The present invention relates to a box producing apparatus that prints multiple colors on sheet faces, and particularly to a box producing apparatus and an inspection unit provided with units to correct registers (adjust registers) for the print colors, and a print register control method for a box producing apparatus.
Some box producing apparatuses that produce boxes from box material sheets (e.g., corrugated board sheets) include a feed section, a printing section, a slotter creaser section, a die cutting section, a folding section (folder gluer section), and a counter ejector section, in this order, from the upstream side. In such a box producing apparatus, a feed section is loaded with box material sheets, which are fed on a sheet by sheet basis, to a printing section, where multiple print units provided therein print respective colors. Then, slotting and scoring are performed by a slitter and a scorer in a slotter creaser section, and cutting is performed in a die cutting section. Then, in a folding section, after gluing is performed by a glue gun, folding and bonding are performed, and the resultant sheets are counted by a counter ejector section. The sheets are stacked into a stack of a certain number, and are transferred to the subsequent step. Note that other box producing apparatuses include no folding section, and sheets are cut in a die cutting section without being glued, folded, or bonded and the cut sheets are counted in a counter ejector section, followed by stacking to a certain number and a transferring to the subsequent step.
A technique has been developed for such a box producing apparatus, wherein a camera is provided in a main part in the box producing apparatus to capture an image of a pass sheet as a master image in advance. In operation of the box producing apparatus, an image of a sheet that went through each of the processes is captured by the camera, and the image of the sheet captured by the camera during the operation is compared against the master image to determine failures by inspecting the qualities of the print position, missing color, and the gluing position. For example, a print failure inspection unit is described in Patent Reference 1.
Further, another technique has been developed wherein an optoelectronic sensor, rotary encoder, or the like is provided in a main part in the box producing apparatus to determine failures in slotting lengths or die cutting positions after processing.
In order to improve the merchantability of produced corrugated board boxes, proper shaping of the boxes and proper processing of cut surfaces and the like are essential. To achieve these goals, slotting positions set by a slotter in a slotter creaser section, gluing positions set by a glue gun for gluing in a folding section, and the like are required to be precisely set. Further, precise positioning of printed pictures and letters (hereinafter, they are collectively referred to as pictures) is quite essential for improving the merchantability of corrugated board boxes.
Apparatuses that inspect product failures as described above, however, are only capable of removing failed articles from products for shipping good products only, but cannot prevent the failed articles from being produced.
Hence, in general, elements in a box producing apparatus are adjusted in advance by feeding a single test sheet. Then, an operator inspects the print positions and the like on the sheet, and makes the following five pre-adjustment by means of button operations:
(1) Adjustment of the index position (position in the print vertical direction) of each color print unit in a printing section;
(2) Adjustment of the position in the print width direction of each color print unit in the printing section;
(3) Adjustment of the index position for a slotter;
(4) Adjustment of the index position for a die cutting; and
(5) Adjustment of the gluing position by a glue gun.
Patent Reference 1: Japanese Laid-open Patent Publication No. 2001-315309
During a pre-adjustment for elements in a box producing apparatus as described above, the results of processing of a test-fed sheet is compared against a sample (reference), a deviation (amount of displacement) of the process result with respect to the sample is determined, and the positions of color print units in a printing section, a slotter, a die cutter, and a glue gun (print position, slotting position, cutting position, and gluing position) are adjusted based on the deviation.
After adjusting the positions of the elements, the positions (print position, slotting position, cutting position, and gluing position) are corrected according to the adjustments. Correcting the positions based on the amounts of displacements requires skill of an operator, and particularly making fine-adjustment for a great deviation to the sample is difficult even for a skillful operator, and multiple test feeds are required to match the test result to the sample.
Once a pre-adjustment is made, the results are stored for each order. By storing the results, the deviation between a test-fed sheet and a sample can be reduced when the stored adjustment values are preset for that order. Thus, a pre-adjustment can be completed after a single test feed. In the case of a new order, however, since an initial deviation is significant, multiple test feeds are required to be performed, which are burdensome to an operator and longer time period is required for the adjustment.
The present invention is made in light of the aforementioned issues, and an object thereof is to provide a box producing apparatus, an inspection unit, and a print register control method for a box producing apparatus that facilitate a pre-adjustment of the box producing apparatus, reduce the burden on an operator, and can manufacture boxes in a suitable and precise manner.
