position specifying unit 183g sequentially specifies the front end position and the end position of the paper being transported. Specifically, the leading edge position of the sheet moved after the leading edge of the sheet is detected from the pulse signal supplied to the stepping motor that drives each driving roller and the detection signal output from the leading edge detection sensor 170 is obtained. calculate. The end position of the paper is calculated from the calculated leading edge position and the paper size. The calculated leading edge position and trailing edge position of the sheet are output to the first correction value selection unit 183h and the second correction value selection unit 183i.

<First Correction Value Selection Unit 183h>
The first correction value selection unit 183h sequentially determines whether or not the leading edge of the sheet has reached the first drive roller 111 based on the leading edge position and the trailing edge position output from the transport position specifying part 183g. . It is also determined whether or not the leading edge of the paper has reached the second drive roller 121. Further, it is determined whether or not the end of the sheet has reached the second drive roller 121.

  As a result of the determination, when the leading edge of the paper reaches the first driving roller 111, the first correction value selection unit 183h performs the first correction until the leading edge of the paper reaches the second driving roller 121. The correction value selected by the value search unit 183d is output to the first head row adjustment unit 183j. When the leading edge of the sheet reaches the second drive roller 121, the correction value selected by the second correction value search unit 183e is used as the first correction value until the end of the sheet reaches the second drive roller 121. The data is output to the head row adjustment unit 183j.

<Second Correction Value Selection Unit 183i>
The second correction value selection unit 183i sequentially determines whether or not the leading edge of the sheet has reached the second driving roller 121 based on the leading edge position and the trailing edge position output from the transport position specifying part 183g. . Further, it is determined whether or not the leading edge of the sheet has reached the third drive roller 131. Further, it is determined whether or not the end of the sheet has reached the third drive roller 131.

  As a result of the determination, when the leading edge of the paper reaches the second driving roller 121, the second correction value selection unit 183i performs the second correction until the leading edge of the paper reaches the third driving roller 131. The correction value selected by the value search unit 183e is output to the second head row adjustment unit 183k. When the leading edge of the paper reaches the third driving roller 131, the correction value selected by the third correction value search unit 183f is used as the second correction value until the trailing edge of the paper reaches the third driving roller 131. The data is output to the head row adjustment unit 183k.

<First Head Row Adjustment Unit 183j>
The first head row adjustment unit 183j performs ink ejection timing, ejection amount, ejection time, and the like related to the first head row 151 according to the first partial image stored in the first partial image storage unit 181a. Adjust. Further, the ink ejection timing is sequentially corrected with the correction value output from the first correction value selection unit 183h.

<Second Head Row Adjustment Unit 183k>
The second head row adjustment unit 183k performs ink ejection timing, ejection amount, ejection time, and the like related to the second head row 152 in accordance with the second partial image stored in the second partial image storage unit 181b. Adjust. Further, the ink ejection timing is sequentially corrected with the correction value output from the second correction value selection unit 183i.

<Measures for eccentricity of each transport roller>
Next, a countermeasure for the eccentricity of each conveyance roller unit will be described. Here, only the driving roller will be described, and the description of the driven roller will be omitted. This is because even if the landing position is shifted due to the eccentricity of the driving roller, the landing position is hardly shifted due to the eccentricity of the driven roller. In other words, the driven roller rotates passively following the rotation of the drive roller. In other words, the driven roller only presses the sheet in the conveyance of the sheet, and does not actively contribute to the conveyance. For this reason, even if the deviation of the landing position is affected by the eccentricity of the driving roller, it is hardly influenced by the eccentricity of the driven roller.

  Each drive roller has a distorted outer peripheral shape or a rotational axis deviated from the central axis, so that the distance from the rotational axis to the outer periphery is not constant over the entire periphery but changes according to the outer peripheral position. Hereinafter, the distance from the central axis to the rotation axis is referred to as an eccentric distance. The distance from the central axis to the outer periphery is called the reference radius. The distance from the rotation axis to the outer periphery is called the eccentric radius.

  Here, as an example, it is assumed that each drive roller is manufactured in the same manufacturing lot. This is because the drive rollers manufactured in the same manufacturing lot are eccentric with the same tendency.

