JP5948396B2 - Method for calculating conveyance amount correction value of image recording apparatus - Google Patents

Description

  The present invention relates to a conveyance amount correction value calculation method for an image recording apparatus that records an image by ejecting ink droplets onto a recording medium.

  In general, an image recording apparatus known as an ink jet printer is equipped with a recording head on which a large number of nozzles for discharging minute ink droplets are arranged. Inkjet printers are roughly classified into line printers and serial printers. The line printer is also equipped with a transport mechanism that transports the recording medium to the position immediately below the recording head. On the other hand, a serial printer is equipped with a transport mechanism that transports a carriage mounted with a recording head to a fixed position. In the following description, a line printer will be described as an example.

  As an outline of the structure of the transport mechanism, a transport roller and a belt, and a pulse encoder which is a part for converting / outputting the transport roller rotation amount into a pulse signal are provided on the transport roller. The printer control unit calculates the carry amount based on the number of pulses output from the pulse encoder and the outer peripheral length of the carry roller. In accordance with the calculated medium conveyance amount, the recording head ejects ink droplets so as to form dots at specified positions in the medium conveyance direction (sub-scanning direction) on the recording medium.

  The medium conveyance amount derived based on the number of pulses output from the pulse encoder may include an error. If there is an error in the transport amount of the medium, an ink droplet is landed on a recording medium that is actually recorded and a dot is formed at a position shifted from the dot position designated as image data. Unless otherwise specified, the medium transport amount error described below suggests an error that occurs regularly, and the medium transport amount error that occurs periodically is described as transport unevenness.

An example of the cause of the medium transport amount error will be described.
First, there is a conveyance roller outer circumferential length error caused by the conveyance roller formation.
When the outer peripheral length of the transport roller is longer than the design value, the medium transport amount per pulse increases, and the recorded image has a gap between dots in the sub-scanning direction. On the other hand, when the outer peripheral length of the transport roller is shorter than the design value, the medium transport amount per pulse decreases, and the recorded image has an overlap between dots in the sub-scanning direction.

Second, there is a belt thickness error caused by forming the conveyor belt.
When the belt thickness is thicker than the design value, the medium conveyance amount per pulse increases. On the other hand, when the belt thickness is thinner than the design value, the medium conveyance amount per pulse decreases. A method of calculating a value for detecting or correcting the medium transport amount error per pulse will be described by taking a line printer as an example.

  After a dot group is recorded in the main scanning direction on the recording medium by a certain recording head, the same dot group is recorded again by the recording head that has performed recording at a position where the medium has been conveyed a predetermined distance. To do. A method of measuring a distance in the sub-scanning direction between the recorded two dot groups and calculating a difference or ratio from the theoretical distance can be given.

As other technical examples, Patent Document 1 and Patent Document 2 are proposed.
Among these, Patent Document 1 discloses a paper conveyance obtained by reading a marker recorded on a recording medium by a marker reading unit provided between the line type recording heads arranged at different positions in the medium conveying direction. A technique for controlling the ink ejection timing based on information and module information (distance between each line recording head and marker reading means, distance between each line recording head) is disclosed.

  Further, in Patent Document 2, as a method for preventing a measurement error caused by conveyance unevenness caused by eccentricity of the conveyance roller in measuring the medium conveyance amount, a roller N rotation period (N ≧ 1 and A technique for recording two or more images with N = natural number) and measuring based on the image positions is disclosed.

JP 2007-196568 A JP 2007-001183 A

As a recording medium usually used, paper or the like is the mainstream, and when these are materials whose physical length or area expands or contracts due to moisture or the like, a test pattern is recorded in a high humidity environment. There is a possibility that the recording medium will expand and contract later.
Due to this expansion / contraction phenomenon, the medium transport amount error value obtained from the distance between the two dot groups located far away from each other has low accuracy and cannot secure sufficient quality.

In the above-described technical example disclosed in Patent Document 1, it is necessary to provide a marker reading unit between the line recording heads, which increases parts / manufacturing costs related to the marker reading unit. Further, in the technical example disclosed in Patent Document 2, the outer peripheral length of the transport roller is used, and cannot be used for an image recording apparatus including a transport mechanism provided with a transport belt.
SUMMARY An advantage of some aspects of the invention is that it provides a conveyance amount correction value calculation method for an image recording apparatus that prevents a decrease in accuracy caused by expansion and contraction due to moisture or the like of a recording medium.

To achieve the above object, an embodiment according to the present invention includes a transport means having a plurality of conveying rollers arranged along the conveying direction of the recording medium, and an encoder for calculating the amount of rotation of those conveying roller, At least a first recording head that records images based on the number of pulses output from the encoder on the recording medium that is arranged at a plurality of different positions in the conveyance direction of the recording medium and that is conveyed by the conveying unit. And a plurality of recording heads including the second recording head, image reading means for reading an image recorded by each recording head, and correction of recording timing of each recording head based on image information read by the image reading means And a control means for controlling the recording timing of each recording head, and calculating a conveyance amount correction value in the image recording apparatus A first recording step of recording a first test pattern image on a recording medium at an arbitrary position in the transport direction by the first recording head, and an image recording timing by the first recording head; After counting only the number of encoder pulses corresponding to the recording medium conveyance amount corresponding to the arrangement interval from one recording head position to the second recording head position, the recording position is the same as the arbitrary position by the second recording head and the recording is performed. A second recording step of recording a second test pattern image on the recording medium at a different position in the width direction of the medium; an image reading step of each test pattern image recorded on the recording medium by the image reading means; Recording position shift amount in the conveyance direction of the recording medium of each test pattern image read by the image reading means A correction amount calculating step for calculating a pulse correction amount corresponding to the recording position deviation amount, and the test pattern images recorded by the recording heads so as to be recorded at the same position in the transport direction. A correction step of correcting the encoder pulse number by adding the pulse correction amount to the encoder pulse number, an arrangement interval between the first recording head and the second recording head, and a corrected encoder pulse An adjustment value calculation step for calculating an image length adjustment value composed of a recording medium conveyance amount per pulse from a ratio to the number is provided.

  According to the present invention, it is possible to provide a conveyance amount correction value calculation method for an image recording apparatus that prevents a decrease in accuracy caused by expansion and contraction due to moisture or the like of a recording medium.

FIG. 1 is a diagram illustrating an example of a system configuration for calculating an image recording apparatus and a medium transport amount error according to the first embodiment. FIG. 2 is a diagram showing a block configuration of a system based on components used for measuring the medium conveyance amount. 3A and 3B are diagrams for explaining the definition of the distance between the recording heads 2 at different positions in the sub-scanning direction. FIG. 4 is a diagram illustrating a configuration example of the inter-recording head distance measuring device according to the first embodiment. FIG. 5A is a diagram showing an example of a test pattern by a line printer, and FIG. 5B is a diagram showing an example of a test pattern by a serial printer. FIG. 6 is a flowchart for explaining the procedure of image length adjustment according to the first embodiment. FIG. 7A is a diagram for explaining the number of transport pulses for transporting the recording medium between the two recording heads, and FIG. 7B is a design distance for transporting the recording medium 12 between the two recording heads. It is a figure for demonstrating. FIG. 8 is a diagram for explaining the shift amount in the sub-scanning direction of the dot group corresponding to the two recording heads. FIG. 9 is a diagram for explaining the correction value pulseβ. FIG. 10 is a flowchart for explaining the procedure of image length adjustment according to the second embodiment. FIG. 11 is a flowchart for explaining the procedure of image length adjustment according to the third embodiment. FIG. 12 is a flowchart for explaining a procedure of image length adjustment according to the fourth embodiment. FIG. 13 is a diagram for explaining the average coordinates of the dot group in the sub-scanning direction. FIG. 14 is a diagram for explaining the average value of dot GroupYAi. FIG. 15 is a diagram illustrating an example of a test pattern according to the fourth embodiment. FIG. 16 is a flowchart for explaining the procedure of image length adjustment according to the fifth embodiment. FIG. 17 is a diagram illustrating an example of a test pattern according to the fifth embodiment. FIG. 18 is a flowchart for explaining the procedure of image length adjustment according to the sixth embodiment. FIG. 19 is a diagram illustrating the distance from the pickup roller to the recording head. FIG. 20 is a flowchart for explaining the procedure of image length adjustment according to the seventh embodiment. FIG. 21 is a flowchart for explaining the procedure of image length adjustment according to the eighth embodiment. FIG. 22 is a flowchart for explaining the procedure of image length adjustment according to the ninth embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic diagram illustrating an example of a system configuration for calculating an image recording apparatus and a medium transport amount error according to the first embodiment. In each embodiment described below, the sub-scanning direction is defined as the recording medium conveyance direction, and the direction orthogonal to the sub-scanning direction is defined as the main scanning direction. A vertical direction perpendicular to the main scanning and sub-scanning directions is a gravity direction. In the image recording apparatus described below as an example, unless otherwise specified, the recording heads 2 of the respective ink colors are arranged along the sub-scanning direction, and each recording head is arranged in a nozzle array having a width equal to or larger than the width of the recording medium 12. A line head type ink jet printer (hereinafter referred to as a printer) having a long (image recording area) is used.

