The present invention relates to a printing apparatus that performs printing with a plurality of printing heads spaced away in a transportation direction of a print medium.
Examples of the currently-used printing apparatus of this type include a printer provided with printing heads, first and second guide rollers, a rotary encoder, and a drive roller (see, for example, Japanese Unexamined Patent Publication 2010-158814).
In the printer, the first guide roller, the second guide roller, and the drive roller are disposed in this order from upstream on a transportation path for web paper, and the printing heads are disposed between the first and second guide rollers. Here, printing is performed while discharge timings of ink droplets from the printing heads are controlled in accordance with a transportation speed of the web paper.
The transportation speed of the web paper and the discharge timings of the ink droplets from the inkjet heads influence printing quality. Accordingly, the transportation speed of the web paper is determined by detecting a number of rotations of the second guide roller downstream of the printing heads with a rotary encoder, and the discharge timings from the printing heads are each adjusted based on the transportation speed. This allows accurate detection of change in transportation speed adjacent to the printing heads and thus allows adjustment of the discharge timings of the ink droplets. This achieves suppression of misregister caused by the variation in transportation speed, leading to enhanced printing quality.
However, the example of the currently-used apparatus with such a construction has the following drawback.
That is, the currently-used apparatus performs printing based on indirect information from the rotary encoder although the discharge timings of the ink droplets are adjusted based on the transportation speed of the web paper. As a result, misregister caused by the change in transportation speed of the web paper may possibly remain. Especially, the printer with high resolution may possess a drawback that extremely minute residue of the misregister causes degraded printing quality.
The present invention has been made regarding the state of the art noted above, and its one object is to provide a printing apparatus that allows suppression of extremely minute misregister, caused by a change in transportation speed, and enhanced printing quality by directly obtaining information on the transportation speed from a print medium.
In order to accomplish the above object, the present invention adopts the following construction.
One aspect of the present invention provides a printing apparatus that performs printing onto a print medium. The printing apparatus includes a transporting device; a plurality of printing head; a photographing unit; a shift detecting chart forming device; and a correcting device. The transporting device transports a print medium. The printing heads are spaced away from one another in a transportation direction of the print medium and print an image onto the print medium. The photographing unit photographs the print medium onto which the printing is performed with the printing heads. The shift detecting chart forming device forms a shift detecting chart having a first line segment group and a second line segment group. The first line segment group consists of first line segments printed onto the print medium at given intervals in an orthogonal direction with respect to the transportation direction with a reference printing head of the printing heads for a reference printing position in the transportation direction. The second line segment group is formed along the first line segment group, and consists of second line segments printed with a subsequent printing head of the printing heads spaced away from the reference printing head in the transportation direction in such a way that distances to the first line segments become small sequentially and then distances becomes large sequentially in a direction from one of the first line segments to another one of the first line segments, or in such a way that distances to the first line segments become large sequentially and then distances becomes small sequentially in a direction from one of the first line segments to another one of the first line segments. The correcting device corrects a printing timing with the subsequent printing head relative to the reference printing head in accordance with a density variation of the shift detecting chart photographed with the photographing unit.
With the above aspect of the present invention, in the shift detecting chart formed by the shift detecting chart forming device, an overlap between the first line segment group and the second line segment group is variable as a transportation speed of the print medium by the transporting device changes. Accordingly, a portion with high density or a portion with low density is shifted toward one side of the shift detecting chart. The correcting device corrects the printing timing with the subsequent printing head relative to the reference printing head in accordance with the density variation of the shift detecting chart photographed with the photographing unit. Consequently, information on the transportation speed of the print medium is directly obtainable from the shift detecting chart. This allows enhanced printing quality along with suppression in extremely minute misregister caused by the change in transportation speed.
Moreover, it is preferred in the aspect of the present invention that the shift detecting chart forming device forms the shift detecting chart following a printing start mark printed beyond a printing area of the print medium.
The shift detecting chart is formed beyond the printing area. This eliminates an influence on the image within the printing area. In addition, an image and the like formed on an opposite surface of the print medium may cause no problem upon reading the density. Consequently, accurate correction is performable based on a density variation.
Moreover, it is preferred in the aspect of the present invention that the correcting device corrects the printing timing in accordance with one of color components into which the shift detecting chart photographed with the photographing unit is decomposed.
Decomposing the color-photographed shift detecting chart into the color components allows clear density distinguishment in one of the components. Consequently, the density variation is easily visible and thus accurate correction is performable.
Moreover, it is preferred in the aspect of the present invention that the correcting device corrects the printing timing in accordance with an average value of shade levels of the line segments in one of the color components in a length direction.
The average value of the shade levels of the line segments in the length direction is calculated, and the printing timing is corrected in accordance with the average value. This allows accurate correction of the printing timing even when the components have different densities.
Moreover, it is preferred in the aspect of the present invention that the correcting device corrects the printing timing in accordance with a blue component of the color components in the shift detecting chart photographed with the photographing unit.