As shown in FIG. 6, the first drive roller 111 is a perfect circle having a reference radius Ra, and the rotation axis (intersection of dotted lines in the figure) is shifted from the center axis (black point in the figure) by an eccentric distance d. , eccentric radius R ₁ from the axis of rotation to the outer periphery in which changes according to not without peripheral position constant at the entire circumference. Further, it rotates at a constant rotational speed ω. For this reason, as shown in the graph 184a, the transport amount R ₁ ωt of the first drive roller 111 varies between (Ra ± d) ωt according to the outer peripheral position of the first drive roller 111.

  The second drive roller 121 and the third drive roller 131 are also substantially the same as the first drive roller 111 and rotate at substantially the same rotational speed ω as the first drive roller 111. That is, the shake / rotation speed of the second drive roller 121 is substantially the same as the shake / rotation speed of the first drive roller 111. Similarly, the shake / rotation speed of the third drive roller 131 is substantially the same as the shake / rotation speed of the first drive roller 111.

For this reason, as shown in the graphs 184a and 184b, the fluctuation cycle of the transport amount R ₂ ωt of the second drive roller 121 is substantially the same as the fluctuation cycle of the transport amount R ₁ ωt of the first drive roller 111. Further, as shown in the graphs 184a and 184c, the fluctuation cycle of the transport amount R ₃ ωt of the third drive roller 131 is substantially the same as the fluctuation cycle of the transport amount R ₂ ωt of the second drive roller 121.

  However, even if these fluctuation periods are substantially the same, if the phases of these fluctuation periods are different, the paper being conveyed is loosened or pulled. This is because, in one cycle, the difference between these transport amounts increases and decreases, and a constant tension is not always applied to the sheet. For example, the outer periphery reference position of the first drive roller 111 is aligned with the 6 o'clock direction, the outer periphery reference position of the second drive roller 121 is aligned with the 9 o'clock direction, and the third outer periphery reference position is aligned with the 12 o'clock direction. Each of them is assumed to be installed on the frame 106 of the printing mechanism 103.

In this case, as shown in the graph 185a, the transport amount difference (R ₁ −R ₂ ) ωt becomes negative at time 0-3π / 4, 7π / 4-2π, and the paper is pulled. become. At the time 3π / 4-7π / 4 or the like, the difference in transport amount (R ₁ −R ₂ ) ωt becomes positive, and the sheet becomes loose. Further, as shown in the graph 185b, at the time 0-π / 4, 5π / 4-2π, etc., (R ₂ −R ₃ ) ωt becomes negative, and the paper is pulled. At time π / 4-5π / 4 or the like, the difference in transport amount (R ₂ −R ₃ ) ωt becomes positive, and the sheet becomes loose.

  Furthermore, when the paper being conveyed is loosened or pulled, the landing position is shifted and print quality is deteriorated. Further, even if an attempt is made to adjust the discharge timing in order to eliminate the deviation of the landing position, the difference in the transport amount changes, so that the adjustment of the discharge timing becomes complicated. In particular, as the sheet is transported at a high speed, that is, as the rotational speed ω increases, the difference in the transport amount increases, and these problems become more prominent.

  Therefore, in order to easily adjust the discharge timing, it is preferable to make the difference between the conveyance amount of the first drive roller 111 and the conveyance amount of the second drive roller 121 substantially constant. The same applies to the difference between the transport amount of the second drive roller 121 and the transport amount of the third drive roller 131.

  In addition, odd-numbered areas are printed by the first head row 151, and even-numbered areas are printed by the second head row 152. The driving roller that affects the conveyance of the sheet is the first driving roller 111 in the first head row 151, and the second driving roller 121 in the second head row 152. For this reason, if the phase of the fluctuation period regarding the conveyance amount of the second drive roller 121 is different from the phase of the fluctuation period regarding the conveyance amount of the first drive roller 111, the connection between the odd-numbered area and the even-numbered area becomes poor.