  The system shown in FIG. 1 measures the distance between each of a printer 1, an image reading device 15 that reads a recording medium recorded by the recording head 2 and converts it into image data, and the recording head 2 assembled to the carriage 3. It is comprised with the distance measuring device 29 between heads. In this example, the printer 1, the image reading device 15, and the head-to-head distance measuring device 29 are separate components. Of course, if the image reading device 15 having a transport mechanism that can be coupled to the transport mechanism of the printer 1 is used, the reading and setting operation by the user described later is unnecessary.

  The printer 1 stores a plurality of recording media 12, a recording medium supply unit 9 that supplies the recording media sequentially one by one, a transport mechanism 6 that transports the recording media 12, and ejects ink as fine droplets onto the recording media 12. The recording head 2 for recording an image, a recording medium cassette 10 for storing a plurality of recording media 12, and a printer control unit 14 for controlling the entire apparatus including image recording.

  The image reading device 15 provided on the downstream side of the printer 1 employs a commercially available flat bed scanner or the like. The image reading device 15 mainly includes an image reading unit 17 that reads an image recorded on the test recording medium 13 (for example, a line sensor including a solid-state imaging device such as a CCD or a CMOS), and an image reading control unit 16. The scanned image is converted into image data and output. The head distance measuring device 29 will be described later in detail with reference to FIG.

  The image processing / control / arithmetic unit (hereinafter referred to as a processing control unit) 18 and the display unit 19 can be replaced by a personal computer. The processing control unit 18 is connected to the printer control unit 14 through a LAN, and the image reading control unit 16 and the head distance measuring device 29 are connected to each other via USB. Of course, these connections are not limited, but are examples, and are not limited to wired connections, but may be connections using wireless or optical fibers.

The input unit 20 inputs an instruction from the user to the processing control unit 18. In accordance with this instruction, the processing control unit 18 controls the printer 1, the image reading control unit 16, and the head distance measuring device 29.
The recording head 2 has a nozzle surface provided with a plurality of nozzle rows (2CN to 2YN) in which, for example, 300 nozzles are opened in a row. The nozzle surface faces the recording medium 12 being conveyed, and ink is ejected from each nozzle. Of course, the number of nozzles is an example and is not limited.

  In the present embodiment, four recording heads 2 (2C [cyan color], 2K [black color], 2M [magenta color], 2Y [yellow] that individually eject at least four colors of ink from the upstream side along the transport direction. Color]), and a single color image or a color image is recorded on the recording medium 4. In this embodiment, a line type recording head is described as an example. However, the present invention is not limited to this, and serial type recording that scans and moves on the recording medium 12 in the main scanning direction is repeated. Even for the head, the same principle can be applied if the target direction is changed.

  In the present embodiment, the recording medium supply unit 9 stores a plurality of recording media 12 in a tray (or cassette) attached to the outside of the apparatus, sequentially picks up one sheet at a time by the pickup roller 11, and supplies it to the transport mechanism 6. Supply. On the other hand, the recording medium cassette 10 provided inside the apparatus accommodates a plurality of recording media 12, is sequentially taken out one by one, and is supplied to the transport mechanism 6.

  The transport mechanism 6 includes, for example, at least two or more transport rollers 5, a pulse encoder 4 provided on one of the transport rollers 5, and a winding in a state in which the transport rollers 5 are tensioned. And a conveyor belt 7.

  Among these, at least one of the transport rollers 5 is connected to a drive source such as a motor (not shown), and the transport belt 7 is rotated by rotating the transport roller 5. At this time, the pulse encoder 4 provided on one of the transport rollers 5 outputs a transport pulse signal in accordance with the rotation cycle of the transport roller 5. The output cycle of this pulse signal is a cycle in which one dot on the recording medium 12 is transported in this embodiment when all the parts constituting the transport mechanism 6 are as designed.

  The conveying belt 7 is configured to have a large number of small holes (not shown) opened and to face all the nozzle surfaces of the recording head 2 in parallel (or at the same interval). A fan 8 serving as suction means is provided inside the conveyor belt 7, and the recording medium 12 is conveyed while being adsorbed and fixed on the conveyor belt 7 by the negative pressure of the fan 8, and the recording head 2. Pass the front of the nozzle face.

  FIG. 2 shows a block configuration of a system based on components used for measuring the medium conveyance amount. This system includes a printer 1, an image reading device 15, an inter-head distance measuring device 29, a processing control unit 18, a display unit 19, and an input unit 20.

  The processing control unit 18 mainly includes an arithmetic processing unit 23 and a storage unit 24. In the storage unit 24, memory areas of a pulse number storage area 25, an image data storage area 26, an inter-head distance storage area 27, and a test pattern storage area 28 are secured. The processing control unit 18 controls the printer 1 and the image reading device 15 and controls the head-to-head distance measuring device 29. Further, the processing control unit 18 analyzes the test recording medium 13 image data read by the image reading device 15 and analyzes each image data. A print timing (ink ejection timing) adjustment value of the recording head 2 is calculated, and a head-to-head distance in the head-to-head distance measuring device 29 is calculated.

  Further, the storage unit 24 and the physical distance between the recording heads 2 obtained by storing the number of medium transport pulses between the recording heads 2 obtained by the print timing adjustment and measuring the head-to-head distance by the head-to-head distance measuring device 29, The test pattern recorded by the print timing adjustment and the image data read by the image reading device (flatbed scanner) 15 are stored.

  Then, using these data, the medium conveyance amount per pulse of medium conveyance is calculated. The control of the printer 1 and the image reading device 15 and the control of the head distance measuring device 29 are performed by an input instruction from the input unit 20 by the user.

  The printer 1 mainly includes a recording head 2, a transport mechanism 6, a printer control unit 14, a printer storage unit 22, and a pulse encoder 4. The printer control unit 14 drives the recording head 2 and the transport mechanism 6 based on each set adjustment value, records a test pattern on the recording medium 12, and records the test recording medium 13. The printer storage unit 22 used here is a nonvolatile memory, but temporarily stores the number of medium transport pulses output from the pulse encoder 4 and temporarily stores test pattern image data. The printer storage unit 22 also stores an alternative function of the test pattern storage area 28 in the processing control unit 18 and various adjustment parameters.

  The image reading device (flatbed scanner) 15 mainly includes an image reading control unit 16 and an image reading unit 17. The image reading control unit 16 controls the image reading unit 17 in accordance with an instruction from the processing control unit 18. The configuration of the inter-head distance measuring device 29 is described in FIG.

  3A and 3B show the definition of the distance between the recording heads 2 at different positions in the sub-scanning direction. 3A and 3B show, as an example, the recording head 2C, the recording head 2Y, and the nozzle rows (2CN, 2YN) for ejecting ink from each recording head 2, and FIG. The arrangement of the recording head 2 in the line printer is shown, and FIG. 3B shows the arrangement of the recording head 2 in the serial printer.

  The distance between the recording heads 2 described in the present embodiment suggests the distance in the sub-scanning direction between the nozzle rows provided in each recording head 2. The distance between the recording heads 2 in the case of a serial printer is the main scanning direction distance between the nozzle rows. By setting the distance between the recording heads 2 to be the distance between each nozzle from which ink is ejected, the accuracy of the image length adjustment value is increased.

For details on how to determine the distance between the nozzle rows, after calculating the center of gravity position of each nozzle, calculate the average of the center of gravity position for each recording head 2, and calculate the difference between the center of gravity center position in the corresponding direction for each printer type. The distance between the nozzle rows. A method for measuring the position of the center of gravity of the nozzle and the distance between the nozzle rows will be described with reference to the measurement apparatus shown in FIG.
FIG. 4 shows an apparatus for measuring the position of the center of gravity of the nozzle of the recording head 2 in this embodiment. The head-to-head distance measuring device 29 used for measuring the center of gravity of the nozzle can be driven in the main scanning direction (or sub-scanning direction) with two or more CCD cameras 30 (CCD camera 30A and CCD camera 30B). It comprises a stage 31 that supports a camera, a carriage support base 32 that supports a carriage 3 on which the recording head 2 is assembled, and a processing control unit 18.

  First, the user sets the carriage 3 on which the recording head 2 is assembled to the carriage support base 32. Thereafter, the CCD camera 30 is controlled by the processing control unit 18 that receives a command when the user inputs a measurement command from the input unit 20. The CCD camera 30 images the target nozzle row of the recording head 2.

  When the imaging range of the CCD camera can be imaged only about 1 to 5 nozzles due to the specification, the user inputs to the input unit 20 and controls the movement of the stage through the processing control unit 18. The number of nozzles to be imaged is increased by moving the stage in the main scanning direction according to this control. Thus, by increasing the number of data samples, it is possible to improve the position calculation accuracy of the nozzle row.

  The distance between the focal positions of the CCD cameras 30 is calibrated in advance, and the distance between the focal points is known. The processing control unit 18 performs image processing from the imaged image data of the nozzle row to obtain the position of the center of gravity of the nozzle. The inter-nozzle row distance is calculated based on the center-of-gravity position of the nozzle obtained here and the distance between the focal positions of the CCD cameras 30. The calculated inter-nozzle row distance is recorded in the storage unit 24.

  FIG. 5A shows an outline of the test recording medium 13 to be recorded by the print timing adjustment. In FIGS. 5A and 5B and the following description, as in FIGS. 3A and 3B, a combination of the recording head 2C and the recording head 2Y is shown as an example. However, in the print timing adjustment, adjustment is made for all combinations of the heads provided in the recording head 2.