It is assumed that the shift detecting chart is formed in black and yellow. Under such assumption, when the color-photographed shift detecting chart is decomposed into components of R (red), G (green), and B (blue), density is clearly distinguished in the blue component. Consequently, the density variation is easily visible and thus accurate correction is performable.
Moreover, it is preferred in the present invention that the correcting device corrects the printing timing in accordance with an average value of shade levels in the blue component in the shift detecting chart in the length direction.
The average value of the shade levels of the line segments in the length direction is calculated, and the printing timing is corrected in accordance with the average value. This allows accurate correction of the printing timing even when the component has different densities.
For the purpose of illustrating the invention, there are shown in the drawings several forms which are presently preferred, it being understood, however, that the invention is not limited to the precise arrangement and instrumentalities shown.
The following describes one embodiment of the present invention with reference to drawings.
The inkjet printing system according to one embodiment of the present invention includes a paper feeder 1, an inkjet printing apparatus 3, and a take-up roller 5.
The paper feeder 1 holds the web paper WP in a roll form to be rotatable about a horizontal axis. The paper feeder 1 unwinds the web paper WP to feed the web paper WP to the inkjet printing apparatus 3. The take-up roller 5 winds up the web paper WP printed by the inkjet printing apparatus 3 about a horizontal axis. Regarding the side from which the web paper WP is fed as upstream and the side to which the web paper WP is taken up as downstream, the paper feeder 1 is disposed upstream of the inkjet printing apparatus 3 whereas the take-up roller 5 is disposed downstream of the inkjet printing apparatus 3.
The inkjet printing apparatus 3 includes a drive roller 7 upstream thereof for taking in the web paper WP from the paper feeder 1. The web paper WP unwound from the paper feeder 1 by the drive roller 7 is transported downstream toward the take-up roller 5 along transport rollers 9. A drive roller 11 is disposed between the most downstream transport roller 9 and the take-up roller 5. The drive roller 11 feeds the web paper WP transported on the transport rollers 9 toward the take-up roller 5.
Here, the inkjet printing apparatus 3 corresponds to the “printing apparatus” in the present invention. The drive rollers 7 and 11 and the transport roller 9 correspond to the “transporting device” in the present invention. The web paper WP corresponds to the “print medium” in the present invention.
The inkjet printing apparatus 3 further includes a print unit 13, a drier 15, and an inspecting unit 17 in this order from upstream thereof between the drive rollers 7 and 11. The drier 15 dries portions printed by the print unit 13. The inspecting unit 17 collects images on a print surface, and inspects the images for any stains or omissions.
The inspecting unit 17 corresponds to the “photographing unit” in the present invention.
The print unit 13 has a plurality of printing heads 19 for discharging ink droplets. In the present embodiment, four printing heads 19 are provided as one example.
The printing heads 19 are formed by a printing head 19a, a printing head 19b, a printing head 19c, and a printing head 19d in this order from upstream thereof. In this specification, when the printing heads 19 should be identified individually, an alphabetical numeral (e.g., a) is applied to the numeral 19. Otherwise, only the numeral 19 is indicated. The printing heads 19 each have a plurality of inkjet nozzles 21 for discharging ink droplets individually. The inkjet nozzles 21 are arranged in a transportation direction of the web paper WP and in an orthogonal direction relative to the transportation direction of the web paper WP. The printing heads 19a to 19d discharge ink droplets in at least two colors, and allows multi-color printing on the web paper WP. For instance, the printing head 19a discharges ink droplets in black (K), the printing head 19b discharges ink droplets in cyan (C), printing head 19c discharges ink droplets in magenta (M), and the printing head 19d discharges ink droplets in yellow (Y). The printing heads 19a to 19d are each spaced away from one another at given intervals in the transportation direction with respect to a position of the printing head 19a that discharges ink droplets in black (K).
A controller 25 includes a CPU and a memory not shown. The controller 25 receives print data from an external computer, not shown, and converts the print data into print-processing data. Thereafter, the controller 25 operates the drive rollers 7 and 11 to transport the web paper WP while the printing heads 19 discharge ink droplets in accordance with the print-processing data, whereby images based on the print data are printed on the web paper WP. The controller 25 stores in advance the print-processing data on the shift detecting chart for detecting the transportation speed of the web paper WP in the transportation direction. When an operator of the inkjet printing system issues a command to print the shift detecting chart, the controller 25 reads the print-processing data on the shift detecting chart, and the controller 25 operates the drive rollers 7, 11 and the printing heads 19 to print the shift detecting chart on the web paper WP.
A correcting unit 27 calculates a correction value for a shift obtained with the shift detecting chart, which is to be mentioned later. The calculated correction value is transmitted to the controller 25. The controller 25 sequentially corrects a timing of discharging the ink droplets from the printing heads 19 depending on the correction value in accordance with the print-processing data.
The correcting unit 27 corresponds to the “correcting device” in the present invention.