  For example, it is assumed that each drive roller rotates at a predetermined rotation angle. Assume that one line of ink is ejected from the line-type inkjet head 150 at a predetermined cycle. In this case, if each drive roller is not decentered, as shown in FIG. 7A, a continuous line connected at the boundary of each partial print area is printed on the paper 50 at a constant interval.

  However, if each drive roller is eccentric and the phase of the fluctuation period related to the conveyance amount of the second drive roller 121 is different from the phase of the fluctuation period related to the conveyance amount of the first drive roller 111, FIG. As described above, a line interrupted at the boundary of each partial print area is printed on the paper 50. Furthermore, the distance between the lines becomes narrower or wider.

  Therefore, in order to make the difference between these conveyance amounts substantially constant, the phase of the fluctuation period related to the conveyance amount of the first drive roller 111 and the phase of the fluctuation period related to the conveyance amount of the second drive roller 121 are matched. In addition, the first drive roller 111 and the second drive roller 121 are adjusted. Further, the second drive roller 121 and the third drive roller are matched so that the phase of the fluctuation period related to the conveyance amount of the second drive roller 121 matches the phase of the fluctuation period related to the conveyance amount of the third drive roller 131. 131.

  If each drive roller is eccentric and the phase of the fluctuation period related to the conveyance amount of the second drive roller 121 is the same as the phase of the fluctuation period related to the conveyance amount of the first drive roller 111, FIG. As shown in FIG. 5, a continuous line is printed on the paper 50 at the boundary between the partial print areas. However, the distance between the lines becomes narrower or wider.

  However, the interval between the lines can be made substantially constant by adjusting the discharge timing of the line-type inkjet head 150 by delaying or advancing the discharge timing. For example, if the eccentric radius of the drive roller is larger than the reference radius, the distance between the lines tends to increase. For this reason, what is necessary is just to adjust discharge timing in the direction which shortens a discharge period. On the other hand, if the eccentric radius of the drive roller is smaller than the reference radius, the distance between the lines tends to be narrowed. For this reason, what is necessary is just to adjust discharge timing in the direction which lengthens a discharge period.

<Measurement jig>
Next, a description will be given of a jig used when calculating a correction value according to the deflection of each drive roller.

As shown in FIG. 8, the measurement jig 190 is a jig used when measuring the deflection of the drive roller. A measurement reference roller 191 and a rotary encoder 192 are provided.
The measurement reference roller 191 has a substantially constant distance from the rotation axis to the outer periphery as viewed from the rotation axis direction, and is driven by a tension spring 193 suspended in a state where the rotation axis can move up and down. Laura.

  The rotary encoder 192 includes a slit disk 192a attached to one end of the rotation shaft of the measurement reference roller 191 and a photo interrupter 192b, and outputs a pulse signal according to the rotation angle of the measurement reference roller 191.

  The measuring jig 190 is used by attaching a driving roller to be measured (hereinafter referred to as a measuring roller 195) to the stepping motor 194. The measurement reference roller 191 is disposed in the 12 o'clock direction of the measurement target roller in a state where the measurement reference roller 191 is in contact with the outer periphery of the measurement target roller 195. A pulse signal is supplied to the stepping motor 194.

  Along with this, the stepping motor 194 is driven to rotate the measurement target roller 195. Following the rotation of the measurement target roller 195, the measurement reference roller 191 rotates. At this time, the measurement reference roller 191 moves up and down according to the eccentric radius of the measurement target roller 195. A pulse signal is output from the rotary encoder 192 according to the rotation angle of the measurement reference roller 191.

<Correction value calculation procedure>
Next, a procedure for calculating a correction value using the measurement jig 190 will be described. Here, it is assumed that each outer peripheral section of the measuring object roller 195 is specified from the pulse signal supplied to the stepping motor 194.

  First, for each outer peripheral section, pulses included in the pulse signal output from the rotary encoder 192 are counted by a measuring device (not shown) such as a pulse counter. Based on (Equation 1) below, a correction value for each outer peripheral section is calculated.