  In the following description, the line printer according to FIG. 5A is used as a model. However, even in the case of a serial printer, the reference pattern in the pattern recorded on the recording medium 12 is used as shown in FIG. The adjustment direction is the same, but the adjustment principle is the same.

  The pattern to be recorded by the print timing adjustment is a dot for one line in the sub-scanning direction drawn at any one position in the sub-scanning direction on the recording medium 12 by ejecting ink from the recording head 2C and the recording head 2Y. A dot group (the number of dots ≧ 2). The user operates the input unit 20 to transmit the image data drawn in this way from the processing control unit 18 to the printer control unit 14. This image data is stored in the storage unit 24 in advance.

  If the difference in ink ejection speed or the transport amount per pulse of medium transport is different from the design value, the dots or dot groups corresponding to the recording heads 2 drawn here are displaced from each other in the sub-scanning direction. In the print timing adjustment, in order to reduce the shift amount, the shift amount is measured, and a print timing (ink ejection timing) correction value is set for each recording head 2.

  At this time, the recording head 2 </ b> C and the recording head 2 </ b> Y are separated from each other by measuring the shift amount of dots or dot groups recorded at any one position in the sub-scanning direction on the recording medium 12. The measurement error due to the expansion and contraction of the recording medium 12 due to moisture or the like is reduced compared to when measuring the distance between dots or dot groups.

  Here, at the completion of the print timing adjustment, after the shift amount is corrected, the dot encoder or the dot group is recorded from the recording head 2C and the dot or the dot group is recorded from the recording head 2Y. Is stored in the storage unit 24.

  Next, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the first embodiment will be described with reference to a flowchart shown in FIG. In the flowchart in FIG. 6, it is expressed as follows. The same applies to the subsequent flowcharts. The nozzle row distance design value indicating the arrangement interval from the first recording head position to the second recording head position is expressed as head Distance Theoretical. The number of encoder pulses corresponding to the recording medium transport amount is expressed as pulse Number AB. The recording position deviation amount in the recording medium conveyance direction is expressed as timing gap AB. The pulse correction amount corresponding to the recording position deviation amount is expressed as pulse β. The image length adjustment value is expressed as image Length.

  In the following description, since the recording head 2C and the recording head 2Y are taken as an example, [2C] is [A] and [2Y] is [B]. Of course, the present invention is not limited to the recording head 2C and the recording head 2Y, and any other combination of the recording heads 2 arranged at different positions in the sub-scanning direction can be used. FIG. 7A is a diagram for explaining the designed number of transport pulses (pulse AB Theoretical) required to transport the recording medium 12 between the two recording heads, and FIG. FIG. 6 is a diagram for explaining a design distance between print heads (head Distance Theoretical) required for transporting a print medium 12 between two print heads.

  First, in the design distance (head Distance Theoretical) between the recording head A and the recording head B shown in FIG. 7B, the design transport required for transporting the recording medium 12 shown in FIG. The number of pulses (pulseAB Theoretical) is substituted into the carrier pulse variable pulse NumberAB (step S1). Note that the design distance in FIG. 7B may be an actually measured value (head Distance Real). Further, the number of carrier pulses in FIG. 7A may be an actual measurement value (a value calculated based on pulse AB Real: 1 head Distance Real).

  The printer storage unit 22 stores in advance a carrier pulse number pulse AB Theoretical (design value), and an area for the carrier pulse variable pulse NumberAB is also secured. These substitution processes are performed by the printer control unit 14 when the printer 1 is first activated. Since the printer storage unit 22 is a non-volatile memory, the value substituted for the carrier pulse variable pulse NumberAB is stored even when the printer 1 is turned off.

  Next, the user inputs a test image recording command from the input unit 20. Upon receiving this recording command, the processing control unit 18 reads the test image data from the test pattern storage area 28 and transmits the test image data and the recording command to the printer control unit 14 via the LAN. The printer control unit 14 that has received the image data drives the pickup roller 11, the transport mechanism 6, and the recording head 2 to perform a recording operation on the recording medium 12 (step S2). In this recording operation, the number of pulses output by the pulse encoder 4 from the recording operation by the recording head A is counted. When the counted number of pulses reaches the carrier pulse variable pulse NumberAB, a recording operation is performed by the recording head B. As shown in FIG. 5A, the test recording medium 13 has a continuous 1 in the sub-scanning direction. A dot group consisting of one or more dots is formed for the line. In the following description, in FIGS. 7 to 9, 13 to 15, 17, and 19, the test recording medium 13 is a recording in which a test image is recorded by the recording head A and the recording head B as an example. It will be described as a medium. In FIG. 19, the position of the pickup roller and the position of each recording head are denoted as drA and drB.

  Next, the user sets the recorded test recording medium 13 in the image reading device 15 and inputs an image reading command from the input unit 20. The processing control unit 18 that has received the command transmits an image reading command to the image reading control unit 16 via the USB. Upon receiving the command, the image reading control unit 16 drives the image reading unit 17 composed of a line sensor composed of a solid-state imaging device such as a CCD or a CMOS, images the entire set test recording medium 13, and outputs image data. To the processing control unit 18. The processing control unit 18 that has received the image data and the average coordinates dot GroupYA of the center of gravity position in the sub-scanning direction of each dot group (number of dots ≧ 1) corresponding to each recording head 2 recorded on the test recording medium 13 and The dot GroupYB (see FIG. 8) is extracted by image processing such as binarization or pattern matching (step S3).

  Further, as shown in FIG. 8, the displacement amount timing gap AB in the sub-scanning direction of the dot groups corresponding to the recording heads A and B is calculated from the difference between the average coordinates dot GroupYA and dot GroupYB obtained in step S3 ( Step S4).

  The dot group deviation amount timing GapAB calculated in step S4 is compared with a predetermined standard value (step S5). In this comparison, if it is within the standard value (YES), the process proceeds to step S8 described later. On the other hand, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6).

  That is, based on the value of the dot group deviation amount timing GapAB obtained in step S4, the dot group corresponding to the recording head B is upstream of the dot group corresponding to the recording head A in the sub-scanning direction as shown in FIG. If it is located at the position, a correction value pulse β (a value converted from the physical distance of timing GapAB to the number of pulses for the timing adjustment value) to advance the ink ejection timing by the recording head B is calculated. When the dot group corresponding to the recording head B is located downstream of the dot group corresponding to the recording head A in the sub-scanning direction, the correction value pulse β for delaying the ink ejection timing by the recording head B is calculated. . At this time, the ink ejection timing correction unit is set to, for example, 1/32 dots in this embodiment.

  Next, timing adjustment is performed by adding the ink ejection timing correction value pulse β obtained in step S6 to the transport pulse variable pulse NumberAB (step S7). By this adjustment, the ink ejection timing of the recording head A or the recording head B is adjusted, and when one dot group is recorded by the recording heads A and B, any one position in the sub-scanning direction on the recording medium 12 is recorded. The dot groups overlap each other. These processing steps S1 to S7 are print timing adjustment steps.

  In the comparison in step S5 described above, when the dot group deviation amount timing GapAB is within the standard value, the design distance between the recording head A and the recording head B from the printer storage unit 22 and the carrier pulse variable pulse NumberAB and the storage unit 24 is stored. Head Distance Theoretical is read into each (step S8). The design distance between the recording head A and the recording head B is previously input by the user from the input unit 20 and stored.

  The distance between the recording head A and the recording head B read in step S8 (head distance theoretical (FIG. 7B)) is divided by the pulse number AB read in step S7 to determine the medium conveyance amount per one medium conveyance pulse ( Step S9). These processing steps S8 and S9 are image length adjustment steps.

  As described above, in order to obtain the medium conveyance amount per pulse of medium conveyance, for example, after recording a dot group from the recording head A, the recording medium is conveyed by one pulse of medium conveyance, and the dot group is again extracted from the recording head A. In the case of the method of recording and measuring the distance between two dot groups, there is a possibility that the reliability of the measurement result of the distance between the two dot groups is lowered and the accuracy is also lowered due to the phenomenon that the medium expands and contracts due to moisture or the like. There is.

  On the other hand, in this embodiment, in order not to be affected by the expansion and contraction of the recording medium, the dot group corresponding to the recording head A and the recording head B is arranged at an arbitrary position on the recording medium 12 in the sub-scanning direction. On the other hand, the number of medium transport pulses when overlapping each other and the head-to-head design distance between the recording head A and the recording head B are used. As a result, it is possible to obtain a medium conveyance amount per pulse of medium conveyance with higher accuracy than the method using the distance between dot groups whose recording positions are separated from each other.

Next, a second embodiment will be described.
With reference to the flowchart shown in FIG. 10, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the second embodiment will be described. In the description of this embodiment, in the same operation procedure (steps S5 to S9) as in the first embodiment described above, the same step numbers are given to simplify the description.

  This embodiment is an operation procedure corresponding to a serial printer. In this operation procedure, the direction used as a reference for obtaining the number of conveyance pulses is changed to the main scanning direction, and at any distance between the two recording heads A [2C] and B [2Y], not the medium conveyance but the carriage conveyance. It is a point to do.