In order to achieve the above-identified object, a box producing apparatus of the present invention is a box producing apparatus comprising: a printing section comprising a plurality of print units; an image obtaining unit that obtains an image of a printed face which is printed on a box material sheet by the printing section; and a register correction control unit that compares a specific picture in a master image (master pattern) of a sample for the print, and the specific picture in the image of the printed face obtained by the image obtaining unit to determine an amount of register displacement in each of the print units, and controls a register adjustment mechanism provided in each of the print units based on the amount of register displacement to correct a register of the print.
Preferably, the register correction control unit detects the specific picture in a region of the printed face where the specific picture is specified to exist in advance based on the master image, and compares the specific picture detected in the printed image against a specific picture in the master image.
The specific picture is preferably a picture including at least an area where a plurality of colors do not overlap, and the register correction control unit preferably comprises a picture extracting section that extracts the specific picture.
Preferably, the box producing apparatus further includes an inspection unit comprising: an image obtaining section that is provided downstream of the printing section, and obtains an image of the printed face which is printed on a box material sheet by the printing section; and a pass/fail determining section that determines whether a printing is pass or fail based on the image of the printed face obtained by the image obtaining section, wherein the image obtaining unit uses the image obtaining section in the inspection unit, rather than a dedicated image obtaining section.
Preferably, the register correction control unit obtains the master image from print plate data.
Preferably, the register correction control unit determines the amount of register displacement using a pattern matching method. In this case, as the pattern matching method, for example, a technique such as a residual matching, that a residual of overlap determines to be minimum point, may be used while moving the position of a master pattern (master image) horizontally and vertically with respect to a target pattern (the obtained image of the printed face).
Preferably, the image obtaining unit obtains an image of a printed face printed on the box material sheet which has been test-fed through the box producing apparatus, and the register correction control unit corrects the print register, based on the image of the printed face obtained by the image obtaining unit, as a pre-adjustment before a production operation of the box producing apparatus.
Preferably, the box producing apparatus further includes a slotter creaser section that is provided downstream of the printing section and comprises a slitter that slots the box material sheet; a slotting position detection apparatus that detects a position slotted by the slitter; and a slotting position controller that compares the slotting position detected by the slotting position detection apparatus and a sample slotting position to determine an amount of displacement of the slotting position, and corrects a slotting position by controlling an index position adjustment mechanism provided in the slitter, based on the amount of displacement of the slotting position.
Preferably, the box producing apparatus further includes a die cutting section that is provided downstream of the slotter creaser section and cuts the box material sheet; a cutting position detection apparatus that detects a cutting position cut by the die cutting section; and a cutting position controller that compares the cutting position detected by the cutting position detection apparatus and a sample cutting position to determine an amount of displacement of the cutting position, and corrects a cutting position by controlling an index position adjustment mechanism provided in the die cutting section, based on the amount of displacement of the cutting position.
Preferably, the box producing apparatus further includes a glue machine that is provided downstream of the die cutting section and glues the box material sheet; a gluing position detection apparatus that detects a gluing position glued by the glue machine; and a gluing position controller that compares the gluing position detected by the gluing position detection apparatus and a sample gluing position to determine an amount of displacement of the gluing position, and corrects a gluing position by controlling an index position adjustment mechanism provided in the glue machine, based on the amount of displacement of the gluing position.
Further, an inspection unit of the present invention is an inspection unit provided in a box producing apparatus comprising a printing section comprising a plurality of print units, the inspection unit comprising: an image obtaining section that obtains an image of a printed face which is printed on a box material sheet by the printing section; and an inspection section that inspects whether a printing is pass or fail based on the image of the printed face obtained by the image obtaining section; a register correction control section that compares a specific picture in a master image of a sample for the print, and a specific picture in the image of the printed face obtained by the image obtaining section to determine an amount of register displacement in each of the print units, and outputs register correction information based on the amount of register displacement to a register adjustment mechanism provided in each of the print units.
Preferably, the register correction control section relates the amount of register displacement to print plate data related to an ink color and outputs the amount of register displacement.
Further, a print register control method for a box producing apparatus of the present invention is a method of adjusting a register for each of a plurality of print units in a box producing apparatus comprising a printing section comprising the print units, the method comprising: obtaining an image of a printed face which is printed on a box material sheet by the printing section; comparing a specific picture in a master image of a sample for the print, and the specific picture in the obtained image of the printed face to determine an amount of register displacement in each of the print units; and controlling a register adjustment mechanism provided in each of the print units to correct a register of the print based on the amount of register displacement.