(Expression 1) Coefficient × (Reference value−Count value) = Correction value Here, the coefficient is a time for adjusting the discharge timing to be delayed or advanced with respect to the conveyance amount of the measurement target roller in one pulse. If the value is positive, it is the time to delay the discharge timing, and if the value is negative, it is the time to advance the discharge timing. The count value is a value obtained by counting with a measuring device (not shown) such as a pulse counter while the measurement reference roller 191 is in contact with the outer peripheral section of the measurement target roller. The reference value is the number of pulses corresponding to the reference discharge timing, and is, for example, the number of pulses for the outer peripheral section obtained by dividing a predetermined number of drive rollers having a reference radius when there is no eccentricity.

<Example of correction value>
Here, as an example, as shown in FIG. 8, the measurement target roller 195 is divided into four at regular intervals with the rotation reference angle set at the outer periphery reference position (black triangle mark in the figure) as a reference (0 degree). Suppose that The outer periphery reference position is set as the outer periphery position where the distance from the drive roller rotation axis to the outer periphery is the maximum over the outer periphery. The outer periphery section obtained by dividing into four parts is defined as an outer periphery section A, an outer periphery section B, an outer periphery section C, and an outer periphery section D in the counterclockwise direction when viewed from the rotation axis direction. Further, the reference value is 2000, and the coefficient is 0.5.

  For example, as a result of measuring the first drive roller 111 using the measuring jig 190, as shown in FIG. 9, the count value of the outer peripheral section A is 2004, the count value of the outer peripheral section B is 1996, Assume that the count value of the outer peripheral section C is 1996 and the count value of the outer peripheral section D is 2004.

  In this case, as a result of calculating the correction value of each outer peripheral section, the correction value of the outer peripheral section A is −2, the correction value of the outer peripheral section B is +2, and the correction value of the outer peripheral section C is +2. The correction value for section D is −2. Then, as shown in FIG. 10, the correction value obtained by calculating for each outer peripheral section in association with the identification code assigned to each outer peripheral section is registered in the first correction table.

Accordingly, a correction value corresponding to the shake of the first drive roller 111 is set for each outer peripheral section obtained by dividing the rotation angle of the first drive roller 111 into four.
Note that correction values are set for the second drive roller 121 and the third drive roller 131 as well as the first drive roller 111.

<Installation conditions for each drive roller>
Next, installation conditions for each drive roller will be described.
As shown in FIG. 11, a mark (a black triangle mark in the figure) is attached to the outer peripheral reference position of the first drive roller 111. When viewed from the front side of the printing mechanism 103, a mark (white triangle in the figure) is attached in the 6 o'clock direction where the first driving roller 111 is installed in the frame 106 of the printing mechanism 103. The first drive roller 111 is installed on the frame 106 of the printing mechanism 103 in a rotatable state so that the mark attached to the first drive roller 111 is aligned with the mark attached to the frame 106 of the printing mechanism 103. .

  Similarly to the first drive roller 111, the second drive roller 121 and the third drive roller 131 are also installed on the frame 106 of the printing mechanism 103. That is, the outer periphery reference position of the first drive roller 111, the outer periphery reference position of the second drive roller 121, and the outer periphery reference position of the third drive roller 131 are aligned in the 6 o'clock direction.

  As a result, the phase of the fluctuation period related to the conveyance amount of the second drive roller 121 becomes substantially the same as the phase of the fluctuation period related to the conveyance amount of the first drive roller 111. The phase of the fluctuation period regarding the conveyance amount of the third drive roller 131 is substantially the same as the phase of the fluctuation period regarding the conveyance amount of the second drive roller 121.

Further, the second drive roller 121 is disposed away from the first drive roller 111 by a distance L _{1 that} is an integer multiple n ₁ of the outer peripheral length l ₁ of the first drive roller 111. Further, the third drive roller 131 is disposed away from the second drive roller 121 by a distance L _{2 that} is an integer multiple n ₂ of the outer peripheral length l ₂ of the second drive roller 121.

  Accordingly, the sheet can be conveyed with the first driving roller 111 and the second driving roller 121 as fixed ends. This is because the distance (peripheral length of the drive roller) carried in one cycle is constant even if the carry amount of the first drive roller 111 changes. For this reason, the cue from the second drive roller 121 can be matched with the cue from the first drive roller 111. The discharge timing of the second head row 152 can be adjusted on the basis of the discharge timing of the first head row 151. The discharge timing can be easily adjusted.