  First, at a design distance b (μm) between the recording head A and the recording head B, a designed transport pulse number a (pulse AB Theoretical) required for carriage transport is substituted into a transport pulse variable pulse NumberAB (step S11). The printer storage unit 22 stores in advance a carrier pulse number pulse AB Theoretical (design value), and an area for the carrier pulse variable pulse NumberAB is also secured. These substitution processes are performed by the printer control unit 14 when the printer 1 is first activated. Since the printer storage unit 22 is a non-volatile memory, the value substituted for the carrier pulse variable pulse NumberAB is stored even when the printer 1 is turned off.

  Next, the printer control unit 14 that has received the image data drives the pickup roller 11, the transport mechanism 6, and the recording heads A and B to perform a recording operation on the recording medium 12. When the number of pulses output from the pulse encoder 4 reaches the carrier pulse variable pulse Number AB by the recording operation by the recording head A, the recording operation by the recording head B is performed, and as shown in FIG. A dot group consisting of one line and one or more dots is formed in the main scanning direction which is the transport direction (step S12).

  Next, the image reading control unit 16 that has received a reading command from the processing control unit 18 according to a user's instruction drives the image reading unit 17 to image the entire set test recording medium 13 and generate image data. To do.

  The processing control unit 18 that has received the image data binarizes the positions in the main scanning direction of the respective dot groups (dot number ≧ 1) corresponding to the recording heads A and B recorded on the test recording medium 13. The average coordinates dot GroupYA and dot GroupYB of the centroid position of each dot group are extracted by image processing such as conversion or pattern matching (step S13). From the difference between these average coordinates dot GroupYA and dot GroupYB, the deviation amount timing Gap AB in the main scanning direction of the dot group corresponding to each recording head A, B is calculated (step S14).

Thereafter, the operation procedure according to steps S5 to S9 described above is performed.
The dot group deviation amount timing GapAB is compared with a predetermined standard value (step S5). If it is outside the rated value (NO), the ink ejection timing correction value pulseβ is calculated (step S6), and the carrier pulse variable pulse NumberAB is calculated. In addition, the ink discharge timing correction value pulse β obtained in step S6 is added to adjust the timing (step S7). The processing steps of Steps S11 to S14 and Steps S5 to S7 are print timing adjustment steps.

  On the other hand, if it is within the standard value in the comparison (YES), the carrier pulse variable pulse NumberAB and the design distance between the printheads head Distance Theoretical are read (step S8). The read design distance between recording heads, head Distance Theoretical, is divided by pulse Number AB to determine the carriage conveyance amount per one carriage conveyance pulse (step S9). These processing steps S8 and S9 are image length adjustment steps.

  As described above, according to the present embodiment, in order to avoid the influence of expansion and contraction of the recording medium in the operation procedure corresponding to the serial printer, the dot group corresponding to the recording head A and the recording head B is the recording medium 12. The number of carriage transport pulses when overlapping in the main scanning direction at any upper position and the head-to-head design distance between the recording head A and the recording head B are used. Thereby, it is possible to obtain a carriage conveyance amount per one pulse of carriage conveyance with higher accuracy than a method using the distance between dot groups whose recording positions are separated from each other.

Next, a third embodiment will be described.
With reference to the flowchart shown in FIG. 11, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the third embodiment will be described. In the description of this embodiment, in the same operation procedure (steps S2 to S7) as in the first embodiment described above, the same step numbers are given to simplify the description. This embodiment is different from the first embodiment described above in that the distance between the print heads is changed from the design value to the actual measurement value. In FIG. 11, the arrangement interval from the actually measured first recording head position to the second recording head position is expressed as head Distance Real.

  First, the nozzle array of the recording head 2 is imaged using the CCD cameras 30A and 30B of the inter-head distance measuring device 29 shown in FIG. The processing control unit 18 performs image processing from the imaged image data of the nozzle row to obtain the position of the center of gravity of the nozzle. Based on the center-of-gravity position of the nozzle obtained here and the distance between the focal positions of the CCD camera 30, the average measured distance between nozzle rows head Distance Real is measured (step S21). The measured average distance between the nozzle rows is recorded in the data server or the storage unit 24 via a LAN (not shown) (step S22).

  Next, in step S22, the stored head distance real is read out, and the nozzle row distance measured value pulse AB Real, which is the number of transport pulses required for transporting the medium between any two recording heads A and B, is calculated. (Step S23). In this embodiment, the designed transport amount per pulse is set to one dot (84.5 μm), and the fraction generated when calculating the transport pulse number pulse AB Real from the head distance real is the ink ejection timing. Complement with the correction value pulse β ′. These processing steps S21 to S23 are a head distance measuring step.

  Next, the user inputs a recording command for the test recording medium 13 from the input unit 20. The printer control unit 14 performs a recording operation on the recording medium 12 in accordance with a recording command. In this recording operation, first, the pulse number AB Real and the ink ejection timing correction value pulse β 'are substituted into the transport pulse variable pulse NumberAB (step S24). Subsequently, when the number of pulses counted from the start of the recording operation reaches the carrier pulse variable pulse NumberAB, the recording operation by the recording head B is performed, and the test recording medium 13 is loaded as shown in FIG. Forms a dot group consisting of one or more dots for one line continuous in the sub-scanning direction (step S2).

   Next, the average coordinates dot GroupYA and dot GroupYB of the barycentric positions of the dot groups in the sub-scanning direction of the respective dot groups (dot number ≧ 1) corresponding to the recording heads A and B recorded on the test recording medium 13. Is extracted (step S3). Further, a deviation amount (sub-scanning direction coordinate difference) timing Gap AB of the dot group corresponding to each recording head 2 is calculated from the difference between the average coordinates dot GroupYA and dot GroupYB obtained in step S3 (step S4). ), And a predetermined standard value is compared (step S5). In this comparison, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6). By adjusting the ink ejection timing using the correction value pulse β, in the respective recordings A and B, the dot groups overlap each other at the recording position of any one dot group on the recording medium 12 in the sub-scanning direction. (Step S7). These processing steps S24 and S2-S7 are print timing adjustment steps.

  On the other hand, in the above comparison, if the value is within the standard value (YES), the storage unit 22 reads the carrier pulse variable pulse NumberAB and the storage unit 24 reads the average nozzle row distance actual measurement value (recording head actual measurement value) head Distance Real. (Step S25). The head distance real read in step S25 is divided by the pulse number AB to determine the medium transport amount per one medium transport pulse that is the image length adjustment value (step S26). These processing steps S25 and S26 are image length adjustment steps.

  As described above, in this embodiment, when calculating the image adjustment value, the distance between the recording heads is changed from the design value to the actual measurement value, so that the image length adjustment can be performed with higher accuracy than in the first embodiment described above. The value can be determined.

Next, a fourth embodiment will be described.
With reference to the flowchart shown in FIG. 12, an operation procedure of image length adjustment (calculation of the medium transport amount per pulse) according to the fourth embodiment will be described. In the description of the present embodiment, the same operation numbers (steps S1, S5-S9) as those in the first embodiment described above are denoted by the same step numbers, and the description is simplified.

  In the present embodiment, the medium conveyance distance per pulse of the number of medium conveyance pulses may periodically fluctuate due to the eccentricity of the conveyance roller. Due to the periodic conveyance distance unevenness, the formation of the test recording medium 13 shown in FIG. 5A causes the dot on the recording medium 12 when the dot group is recorded by the recording head A [2C] and the recording head B [2Y]. Each time the position is different, the number of medium transport pulses obtained from the pulse encoder 4 is also different. When the image length adjustment value calculated from the number of medium conveyance pulses obtained in this way is used, the accuracy is lowered.

  Therefore, in the present embodiment, due to uneven conveyance distance, a plurality of lines are drawn on the test recording medium 13a, and the average value of the obtained medium conveyance pulses is used for calculating the image length adjustment value. Prevents the accuracy of length adjustment from being reduced.

  First, at the design distance (head Distance Theoretical) μm between the recording head A and the recording head B, the designed number of transport pulses (pulse AB Theoretical) required for transporting the recording medium 12 is expressed by the transport pulse variable pulse. Substitute into NumberAB (step S1).

  Next, the dot group formed when determining the number of medium transport pulses is a test recording medium 13a in which at least four lines are drawn in the sub-scanning direction in accordance with the 1/4 cycle of the transport roller as shown in FIG. . In FIG. 15, L0 is a reference position, and Lr is a conveyance roller cycle length. That is, in the sub-scanning direction 1 on the recording medium at each pulse timing corresponding to the conveyance roller cycle length Lr × i / Nd (i = 1, 2, 3,..., Nd, Nd ≧ 4 and Nd / 2 = 0). Nd dot groups (number of dots ≧ 1) for the line are recorded from the recording head A. Thereafter, when the recording medium is conveyed by the pulse number AB, the recording is performed in the recording head B in the same manner. The recorded recording medium is read and processed (step S41). Then, as shown in FIG. 13, the average coordinates dot GroupYAi (i = 1, 2, 3,..., Nd) and dot GroupYBi (i = 1, 2, 3,. ) Is extracted (step S42).