In accordance with the box producing apparatus, the inspection unit, and the print register control method of the present invention, an amount of register displacement for each of the print units is determined by comparing a picture in the specified region within the obtained image of the printed face against the specific picture in the master image of the sample for print. Then, based on the amount of register displacement, a register adjustment mechanism provided in each print unit is controlled to correct the register for print. For example, by obtaining master image information, identifying a picture to be printed by each print unit from that master image information, and specifying a region including that picture in advance, a print image can be obtained by the image obtaining unit by test feeding a single box material sheet. Then, a picture in the specified region in the print image is compared against the specific picture in the master image, and an amount of register displacement for a print plate of each of the print units is determined by the register correction control unit. Based on that amount of register displacement, a register adjustment mechanism in each of the print units is controlled to automatically correct the register for print. Accordingly, a pre-adjustment of the box producing apparatus can be facilitated, and the burden on an operator can be reduced. Without requiring the skill of the operator, boxes can be manufactured suitably swiftly in shorter time.
Further, since the image obtaining section including the image obtaining section and the pass/fail determining section in the inspection unit is used as an image obtaining unit, the same unit can be used for both the register control and the pass/fail inspection. Hence, the advantage in that the apparatus design can be simplified and the effect in that the cost for the apparatus can be reduced, can be obtained.
Additionally, since master images can be obtained from print plate data which is available upon the order, appropriate master images can be obtained easily and the preciseness of the control can be improved, while reducing the human burden.
Further, by specifying the specific picture as a picture including at least an area where a plurality of colors do not overlap, an amount of register displacement is determined without an error for a print unit in interest. By automatically extracting such a specific picture by the register correction control unit, the specific picture can be easily set.
The amount of register displacement is determined in a reliable and precise manner since a pattern matching method is used for the determination.
Further, in addition to correction of the register for print, the position slotted by the slitter is detected, an amount of displacement of the slotting position is determined by comparing the detected slotting position against the sample slotting position, and the slotting position is corrected based on the amount of displacement. This can improve the quality of box production.
Further, the cutting position cut by the die cutting section is detected, an amount of displacement of the cutting position is determined by comparing the detected cutting position against the sample cutting position, and the cutting position is corrected based on the amount of displacement. This can also improve the quality of box production.
Similarly, the gluing position glued by the glue machine is detected, an amount of displacement of the gluing position is determined by comparing the detected gluing position against the sample gluing position, and the gluing position is corrected based on the amount of displacement. This can also improve the quality of box production.
Note that, the determined amount of register displacement is output while relating it to print plate data related to an ink color, and hence, a register for print can be corrected by controlling the register adjustment mechanism in the print unit related to that ink color, even when the combinations of print plates and print units having the print plate attached thereto are modified.
Hereinafter, embodiments of the prevent invention will be described with reference to the drawings.
Firstly, a box producing apparatus in accordance with the present embodiment will be described.
As shown in
The feed section 1 is introduced, having a large number of plate-shaped corrugated board sheets 10a loaded thereon, and the corrugated board sheets 10a are supplied to the printing section 2 on a sheet by sheet basis on a transfer conveyer 7.
The printing section 2 includes print units 2a-2d, each supplied for one of a certain number of print colors (four colors in this example), and in the printing section 2, each print color ink is sequentially printed to the corrugated board sheets 10a supplied on a sheet by sheet basis by the transfer conveyer 7. In the example shown in
The slotter creaser section 3 includes a slitter and a scorer, and the corrugated board sheets 10a that have been printed by the printing section 2 undergo slotting by the slitter and scoring by the scorer.
The die cutting section 4 cuts and removes unnecessary sections from the corrugated board sheets 10a by die cutting.
A glue gun is provided in the most upstream of the folding section 5. Glue is applied by the glue gun to one of transverse gluing edges of the corrugated board sheets 10a that have been printed, slotted, scored, and die-cut. The corrugated board sheet 10a are then folded such that the transverse gluing edges of the corrugated board sheets 10a overlap on the rear side (lower side), and the transverse gluing edges of the corrugated board sheets 10a are bonded together with the glue to produce box producing sheets 10.
In the counter ejector section 6, the box producing sheets 10 processed in the folding section 5 are stacked on a stacker, while being counted. Once a certain number of box producing sheets 10 are stacked, the resultant sheet group 100 is transferred to a subsequent step.