As illustrated in
The following describes the shift detecting chart DC with reference to
The shift detecting chart DC includes a first line segment group L1g and a second line segment group L2g. The first line segment group L1g consists of line segments L1 printed on the web paper WP at given intervals in an orthogonal direction relative to the transportation direction by a printing head 19a. The printing head 19a performs first discharge among the four printing heads 19 to the web paper WP with ink droplets in black (K). The second line segment group L2g consists of second line segments L2 printed by a printing head 19d that is disposed most downstream of the four printing head 19 in the transportation direction away from the printing head 19a, and discharges ink droplets in yellow (Y). The second line segment group L2g is formed along the first line segment group L1g in such a way that distances d between the second line segments L2 and the first line segments L1 become sequentially small toward downward and then become sequentially large.
The second line segment group L2g in the shift detecting chart DC that consists of second line segments L2 may be formed along the first line segment group L1g in such a way that distances d to the first line segment L1 become large sequentially from upstream toward downstream and then distances d to the first line segment L1 become sequentially small.
Here, the printing head 19a corresponds to the “reference printing head” in the present invention. The printing head 19d corresponds to the “subsequent printing head” in the present invention. Both the printing heads 19a and 19d correspond to the “shift detecting chart forming device” in the present invention.
Reference is now made to
The inspecting unit 17 photographs the shift detecting chart DC printed on the web paper WP. The inspecting unit 17 photographs the web paper WP containing the printing area PA over a width of the web paper WP to obtain image data, and inspects the printing area PA in accordance with the image data. In addition, in the present embodiment, the correcting unit 27 fetches a density distribution of the shift detecting chart DC from the image data obtained by the inspecting unit 17 as shade levels.
The correcting unit 27 detects the variation in transportation speed as a shift in accordance with a density (shade level) variation in the shift detecting chart DC for determining the correction value used for correcting the shift. Accordingly, the image data obtained by the inspecting unit 17 may be resolution lower than the printing resolution. As a result, this achieves a simplified inspecting unit 17, leading to suppression in apparatus cost.
With the present embodiment, when the transportation speed of the web paper WP by the drive rollers 7 and 11 and the transport roller 9 changes, an overlap amount of the first line segment group L1g and the second line segment group L2g changes, and a portion having a high density is moved toward one end of the shift detecting chart DC formed by the printing heads 19a and 19d. The correcting unit 27 corrects a printing timing with the printing head 19d relative to the printing head 19a in accordance with the density variation in the shift detecting chart DC obtained by the inspecting unit 17. Consequently, information on the transportation speed of the web paper WP is obtained directly from the shift detecting chart DC, achieving an enhanced printing quality while extremely minute misregister is suppressed caused by the variation in transportation speed.
The following describes a preferable process of the shift detecting chart DC with reference to
The correcting unit 27 receives the image data on the shift detecting chart DC from the inspecting unit 17. The image data is a color image as illustrated on the left of
Consequently, the density variation of the shift detecting chart DC is easily visible and thus accurate correction is performable.
In addition, as illustrated in
Determination of the shift in such a manner as above achieves accurate correction of the printing timing even with an uneven distribution of density in a length direction of the line segments L1 and L2 in the shift detecting chart DC.
The present invention is not limited to the foregoing examples, but may be modified as follows.
(1) In the embodiment mentioned above, the shift detecting chart DC has the first line segment L1 and the second line segment L2 formed in parallel as illustrated in
In this shift detecting chart DC, the first line segment group L1g is formed in the same manner as in the above embodiment. However, a second line segment group L2g is different from that in the above embodiment. Specifically, second line segments L2g each have a density inclination in a line segment direction of the first line segment group L1g. The density inclination divides lengths of the line segments L1 and L2 into five regions AR1 to AR5 in an orthogonal direction relative to the length direction, and generates a second line segment group L2g (density inclined line group) in such a way that the regions AR1 to AR5 each have a different portion with a high yellow (Y) density. Such a configuration obtains five density peaks with one shift detecting chart DC, and the shift is averaged from ever reference thereof. This allows accurate determination of the shift.
(2) In the embodiment mentioned above, the web paper WP has been described as one example of the print medium. However, the print medium is not limited to the web paper WP in the present invention. For instance, a paper sheet or a film is applicable.
(3) The embodiment mentioned above illustrates an inkjet type printing apparatus. However, a printing apparatus with printing heads spaced away in a paper-feed direction is applicable to the present invention.
(4) The embodiment mentioned above adopts the printing head 19a as the reference printing head. Alternatively, any of the printing heads 19b to 19c may be used as the reference printing head. Moreover, the above embodiments adopt the printing head 19d as the subsequent printing head. Alternatively, any of the printing heads 19a to 19d may be used as long as it is different from the reference printing head.
(5) In the embodiment mentioned above, the shift is distinguished based on the component B (blue) in the color image of the shift detecting chart DC. However, the present invention is not limited to this. If the ink droplets are formed by different colors other than KCMY, the shift may be determined based on a color component other than the component B (blue).
The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof and, accordingly, reference should be made to the appended claims, rather than to the foregoing specification, as indicating the scope of the invention.
Number | Date | Country | Kind |
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2015-066616 | Mar 2015 | JP | national |
Number | Name | Date | Kind |
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7384128 | Sheahan | Jun 2008 | B2 |
Number | Date | Country |
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2010-158814 | Jul 2010 | JP |