  Next, as shown in FIG. 14, the average value dot Group Average YA of dot GroupYAi (i = 1, 2, 3,..., Nd) and dot Group YBi (i = 1, 2, 3,..., Nd). The average value dot group average YB is obtained (step S43). Thereafter, the sub-scanning direction coordinate difference timing Gap is obtained from the difference between the dot group average YA and the dot group average YB (step S44). That is, timing Gap AB = dot Group Average YA−dot Group Average YB.

  Thereafter, an operation procedure is performed according to the processing of steps S5 to S9 described above, and an image length adjustment value is obtained. The sub-scanning direction coordinate difference timing Gap AB is compared with a predetermined standard value (step S5). In this comparison, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6). By adjusting the ink ejection timing using the correction value pulse β, in the respective recordings A and B, the dot groups overlap each other at the recording position of any one dot group on the recording medium 12 in the sub-scanning direction. (Step S7). These processing steps S1, S41-44 and S5-S7 are print timing adjustment steps.

  On the other hand, if it is within the standard value in the comparison (YES), the carrier pulse variable pulse NumberAB and the design distance between the printheads head Distance Theoretical are read (step S8). The read design distance between recording heads, Head Distance Theoretical, is divided by pulse Number AB to determine the medium transport amount per pulse of medium transport (step S9). These processing steps S8 and S9 are image length adjustment steps.

  As described above, in the present embodiment, since the conveyance distance is uneven, a plurality of lines are drawn on the test recording medium 13a, and the average value of the obtained medium conveyance pulses is used to calculate the image length adjustment value. By utilizing this, it is possible to prevent a decrease in accuracy of image length adjustment.

  In the present embodiment, the recording head A and the recording head are continuously formed from the test pattern of the test recording medium 13 shown in FIG. 5A continuously for each conveyance roller cycle length 1 / Nd (Nd = 4) cycle shown in FIG. From B, the test pattern of the test recording medium 13a on which a plurality of dot groups are drawn is changed. In the present embodiment, four lines formed at a timing per quarter division of the circumference have been described as test pattern images as countermeasures for uneven conveyance due to roller eccentricity. However, the present invention is not limited to this. Since it suffices to divide it into a plurality, it is not limited to Nd = 4. Then, the average coordinate in the sub-scanning direction is obtained for all the recorded dot groups, and the sub-scanning direction coordinate difference timing Gap is obtained from the average value of all the recorded dot groups.

  Therefore, according to the present embodiment, in addition to the effects of the first embodiment described above, it is possible to cope with periodic fluctuations due to the eccentricity of the conveying roller, and to obtain the image length adjustment value with high accuracy.

Next, a fifth embodiment will be described.
With reference to the flowchart shown in FIG. 16, an operation procedure of image length adjustment (calculation of the medium transport amount per pulse) according to the fifth embodiment will be described. In the description of this embodiment, the same operation numbers (steps S1 and S5-S9) as those in the first embodiment described above are denoted by the same step numbers, and the description is simplified.

  As described above, the medium conveyance distance per medium conveyance pulse number may fluctuate due to uneven thickness of the conveyance belt. In this embodiment as well, a decrease in image length adjustment accuracy similar to the phenomenon described in the fourth embodiment occurs. In the present embodiment, the test pattern used in the fourth embodiment is applied to the entire recording area corresponding to the belt circumferential length in order to reduce the decrease in the accuracy of the image length adjustment caused by the conveyance distance unevenness due to the conveyance belt thickness unevenness. The pattern is changed to the expanded test recording medium 13b shown in FIG. In the test pattern of the test recording medium 13b, a dot group recorded from the recording head A and the recording head B is drawn continuously for every ¼ period of the conveying roller period, and the belt circumference is similar for each period. Is drawn over the entire recording area corresponding to.

  First, the designed transport pulse number pulseABTheoretical required for transporting the medium at the distance between any two recording heads A and B is substituted into the transport pulse variable pulse NumberAB (step S1). That is, pulse NumberAB = pulseABTheoretical.

  Next, sub-scanning on the recording medium 13 is performed at each pulse timing corresponding to the conveyance roller cycle length Lr × i / Nd (i = 1, 2, 3... Nd, where Nd ≧ 4 and Nd / 2 = 0). A dot group for one line in the direction (number of dots ≧ 1) Nd × Nr (NrILr × Nr ≦ natural number (including 0) in the sub-scanning direction length) is recorded from the head A (step S61). Incidentally, after the initial recording by the recording head A, the same recording is performed from the recording head B when the recording medium is conveyed by the pulse number AB.

  Further, image reading and image processing of the recorded recording medium 13 are performed, and the average coordinates dot GroupYAi (i = 1, 2, 3,..., Nd × Nr) and dot GroupYBi (i = 1, 2, 3,..., Nd × Nr) is extracted (step S62). Subsequently, an average value dot group AverageYA of dot GroupYAi (i = 1, 2, 3,..., Nd × Nr) and an average value dot group AverageYB of dot Group YBi (i = 1, 2, 3,..., Nd × Nr) Is obtained (step S63).

  Thereafter, the sub scanning direction coordinate difference timing Gap is obtained from the difference between the dot group average YA and the dot group average YB (step S64). That is, timing GapAB = dot Group Average YA−dot Group Average YB.

  From the difference between these average coordinates dot GroupYA and dot GroupYB, a displacement amount timing gap AB in the main scanning direction of the dot group corresponding to each recording head A and B is calculated and compared with a predetermined standard value (step S5). . In this comparison, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6). By adjusting the ink ejection timing using the correction value pulse β, in each of the recording heads A and B, each dot group overlaps the recording position of any one dot group on the recording medium 12 in the sub-scanning direction. (Step S7). These processing steps S1, S61-S64 and S5-S7 are print timing adjustment steps.

  On the other hand, if it is within the standard value in the comparison (YES), the carrier pulse variable pulse NumberAB and the design distance between the printheads head Distance Theoretical are read (step S8). The read design distance between recording heads, Head Distance Theoretical, is divided by pulse Number AB to determine the medium transport amount per pulse of medium transport (step S9). These processing steps S8 and S9 are image length adjustment steps.

  In this embodiment, a recording area corresponding to the belt circumference is secured using a continuous recording medium, but the present invention is not limited to this, and is not limited to this. The image length adjustment can also be performed using a sheet.

  Therefore, according to the present embodiment, in addition to the effects of the first embodiment described above, in addition to the periodic fluctuation due to the eccentricity of the conveyance roller, the high recording area corresponding to the entire recording area over the belt circumference is provided. The image length adjustment value can be obtained with high accuracy.

Next, a sixth embodiment will be described.
With reference to the flowchart shown in FIG. 18, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the sixth embodiment will be described. In the description of the present embodiment, the same operation numbers as those in the first embodiment (steps S1 and S3-S9) are given the same step numbers to simplify the description.

  Normally, the pickup roller 11 is rotated when the recording medium 12 is conveyed from the recording medium supply unit 9 to the conveying mechanism 6. At this time, when the medium conveyance speed (roller rotation speed) by the pickup roller 11 is lower than the medium conveyance speed of the conveyance mechanism 6, the recording medium 12 moves away from the pickup roller 11 (from the contact state to the non-contact state). The conveyance speed of the recording medium 12 changes momentarily. Further, when the angle in the conveyance direction of the recording medium 12 by the pickup roller 11 and the angle in the conveyance direction by the conveyance mechanism 6 are misaligned, the recording medium 12 is distorted. Due to this distortion, when the recording medium 12 moves away from the pickup roller 11, the recording medium 12 works to return to its original shape, and vibration occurs in the recording medium 12 for a moment. When image recording is performed at such “instant”, there may be a deviation in the position of the dot group formed in the sub-scanning direction. In the present embodiment, in order to prevent this deviation, a test pattern in which the recording head 2 does not perform recording at the moment when the recording medium 12 leaves the pickup roller 11 is used.

  First, the designed transport pulse number pulseABTheoretical required for transporting the medium at the distance between any two recording heads A and B is substituted into the transport pulse variable pulse NumberAB (step S1).

  Next, after a dot group (dot number ≧ 1) for one line in the sub-scanning direction is recorded on the recording medium 13 from the recording head A, recording is also performed from the recording head B when the recording medium is conveyed by the pulse number AB. . However, the distances between the pickup roller 11 and the recording heads A and b are set as drA and drB. At this time, the dot group is not recorded on the recording medium 13 around the positions of the distances drA and drB from the trailing edge to the leading edge (step S81).

  Then, the process of step S3 thru | or S9 is performed. That is, image reading and image processing of the recorded recording medium is performed, and the average coordinates dot GroupYA and dot GroupYB in the sub-scanning direction of each dot group are extracted (step S3). Thereafter, the sub-scanning direction coordinate difference timing GapAB is obtained from the difference between dot GroupYA and dot GroupYB (step S4). This difference, that is, the deviation amount timing Gap AB is calculated and compared with a predetermined standard value (step S5). In this comparison, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6). By adjusting the ink ejection timing using the correction value pulse β, in the respective recordings A and B, the dot groups overlap each other at the recording position of any one dot group on the recording medium 12 in the sub-scanning direction. (Step S7). These processing steps S1, S81 and S5-S7 are print timing adjustment steps.

  On the other hand, if it is within the standard value in the comparison (YES), the carrier pulse variable pulse NumberAB and the design distance between the printheads head Distance Theoretical are read (step S8). The read design distance between recording heads, Head Distance Theoretical, is divided by pulse Number AB to determine the medium transport amount per pulse of medium transport (step S9). These processing steps S8 and S9 are image length adjustment steps.