As shown in
Note that the pass/fail determining section 53 and the register correction control section 60 are configured as function elements in an inspection unit server (server computer) 52 in the present embodiment. However, the inspection unit 50 may be configured to have the camera 51 and the inspection unit server 52 including the pass/fail determining section 53, while the register correction control section 60 may be configured from hardware (a computer for register correction control) separately from the inspection unit server 52, when communicatively connected to the inspection unit server 52.
The pass/fail determining section 53 only determines whether or not a picture corresponding to the position corresponding to each picture in the master image is present in the image of the printed face, during a normal operation of the box producing apparatus. In contrast, the register correction control section 60 determines, during a preparation stage before the normal operation (during pre-adjustment), an amount of displacement of a print picture in the image of the printed face corresponding to the picture of each ink color in the master image according to a picture of the sample of the print picture, to calculate an amount to be corrected for correcting a register in the print plate, and correct the register in each of the print units 2a-2d.
Hereinafter, the configurations of the print units 2a-2d will be described briefly. As shown in
Upon printing using a box producing apparatus, unlike typical printing machines for offset print where print units to be used depend on ink colors, inks to be used are all special colors and inks are assigned to print units 2a-2d differently depending on the case. Accordingly, when ink colors are assigned to the print units 2a-2d, the ink colors are associated with the print units 2a-2d and the associations of ink colors with print pictures are maintained in print plate data.
As shown in
Next, the register correction control will be described.
The register correction control requires data of a master image of a sample for printing, and as shown in
Note that, that typical picture 202 is a picture which includes at least a region where multiple colors do not overlap, and is a picture where any other color is not present in the vicinity in the present embodiment. A picture which includes at least a region where multiple colors do not overlap, or a picture where any other color is not present in the vicinity, can be automatically extracted from plate making data as a region where multiple colors do not overlap or multiple colors are separated from each other. Although the register correction control section 60 extracts a typical picture 202 automatically (this function is referred to as a picture extracting section), the typical picture 202 may be selected manually, as a matter of course.
Although the region 213 including such a typical picture is automatically specified by the register correction control section 60 (this function is referred to as a region specifying section), the region 213 may also be manually set.
In the example shown, the “ABODE” where no other color ink is present in the vicinity is extracted from print data (first color data) 201a by a first print unit as a typical picture 202a, and a region 213a including this typical picture 202a with sufficient margins is selected and specified in search window data 211a. Similarly, the “OpqrStuv” where no other color ink is present in the vicinity is extracted from print data (second color data) 201b by a second print unit as a typical picture 202b, and a region 213b including this typical picture 202b with sufficient margins is selected and specified in search window data 211b. Similarly, the “FGIJKLMN” where no other color ink is present in the vicinity is extracted from print data (third color data) 201c by a third print unit as a typical picture 202c, and a region 213c including this typical picture 202c with sufficient margins is selected and specified in search window data 211c. Similarly, the “WXYZ” where no other color ink is present in the vicinity is extracted from print data (fourth color data) 201d by a fourth print unit as a typical picture 202d, and a region 213d including this typical picture 202d with sufficient margins is selected and specified in search window data 211d.
In contrast, the register correction control requires data of the image of the printed face (sensor image), which is printed using the print plate 24 based on print data, and the inspection unit server 52 obtains image data from the camera 51, as shown in
The register correction control section 60 in the inspection unit server 52 performs a resolution conversion to the resolution of the captured and recorded master image data, and specifies a reference position (absolute address X0 and Y0), as in search window data 211.
Once data (typical picture) 202 (202a-202d) in file data 201 (201a-201d) of the master image, and data (pictures corresponding to typical pictures) 212 (212a-212d) in search window data 211 (211a-211d) in the sensor image (the image of the printed face) are obtained in this manner, as shown in
There are a wide variety of known pattern matching methods to be applied, including, for example, a residual matching that a residual of overlap determines to be a minimum point while moving the position of a master pattern horizontally and vertically with respect to a target pattern, a normalization correlation method, a phase limiting correlation, a geometrical matching and the like.
That is, as shown in
In this manner, the register correction control section 60 in the inspection unit server 52 determines an index direction displacement and a width direction displacement (correctively referred to as “register displacement”) for each print unit, and generates and outputs a control signal corresponding to a control amount for canceling the displacement for a register adjustment mechanism provided in the printing cylinder 23 for each print unit, corresponding to the index direction displacement and the width direction displacement. Note that the relationship of an adjustment amount (control amount) of the position in the index direction of the print plate 24 to the index direction displacement, and the relationship of an adjustment amount (control amount) of the position in the width direction of the print plate 24 to the width direction displacement are stored in memory in the inspection unit server 52 or an external memory, and is refereed to upon generation of a control signal.