<Example of adjusting discharge timing>
Next, an example of adjusting the discharge timing will be described.
For example, it is assumed that the paper is sent out by each outer peripheral section until the leading edge of the paper is sent from the first driving roller 111 and reaches the second driving roller 121. In this case, based on (Equation 2) below, the ejection cycle of the first head row 151 is calculated while the sheet is in contact with the outer peripheral section.

(Expression 2) Reference discharge cycle + correction value = discharge cycle Here, it is assumed that the reference discharge cycle is 86.8 [μs]. In this case, from the first correction table shown in FIG. 10, while the sheet is in contact with the outer peripheral section A, the ejection cycle of the first head row 151 is 84.8 [μs]. While the sheet is in contact with the outer peripheral section B, the ejection cycle of the first head row 151 is 88.8 [μs]. While the sheet is in contact with the outer peripheral section C, the ejection cycle of the first head row 151 is 88.8 [μs]. While the sheet is in contact with the outer peripheral section D, the ejection cycle of the first head row 151 is 84.8 [μs].

<Summary>
As described above, according to the present embodiment, it is possible to adjust the discharge timing of the line-type inkjet head using the correction value set in accordance with the shake of each drive roller. Thereby, it is possible to obtain a printing result in which printing is performed at a substantially constant pitch with respect to each partial printing area, and the contents of the adjacent partial printing areas on the printing surface are naturally connected.

<Modification>
(1) The correction value may be determined in consideration of the shake / rotation speed of the driven gear attached to one end of the drive roller in addition to the shake / rotation speed of the drive roller.

  For example, as shown in FIG. 12, each driving roller is installed on the frame 106 of the printing mechanism 103, and the driving gear is attached to each driving roller. May be measured. As a result, it is possible to measure the drive roller shake superimposed on the drive gear shake.

Further, each correction value corresponding to the measured result may be stored in the correction value storage unit 182. Thereby, the discharge timing can be adjusted in a state close to the operating state.
(2) The outer peripheral reference position of the first drive roller 111 may be the outer peripheral position where the distance from the rotation axis of the first drive roller 111 to the outer periphery is minimized over the outer periphery. The outer peripheral reference position of the second drive roller 121 may be an outer peripheral position where the distance from the rotation axis of the second drive roller 121 to the outer periphery is minimized over the outer periphery. The reference outer peripheral position of the third drive roller 131 may be an outer peripheral position where the distance from the rotation axis of the third drive roller 131 to the outer periphery is minimized over the outer periphery.

  (3) Each line-type inkjet head 150 realizes a plurality of colors by combining a plurality of line-type inkjet heads 150 that discharge a single color with a single line-type inkjet head 150 and discharge different colors. It may be. Further, two or more stages may be arranged in the sheet conveyance direction, or three or more stages may be arranged in the sheet width direction. Moreover, it may be arranged in a staggered arrangement.

(4) In addition to the common water-based ink, examples of the ink include various liquid compositions such as oil-based ink, gel ink, and hot melt ink.
(5) The liquid ejection device 100 may eject other liquids in addition to ink as long as it is a material that can be ejected. For example, as the other liquid, the substance may be in a liquid phase, (a) a liquid having high or low viscosity, (b) liquid crystal, (c) sol, (d) gel water, (e) an inorganic solvent, (F) Organic solvents, (g) solutions, (h) liquid resins, (i) molten metals, and the like. Further, (j) a functional material made of a solid such as a pigment or metal particles is dissolved in a solvent, (k) a functional material made of a solid such as a pigment or metal particles is dispersed in a solvent, (l And a mixture of two or more kinds of functional materials made of solid materials such as pigments and metal particles in a solvent.