  As shown in FIG. 19, in the present embodiment, when the distances from the pickup roller 11 to the recording head A [2C] and the recording head B [2Y] are drA and drB, respectively, the trailing edge on the recording medium 13 is shown. A test pattern in which recording by the recording head A is not performed at the position of the distance drA from the head toward the tip, and recording by the recording head B is not performed at the position of the distance drB.

  Therefore, even if a deviation occurs in the position of the dot group formed in the sub-scanning direction, the image length can be adjusted with a test pattern that is not affected by the deviation, and a more accurate image length adjustment value is obtained. Can do.

Next, a seventh embodiment will be described.
With reference to the flowchart shown in FIG. 20, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the seventh embodiment will be described. In the description of this embodiment, the same operation numbers (steps S2 to S9) as those in the first embodiment described above are denoted by the same step numbers, and the description is simplified.

  Usually, when the test recording medium 13 shown in FIG. 5A is output, the number of medium conveyance pulses required for medium conveyance between any two recording heads 2 is obtained. At this time, the closer the two arbitrary recording heads 2 are arranged in the sub-scanning direction, the shorter the number of medium transport pulses obtained, the more the sampling is performed in a shorter section, and the lower the image length adjustment accuracy.

  Therefore, in this embodiment, in order to improve the image adjustment accuracy, among the plurality of recording heads 2 provided, the two recording heads A and B that are the acquisition targets of the number of medium transport pulses are combinations having the maximum distance. And That is, any two recording heads 2 are defined so as to select a combination having the maximum distance between nozzle rows. In the system configuration example shown in FIG. 1, this rule is the combination of the recording head A [2C] and the recording head B [2Y], and the distance between the nozzle rows is the maximum, and the image length adjustment value is calculated for this combination. Do.

  First, a design pulse number pulseABTheoretical required for medium conveyance is substituted into a conveyance pulse variable pulse NumberAB at a distance between two recording heads A and B having a maximum distance between head nozzle arrays in a combination of a plurality of heads. (Step S91). That is, Pulse Number AB = pulse AB Theoretical.

  Then, the process of step S2 thru | or S9 is performed. That is, after a test pattern is recorded from the recording head A for a dot group (dot number ≧ 1) for one line in the sub-scanning direction on the recording medium, when the recording medium 13 is conveyed by the pulse number AB, the recording head B also Test pattern recording is performed (step S2). Image reading / image processing of the recorded recording medium is performed, and the average coordinates dot GroupYA and dot GroupYB in the sub-scanning direction of each dot group are extracted (step S3).

  Subsequently, sub-scanning direction coordinate difference timing GapAB is obtained from the difference between dot GroupYA and dot GroupYB (step S4). This difference, that is, the deviation amount timing Gap AB is calculated and compared with a predetermined standard value (step S5). In this comparison, if the dot group deviation amount timing GapAB is outside the standard value (NO), the ink ejection timing correction value pulseβ is calculated (step S6). By adjusting the ink ejection timing using the correction value pulse β, in the respective recordings A and B, the dot groups overlap each other at the recording position of any one dot group on the recording medium 12 in the sub-scanning direction. (Step S7). These processing steps S1, S81 and S5-S7 are print timing adjustment steps.

  On the other hand, if it is within the standard value in the comparison (YES), the carrier pulse variable pulse NumberAB and the design distance between the printheads head Distance Theoretical are read (step S8). The read design distance between recording heads, Head Distance Theoretical, is divided by pulse Number AB to determine the medium transport amount per pulse of medium transport (step S9). These processing steps S8 and S9 are image length adjustment steps.

  As described above, according to the present embodiment, by setting the arbitrary two recording heads 2 to the recording heads A and B having the maximum distance, the number of medium transport pulses obtained is sampled in the maximum interval. It is possible to obtain higher image length adjustment accuracy than other combinations of recording heads.

Next, an eighth embodiment will be described.
With reference to the flowchart shown in FIG. 21, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the eighth embodiment will be described. In addition, in the flowchart in FIG. The number of encoder pulses corresponding to the recording medium transport amount, which is the arrangement interval from the first recording head position to the second recording head position and from the first recording head position to the third recording head position, is pulse NumberAtBx (Bx = (Second recording head, third recording head). The shift amounts of the recording position of the second test pattern image with respect to the recording position of the first test pattern image and the recording position of the third test pattern image with respect to the recording position of the first test pattern image are respectively expressed as timing GapAtBx. The pulse correction amount corresponding to the recording position deviation amount is expressed as pulse βx. The total sum of the calculated pulse correction amounts is expressed as pulse Adjustment Total.

  Furthermore, the average value of the pulse correction amount in the number of recording heads for recording the test pattern image (a total of two recording heads, the second recording head and the third recording head) is expressed as pulse Adjustment Average. The arrangement interval between the two recording heads is expressed as head Distance Theoretical. The number of encoder pulses indicating the recording medium conveyance amount corresponding to the arrangement interval is expressed as (pulse Number Theoretical. The corrected encoder pulse number and the arrangement interval between the two recording heads are expressed as head Distance Theoretical. The adjustment value is expressed as image Length.

  In this embodiment, three or more recording heads are used to obtain an average value of correction encoder pulses, and this average value (which is a value common to each head group) is added to each encoder pulse amount, thereby achieving high accuracy. In this example, the image length adjustment value is obtained.

  In general, the recording head 2 has a situation in which ink discharge speed unevenness occurs in which the ink discharge speed is different for each recording head. For this reason, as an assumption for explanation, even in the case of a combination of a plurality of heads having the same distance, the number of medium transport pulses to be acquired is different for each combination of two recording heads to be acquired. .

  Therefore, in the present embodiment, in order to reduce the decrease in accuracy of acquiring the medium conveyance pulse number due to the uneven ink discharge speed for each recording head 2, among the provided recording heads 2, recording that is the acquisition target of the medium conveyance pulse number. The number of heads is set to three or more and the number of recording heads provided. In the present embodiment described below, the number of recording heads for which the number of medium transport pulses is to be acquired is provided with two or more recording heads Bx to be combined with this reference head with one recording head At as a reference. It is defined that the number of recording heads is equal to or less than the specified number. In this embodiment, for the sake of simplicity of description, the recording head Bx is described on the assumption that two or more recording heads are positioned downstream of the recording head At in the sub-scanning direction.

  First, for the combination of the recording head At and the other two or more recording heads Bx (Bx = A, B, C,..., Nh, At ≠ Bx), the designed transport required for transporting the medium at the distance between the recording heads. The pulse number pulseAtBx Theoretical is assigned to each inter-head transfer pulse variable pulse NumberAtBx (step S101). That is, pulse number AtBx = pulseAtBx Theoretical (Bx = A, B, C,..., Nh, At ≠ Bx).

  Next, a storage variable for the total ink ejection timing correction value of each head is initialized (step S102). That is, pulse Adjustment Total = 0.

 Next, the number of transport pulses is set to Pulse Number Theoretical = pulseAtBx Theoretical, and the recording head arrangement interval is set to head Distance Theoretical = head DistanceAtBx Theoretical (step S103).

  Subsequently, after a dot group (number of dots ≧ 1) for one line in the sub-scanning direction is recorded on the recording medium 13 from the recording head A, each recording head Bx is transferred when the recording medium 13 is conveyed by the pulse number AtBx. Is also recorded (step S104). This is to perform the recording operation by the recording head Bx every time the pulse count number output from the pulse encoder 4 reaches each carrier pulse variable pulse NumberAtBx from the recording operation by the reference recording head At.

  Next, the image reading and image processing of the recording medium 13 on which the test pattern is recorded is performed, and the average coordinates dot GroupYAt and dot GroupYBx (Bx = A, B, C,..., Nh) of each dot group in the sub-scanning direction, respectively. Is extracted (step S105). Thereafter, each difference timing Gap AtBx in the sub-scanning direction coordinates is obtained from the difference between the dot GroupYAt and each dot GroupYBx (step S106). That is, timing GapAtBx = dot GroupYBx−dot GroupYAt (Bx = A, B, C,..., Nh, At ≠ Bx). This calculates the average coordinates in the sub-scanning direction for all the recorded dot groups. The sub-scanning direction coordinate difference timing GapAtBx is obtained for each combination of dot groups from the average values obtained here. In this embodiment, the timing GapAtBx is determined based on one recording head (= At), and the sub-scanning direction coordinate difference timing GapAtBx of each dot group combined with each other recording head is obtained.

  Further, it is determined whether or not the sub-scanning direction coordinate difference timing GapAtBx (Bx = A, B, C,..., Nh, At ≠ Bx) is equal to or less than a predetermined standard value (step S107). That is, timing GapAtBx ≦ standard value is determined. In this determination, each of the plurality of sub-scanning direction coordinate differences timing GapAtBx obtained for each combination of dot groups is compared with a standard value. If at least one of the values is outside the standard value in this determination (NO), the print timing of one of the recording heads that is not the reference is adjusted. That is, the ink ejection timing correction value pulse βx (Bx = βx) of the recording head Bx is calculated from the calculated timing GapAtBx (step S108).

  Next, the inter-head transfer pulse variable pulse NumberAtBx is set to pulse NumberAtBx + pulse / βx (step S109). However, Bx = βx = A, B, C,..., Nh, At ≠ Bx. Then, the sum of ink ejection timing correction values for all head combinations is stored (step S110). That is, pulse Adjustment Total and pulse βx are stored as the ink ejection timing correction value pulse Adjustment Total, and the process returns to Step S104. The processing steps from step S101 to step S110 are print timing adjustment steps.

  On the other hand, if the sub-scanning direction coordinate difference timing GapAtBx is equal to or smaller than the standard value in step S107 (YES), the average of the ink ejection timing correction values is calculated (step S111). That is, the average is obtained by dividing Pulse Adjustment Average = pulse Adjustment Total by the number of head combinations. Further, the image length adjustment value image Length is calculated by dividing the head distance theoretical by (pulse Number Theoretical + pulse Adjustment Average) to calculate the average of the ink ejection timing correction values.

Further, an average value pulse number average of the number of medium transport pulses is calculated from the transport pulse variable pulse NumberAtBx for each combination of the target recording heads, and an average head design distance head distance AtBx Theoretical Average is calculated from the head distance AtBx Theoretical between each head. (Step S112).
As described above, according to the present embodiment, the image length adjustment value can be obtained from the calculated pulse number average and head distance AtBx Theoretical average.

Next, a ninth embodiment will be described.
With reference to the flowchart shown in FIG. 22, an operation procedure of image length adjustment (calculation of medium transport amount per pulse) according to the ninth embodiment will be described. In addition, in the flowchart in 22, it describes as follows. The number of encoder pulses corresponding to the recording medium transport amount, which is the arrangement interval from the first recording head position to the second recording head position and from the first recording head position to the third recording head position, is pulse NumberAtBx (Bx = (Second recording head, third recording head).

  The arrangement interval between the first recording head and the second recording head is expressed as head DistanceAtBx (At is 1 and Bx is 2). The corrected encoder pulse number is expressed as pulse NumberAtBx [At is 1 and Bx is 2]. The first image length adjustment value is expressed as image LengthAtBx [At is 1 and Bx is 2].

  Further, the arrangement interval between the first recording head and the third recording head is expressed as head DistanceAtBx (At is 1 and Bx is 3). The corrected encoder pulse number is expressed as pulse NumberAtBx [At is 1 and Bx is 3]. The second image length adjustment value is expressed as image LengthAtBx [At is 1 and Bx is 3]. The average value of the image length adjustment values is expressed as image Length Average. This embodiment is an example in which three or more recording heads are used to obtain an average value of the image length adjustment values obtained from the combination of the heads, and the average value is used as the image length adjustment value.

  In the print timing adjustment process of this embodiment, the same operation procedure (step S101, step S104 to step S109) as that of the above-described eighth embodiment is given the same step number, and the description is simplified. In the present embodiment described below, as in the eighth embodiment, two or more recording heads Bx to be combined with this reference head are used on the basis of one recording head At, and the number is equal to or less than the number provided. Stipulated as a recording head. In this embodiment, for the sake of simplicity of description, the recording head Bx is described on the assumption that two or more recording heads are positioned downstream of the recording head At in the sub-scanning direction.

  First, for the combination of the recording head At and the other two or more recording heads Bx (Bx = A, B, C,..., Nh, At ≠ Bx), the designed transport required for transporting the medium at the distance between the recording heads. The pulse number pulseAtBx Theoretical is assigned to each inter-head transfer pulse variable pulse NumberAtBx (step S101).

  Next, after a dot group (number of dots ≧ 1) for one line in the sub-scanning direction is recorded on the recording medium 13 from the recording head A, each recording head Bx is transferred when the recording medium 13 is conveyed by pulse NumberAtBx. Is also recorded (step S104).

  Next, based on the test pattern recorded on the recording medium 13, the average coordinates dot GroupYAt and dot GroupYBx (Bx = A, B, C,..., Nh) of each dot group in the sub-scanning direction are extracted (step S105). ). Thereafter, each difference timing Gap AtBx in the sub-scanning direction coordinates is obtained from the difference between the dot GroupYAt and each dot GroupYBx (step S106).

  Further, it is determined whether or not the sub-scanning direction coordinate difference timing GapAtBx (Bx = A, B, C,..., Nh, At ≠ Bx) is equal to or less than a predetermined standard value (step S107). If at least one of the values is outside the standard value in this determination (NO), the print timing of one of the recording heads that is not the reference is adjusted. The ink ejection timing correction value pulse βx of the recording head Bx is calculated from the calculated timing GapAtBx (step S108). Next, the inter-head transfer pulse variable pulse NumberAtBx is set to pulse NumberAtBx + pulse / βx (step S109), and the process returns to step S104. The processing steps from step S101 to step S109 are print timing adjustment steps.

  If the sub-scanning direction coordinate difference timing GapAtBx is equal to or smaller than a predetermined standard value in the determination in step S107 (YES), the pulse number AtBx of each recording head AtBx and the nozzle row distance design value head DistanceAtBx Theoretical (stored in advance). Are calculated from the distance data between the heads (step S121).

  Next, an image length adjustment value for each combination of recording heads is calculated (step S122). That is, image LengthAtBx = head DistanceAtBx Theoretical / pulse NumberAtBx (Bx = A, B, C,..., Nh, At ≠ Bx).

Here, a variable for substituting the total image length adjustment value for each print head combination obtained is initialized (step S123). For example, image Length Total = 0. Subsequently, all the image length adjustment values for each combination of recording heads are summed (step S124). This is image length total = image length total + image length AtBx (Bx = A, B, C,..., Nh, At ≠ Bx). Further, an average image length adjustment value is obtained (step S125). Average image length adjustment value Image Length Average = image Length Total / number of recording head combinations.
As described above, according to the present embodiment, the image length adjustment value can be obtained by dividing the calculated image Length Total by the number of combinations of recording heads.

In each of the embodiments described above, the following is defined.
The main scanning direction is the recording medium width direction or the carriage conveyance direction (serial printer). The sub-scanning direction is a recording medium conveyance direction or a direction perpendicular to the carriage conveyance direction.
-Print timing adjustment sets ink ejection timing for each head so that each color dot overlaps without misalignment when recording from the respective recording heads at the same position in the sub-scanning direction (or carriage conveyance direction) on the recording medium. Means adjustment. (However, for example, the adjustment unit is 1/32 dots.)
-The conveyance pulse (recording medium conveyance pulse for line printers and carriage conveyance pulse for serial printers) is rotated at the rotation cycle when the recording medium conveyance roller (or carriage conveyance roller for serial printers) is rotated in the line printer. The signals are output together. In the present embodiment, the transport amount per pulse is one dot (84.5 μm) in terms of design when all the parts constituting the transport mechanism are formed with theoretical values.

  The design distance between any two heads AB refers to the distance between the nozzles of any two recording heads A and B in the design (or actual measurement). In particular, if not specified, the recording heads A and B (and C, D,..., Nh) are arranged at different positions on the carriage in the sub-scanning direction (main scanning direction in the case of a serial printer). And

  The image length adjustment value is the recording medium / carriage conveyance amount per pulse (of pulses output in accordance with the rotation amount of the conveyance roller). If there is an error in the transport amount per pulse, when a line is drawn in the sub-scanning direction, a gap or a line in which the dots overlap is drawn between the dots. As a result, since the line becomes more stretched than the image data input in the sub-scanning direction of the recording medium, an adjustment value for performing this correction is suggested.

As described above, each embodiment has the following effects.
1) The accuracy of the recording medium is prevented from being reduced due to expansion and contraction due to moisture or the like, and the medium conveyance amount is obtained with high accuracy. In obtaining the medium conveyance amount, in the present invention, the dot composed of one or more dots in the same direction corresponding to each of two arbitrary recording heads A and B arranged at different positions in the sub-scanning direction. The number of medium transport pulses when the group overlaps at an arbitrary position on the recording medium and the physical distance between the recording heads AB are used. This prevents a decrease in accuracy caused by expansion / contraction due to moisture or the like of the recording medium, as compared with the case where the number of medium conveyance pulses is obtained from the distance of the dot groups located on the recording medium. Furthermore, the present invention can also be used when the transport mechanism is configured to include a transport belt.

  2) In a line printer, a dot group consisting of one or more dots in the same direction corresponding to any two recording heads A and B arranged at different positions in the sub-scanning direction is formed on the recording medium. The number of carrier pulses when drawn at any one position in the sub-scanning direction is recorded, and then the design distance between any two recording heads AB is divided by the number of carrier pulses obtained previously. The value is the image length adjustment value.

  3) In a serial printer, a dot group consisting of one or more dots corresponding to one arbitrary line corresponding to two arbitrary recording heads A and B arranged at different positions in the main scanning direction is a recording medium. The number of carriage conveyance pulses when drawn at any one position in the main scanning direction is recorded. Next, the design distance between any two recording heads AB is determined by the number of carriage conveyance pulses obtained previously. A value obtained by dividing is used as an image length adjustment value.