(6) It should be noted that the liquid may be discharged from the liquid discharge device 100 so as to draw a tail in a drop shape, a granular shape, a tear shape, or a thread shape.
(7) The liquid ejection device 100 may be, for example, (a) a textile printing device, (b) a microdispenser, etc., other than the ink jet printing device. In addition, (c) as an apparatus for discharging a liquid containing a material in which a material such as an electrode material or a color material used for manufacturing a liquid crystal display, an electroluminescence display, a surface emitting display, a color filter, or the like is dispersed or dissolved. Also good. Moreover, (d) It is good also as an apparatus which discharges the bioorganic matter used for manufacture of a biochip. Moreover, (e) It is good also as an apparatus which discharges the liquid used as the sample used as a precision pipette. Moreover, (f) It is good also as an apparatus which discharges lubricating oil pinpoint to precision machines, such as a timepiece and a camera. (G) In order to form a micro hemispherical optical lens used for an optical communication element or the like, a device that discharges a transparent resin liquid such as an ultraviolet curable resin onto a substrate may be used. (H) In order to etch a substrate or the like, an apparatus for discharging an etchant such as acid or alkali may be used.

(8) In addition to the paper, the discharge target includes a substrate, a color filter, a fiber material, a three-dimensional object, and the like.
(9) The image storage unit 181 may be a storage area allocated to a volatile memory such as a DRAM (Dynamic Random Access Memory). The correction value storage unit 182 may be a storage area allocated to a nonvolatile memory such as an EEPROM (Electrically Erasable and Programmable Read Only Memory).

  (10) The discharge adjustment unit 183 may be realized by executing a program for controlling the liquid discharge apparatus 100 with an arithmetic device such as a CPU (Central Processing Unit). Further, it may be realized by a full custom LSI (Large Scale Integration). Further, it may be realized by a semi-custom LSI such as ASIC (Application Specific Integrated Circuit). Further, it may be realized by a programmable logic device such as a field programmable gate array (FPGA) or a complex programmable logic device (CPLD). Further, it may be realized as a dynamic reconfigurable device whose circuit configuration can be dynamically rewritten.

  Further, design data for forming one or more functions constituting the discharge adjustment unit 183 in these LSIs is hardware description such as VHDL (Very High Speed Integrated Circuit Hardware Description Language), Verilog-HDL, SystemC, and the like. It may be a program written in a language (hereinafter referred to as an HDL program). Alternatively, it may be a gate level netlist obtained by logical synthesis of an HDL program. Further, it may be macro cell information in which arrangement information, process conditions, etc. are added to a gate level netlist. Further, it may be mask data in which dimensions, timing, and the like are defined.

  Furthermore, the design data may be recorded on a recording medium readable by a hardware system such as a computer system or an embedded system. Furthermore, the design data read by the other hardware system via the recording medium may be downloaded to the programmable logic device via the download cable. Thus, the discharge adjustment unit 183 can be realized in another hardware system. Here, as a recording medium readable by the hardware system, an optical recording medium (for example, a CD-ROM), a magnetic recording medium (for example, a hard disk), and a magneto-optical recording medium (for example, an MO) are used. And semiconductor memory (for example, a memory card).

  The design data may be held in a hardware system connected to a network such as the Internet or a local area network. Furthermore, the design data acquired by the other hardware system via the network may be downloaded to the programmable logic device via the download cable. Thus, the discharge adjustment unit 183 can be realized in another hardware system. Here, as a network, a terrestrial broadcasting network, a satellite broadcasting network, a PLC (Power Line Communication), a mobile telephone network, a wired communication network (for example, IEEE802.3), and a wireless communication network (for example, IEEE802.11). There is.

  Further, the logic synthesis, arrangement, and wiring design data may be recorded in the serial ROM. The design data recorded in the serial ROM may be directly downloaded to the FPGA when energized.

  INDUSTRIAL APPLICABILITY The present invention can be used as a liquid discharge apparatus that discharges liquid onto a discharge target, particularly as a liquid discharge apparatus that can adjust the discharge timing of a liquid discharge head according to the shake of a transport roller. .