  4) For high adjustment accuracy by actually measuring the distance between the heads, the distance between any two heads is set as the actually measured distance in the first and second embodiments described above. In the actual measurement method, two CCD cameras are arranged at a predetermined position / height / tilt (directly below an arbitrary recording head to be measured) at which a head nozzle can be photographed and calibrated. The nozzle is photographed and the coordinates of the center of gravity are obtained by image processing. Then, it is calculated from the nozzle center-of-gravity coordinates obtained here and the distance between the CCD cameras.

  5) High adjustment accuracy by acquiring the number of pulses that invalidates measurement errors caused by uneven conveyance due to roller eccentricity. In the pulse number acquisition method in the first to third embodiments described above, at a timing at which the conveyance roller period length provided with the pulse encoder is divided at equal intervals and at least an even value Nd of 4 or more, When a dot group consisting of one or more dots is formed from two arbitrary recording heads A and B, and the dot groups for each recording head are drawn at Nd positions in the sub-scanning direction on the recording medium. Is the average of the number of pulses obtained.

  6) High adjustment accuracy by acquiring the number of pulses with reduced measurement error due to uneven belt thickness / uneven belt slip conveyance with respect to rollers. In the pulse number acquisition method in the fourth embodiment described above, the average number of pulses obtained when the conveyance roller cycle length × N times is repeated. Here, N is equal to or greater than 1 and less than a value obtained by the conveyance belt cycle length L2 / the conveyance roller cycle length L1 (integer value). If the recording area length in the sub-scanning direction exceeds the recording medium length per sub-scanning direction, a plurality of recording media are used.

  7) Higher adjustment accuracy by acquiring pulses that invalidate measurement errors caused by uneven registration conveyance unevenness. In the pulse number acquisition methods of the first to fifth embodiments described above, the moment when the trailing edge of the recording medium fed from the sheet feeding table passes through the feeding roller (from the trailing edge of the recording medium). A test pattern that is not recorded in the center of gravity of the paper feed roller and the distance between the nozzles of the ejection head) is formed in the leading direction.

  8) High adjustment accuracy by obtaining the number of pulses between two heads of the maximum head-to-head distance. When applied to the pulse number acquisition method and line printer of the first to third embodiments described above, the two most distant recording heads among the recording heads at different positions in the sub-scanning direction are used.

  9) A pulse number acquisition method in which measurement error due to uneven ink discharge speed is reduced. In the pulse number acquisition methods of the first to third embodiments described above, the average number of pulses obtained by combining two or more all the recording heads is used.

Each embodiment mentioned above contains the summary of the following invention.
A carriage movable along a predetermined direction;
A carriage moving means having a plurality of conveyance rollers for moving the carriage in the predetermined one direction, an endless belt stretched over the plurality of conveyance rollers, and an encoder for calculating a rotation amount of the conveyance rollers;
A plurality of recording heads arranged on the carriage at a plurality of different positions along the predetermined direction and having at least a first recording head and a second recording head for recording an image on a recording medium;
Image reading means (image reading device 15) for reading an image recorded by each recording head;
Control means [image processing / control / calculation unit (processing control unit) 18] for correcting the recording timing of each recording head and controlling the recording timing of each recording head based on the image information read by the image reading unit; ,
In a method for calculating a carriage movement amount correction value in an image recording apparatus having:
A first recording step of recording a first test pattern image (test pattern: dot group) on the recording medium at an arbitrary position in the recording medium conveyance direction by the first recording head; and (step S2).
After counting the number of encoder pulses (pulse Number AB) corresponding to the carriage movement amount corresponding to the arrangement interval from the first recording head position to the second recording head position from the image recording timing by the first recording head, the second recording head A second recording step of recording a second test pattern image (test pattern: dot group) on the recording medium by (step S2)
A step of reading each test pattern image recorded on a recording medium by the image reading means; (step S3)
Based on the recording position of each test pattern image read by the image reading means, the test pattern images recorded by the recording heads are recorded at the same position in the predetermined one direction. A step of correcting the number of encoder pulses; (steps S4, S6, S7)
Calculating a carriage movement amount correction value (image length adjustment value) for a predetermined pulse from the encoder from a ratio between an arrangement interval between the first recording head and the second recording head and a corrected encoder pulse number; (Steps S8, S9)
A conveyance amount correction value calculation method characterized by comprising: The above supplementary notes are applied to a serial printer (second embodiment).

  DESCRIPTION OF SYMBOLS 1 ... Printer (image recording device), 2 ... Recording head, 3 ... Carriage, 4 ... Pulse encoder, 5 ... Conveying roller, 6 ... Conveying mechanism, 7 ... Conveying belt, 8 ... Fan, 9 ... Recording medium supply part, 10 DESCRIPTION OF SYMBOLS ... Recording medium cassette, 11 ... Pickup roller, 12 ... Recording medium, 13 ... Test recording medium, 14 ... Printer control part, 15 ... Image reading apparatus, 16 ... Image reading control part, 17 ... Image reading part, 18 ... Image processing / Control / calculation unit (processing control unit), 19 ... display unit, 20 ... input unit, 22 ... printer storage unit, 23 ... calculation processing unit, 24 ... storage unit, 25 ... pulse number storage region, 26 ... image data Storage area 27: Distance between heads storage area, 28: Test pattern storage area, 29 ... Distance measurement apparatus between heads, 30 ... CCD camera, 31 ... Stage, 32 ... Carriage support base.

Claims (6)

A transport unit having a plurality of transport rollers arranged along the transport direction of the recording medium, and an encoder for calculating a rotation amount of the transport roller;
At least a first recording head that records images based on the number of pulses output from the encoder on the recording medium that is arranged at a plurality of different positions in the conveyance direction of the recording medium and that is conveyed by the conveying unit. A plurality of recording heads including a second recording head;
Image reading means for reading an image recorded by each recording head;
Control means for correcting the recording timing of each recording head based on the image information read by the image reading means, and for controlling the recording timing of each recording head;
A conveyance amount correction value calculation method in an image recording apparatus having:
A first recording step of recording a first test pattern image on a recording medium at an arbitrary position in the transport direction by the first recording head;
After counting only the number of encoder pulses corresponding to the recording medium conveyance amount corresponding to the arrangement interval from the first recording head position to the second recording head position from the image recording timing by the first recording head, the second recording head A second recording step of recording a second test pattern image on the recording medium at the same position as the arbitrary position and at a different position in the width direction of the recording medium,
An image reading step of reading each test pattern image recorded on a recording medium by the image reading means;
A correction amount calculating step of calculating a recording position deviation amount in the conveyance direction of the recording medium of each test pattern image read by the image reading unit, and calculating a pulse correction amount corresponding to the recording position deviation amount;
The encoder pulse number is corrected by adding the pulse correction amount to the encoder pulse number so that the test pattern images recorded by the recording heads are recorded at the same position in the transport direction. A correction step to
An adjustment value calculating step for calculating an image length adjustment value composed of a recording medium conveyance amount per pulse from a ratio between an arrangement interval between the first recording head and the second recording head and a corrected encoder pulse number; ,
A conveyance amount correction value calculation method characterized by comprising: A head interval measuring means for directly measuring an interval between the first recording head and the second recording head;
In the second recording step, a second test pattern is calculated after counting the number of encoder pulses calculated based on the arrangement interval from the first recording head position to the second recording head position measured by the head interval measuring means. The conveyance amount correction value calculation method according to claim 1, wherein an image is recorded. In the first recording step and the second recording step, one rotation of the conveyance roller is set to one circumference, and 1 / N (N is an integer of 2 or more) of the number of pulses generated in one rotation. Based on the image recording timing based on the number of generated pulses, test pattern images each consisting of N images are recorded over a recording area corresponding to the circumference of the conveying roller,
Before Kiho positive amount calculating step calculates the average value of the recording position in the recording medium conveying direction in N images constituting the test pattern image for each of the test pattern image, the deviation of the average value of the test pattern image 2. The conveyance amount correction value calculation method according to claim 1, wherein a pulse correction amount corresponding to the amount is calculated. The first recording step and the second recording step are performed over the entire recording area of the cut sheet-like recording medium having the maximum recording area that can be used in the image recording apparatus at a predetermined interval and at a plurality of image recording timings. And recording a test pattern image composed of a plurality of images,
Before Kiho positive amount calculating step calculates the average value of the recording position in the recording medium conveying direction in the plurality of images constituting the test pattern image for each of the test pattern image, the deviation of the average value of the test pattern image 2. The conveyance amount correction value calculation method according to claim 1, wherein a pulse correction amount corresponding to the amount is calculated. The conveying means is
A first conveyance mechanism comprising the conveying roller,
Than the first conveyance mechanism is disposed in the recording medium conveyance direction upstream side, and a second transfer mechanism comprising a pickup roller for conveying the recording medium to the first transport mechanism, and
The first recording step and the second recording step include an interval between a recording position for recording each test pattern image and a rear end in a conveyance direction on the recording medium, a position of a pickup roller in the second conveyance mechanism, and each recording head. 2. The transport amount correction value calculation method according to claim 1, wherein each test pattern image is recorded in a recording area on a recording medium other than a position where the interval with the position coincides. An interval in the recording medium conveyance direction between the first recording head and the second recording head is disposed so as to be widest with respect to an interval between other recording heads.
In the first recording step and the second recording step, each test pattern image is recorded using a first recording head and a second recording head having the widest head spacing among the plurality of recording heads. The conveyance amount correction value calculation method according to claim 1.

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