50 Paper 100 Liquid Ejecting Device 101 Paper Feeding Base 102 Paper Feeding Mechanism 103 Printing Mechanism 104 Paper Discharge Mechanism 105 Paper Receiving Base 106 Frame 110 First Conveying Roller Unit 111 First Drive Roller 112 First Drive Roller 113 Driven Gear 114 Drive gear 115 Stepping motor 120 Second transport roller unit 121 Second drive roller 122 Second driven roller 123 Driven gear 124 Drive gear 125 Stepping motor 130 Third transport roller unit 131 Third drive roller 132 Third Driven roller 133 Driven gear 134 Drive gear 135 Stepping motor 140 Conveying guide unit 150 Line-type inkjet head 151 First head row 152 Second head row 170 Paper leading edge detection sensor 170a Light emitting element 170b Light receiving element 171 First outer peripheral reference position detection Sensor 171a Light emitting element 171b Light receiving element 171c Reflector 172 Second outer reference position detection sensor 172a Light emitting element 172b Light receiving element 172c Reflector 173 Third outer reference position detecting sensor 173a Light emitting element 173b Light receiving element 173c Reflector 180 Control unit 181 Image storage unit 181a First partial image storage unit 181b Second partial image storage unit 182 Correction value storage unit 182a First correction table storage unit 182b Second correction table storage unit 182c Third correction table storage unit 183 Adjustment unit 183a First outer circumference section identification section 183b Second outer circumference section identification section 183c Third outer circumference section identification section 183d First correction value search section 183e Second correction value search section 183f Third correction value search section 183g Transport position specifying unit 183h First correction value selecting unit 183i Correction value selection unit 183j First head row adjustment unit 183k Second head row adjustment unit 184a-184c Graph 185a, 185b Graph 190 Measurement jig 191 Measurement reference roller 192 Rotary encoder 192a Slit disc 192b Photo interrupter 193 Tension spring 194 Stepping motor 195 Roll to be measured

Claims (4)

A liquid discharge head in which a plurality of nozzles for discharging liquid are arranged, a first transport roller disposed on the upstream side of the liquid discharge head, and a second transport roller disposed on the downstream side of the liquid discharge head A liquid ejection device that ejects liquid onto an ejection target that is conveyed from the first conveyance roller to the second conveyance roller,
Corresponding to each of a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number on the basis of the outer peripheral reference position of the first transport roller, it is set according to the deflection of the first transport roller Storage means for storing a correction value of the discharge period of the liquid discharge head;
A first outer peripheral section specifying means for sequentially specifying an outer peripheral section for sending out the discharge target in the first transport roller in operation from the plurality of outer peripheral sections of the first transport roller;
A selection means for sequentially selecting a correction value corresponding to the outer periphery section sequentially specified by the first outer periphery section specifying means from the plurality of correction values stored in the storage means;
A liquid ejection apparatus comprising: an adjustment unit that sequentially adjusts the ejection timing of the liquid ejection head according to the correction value sequentially selected by the selection unit. Outer periphery that sends out the discharge target in the second transport roller in operation from a plurality of outer peripheral sections obtained by dividing the outer periphery into a predetermined number based on the outer peripheral reference position of the second transport roller A second outer peripheral section specifying means for sequentially specifying the sections;
The storage means stores a correction value of the discharge period of the liquid discharge head set in accordance with the shake of the second transport roller in association with each of the plurality of outer peripheral sections of the second transport roller. ,
The selection means selects a correction value corresponding to an outer periphery section sequentially specified by the second outer periphery section specifying means from a plurality of correction values stored in the storage means. Item 2. The liquid ejection device according to Item 1. A transport position specifying means for sequentially specifying the transport position of the discharge target during transport;
A correction value corresponding to the outer peripheral section sequentially specified by the first outer peripheral section specifying means according to the transport position of the ejection target object sequentially specified by the transport position specifying means; The liquid ejecting apparatus according to claim 2, wherein one of correction values corresponding to the outer peripheral sections sequentially specified by the two outer peripheral section specifying means is sequentially selected. The second transport roller is separated from the first transport roller by a distance that is an integral multiple of the outer peripheral length of the first transport roller;
The outer peripheral reference position of the first transport roller and the second transport so that the phase of the fluctuation cycle related to the shake of the first transport roller matches the phase of the fluctuation cycle related to the shake of the second transport roller. The liquid ejection device according to any one of claims 1 to 3, wherein an outer peripheral reference position of the roller is adjusted.

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