Note that this register correction control section 60 outputs the determined amount of register displacement while relating it to print plate data related to an ink color, and hence, a register for print can be corrected by controlling the register adjustment mechanism in the print unit related to that ink color, even when the combination of print plates and print units having the print plate attached thereto is modified.
Since the box producing apparatus and the inspection unit in accordance with the first embodiment of the present invention are configured as described above, as shown in
More specifically, firstly, before the normal operation preparation stage (during the pre-adjustment), a single sheet feed is commanded through a button operation of the box producing apparatus M, and only a single corrugated board sheet is test-fed (Step S10). In response, the box producing apparatus M performs print on the single corrugated board sheet 10a that is fed (Step S20). Note that the box producing apparatus M processes up to folding and edge bonding after the printing.
Once the print is performed on the corrugated board sheet 10a, the camera 51 in the inspection unit 50 captures the printed face (Step S30) and information of the captured print image is sent to the register correction control unit (register correction control section) 60 (Step S40).
The register correction control unit (register correction control section) 60 compares the print image (sensor image) and the master image, calculates the amount of register displacement (index direction amount of displacement and width direction amount of displacement) for each plate (Step S50), and correct the plate position by controlling the register correction mechanism in each print unit in the printing section, based on the calculated amount of register displacement (Step S60).
Note that, upon determining the amount of register displacement, instead of paying attention to ink colors, each of the print units 2a-2d and the specific picture (typical picture) 202 printed by the print unit are related to each other, and a region 213 where the other ink colors are absent is selected and specified such that there is a sufficient margin with respect to the typical picture 202. Since the specific picture is searched for within that region 213, the amount of register displacement is determined by suitably extracting a picture related to each of the print units 2a-2d from the data of the sensor picture.
Accordingly, in accordance with the present box producing apparatus, the present inspection unit, and the present print register control method, an amount of register displacement for each of the print units 2a-2d is determined by comparing a picture in the specified region within the obtained image of the printed face against the specific picture in the master image of the sample for print. Then, based on the amount of register displacement, a register adjustment mechanism provided in each of the print units 2a-2d is controlled to correct the register for print. For example, by obtaining master image information, identifying a picture to be printed by each print unit from that master image information, and specifying a region including that picture in advance, a print image can be obtained by the camera 51 by test feeding a single box material sheet. Then, a picture in a specified region in the print image is compared against the specific picture in a master image, and an amount of register displacement for a print plate of each of the print units 2a-2d is determined by the register correction control section 60. Based on that amount of register displacement, a register adjustment mechanism in each of the print units 2a-2d is controlled to automatically correct the resister in the print plate. Accordingly, a pre-adjustment of the box producing apparatus can be facilitated, and the burden on an operator can be reduced. Without requiring the skill of the operator, boxes can be manufactured suitably in shorter time.
Further, since the camera 51 in the inspection unit 50 including the camera (image obtaining section) 51 and the pass/fail determining section 53 is used as an image obtaining unit that supplies image information to a register correction control section (register correction control unit) 60, the same unit can be used for both the register control and the pass/fail inspection. Hence, the advantage in that the apparatus design can be simplified and the effect in that the cost for the apparatus can be reduced, can be obtained.
Additionally, since master images can be obtained from print plate data which is available upon the order, appropriate master images can be obtained easily and the preciseness of the control can be improved, while reducing the burden on the operator.
The amount of register displacement is determined in a reliable and precise manner since a pattern matching method is used for the determination.
Next, a second embodiment of the present invention will be explained with reference to
As shown in
Additionally, in addition to a register correction control section (register correction control unit) 60, the present embodiment is provided with a slotting position control section (slotting position controller) 61 that determines an amount of displacement of the slotting position by comparing the slotting position detected by the slotting position sensor 54 with the sample slotting position, and controls an index position adjustment mechanism (not shown) provided in the slitter in the slotter creaser section 3 based on the amount of displacement of the slotting position to correct the slotting position; a cutting position control section (cutting position controller) 62 that determines an amount of displacement of the cutting position by comparing the cutting position detected by the cutting position sensor 56 with the sample cutting position, and controls an index position adjustment mechanism (not shown) provided in the die cutting section 4 based on the amount of displacement of the cutting position to correct the cutting position; and a gluing position control section (gluing position controller) 63 that determines an amount of displacement of the gluing position by comparing the gluing position detected by the gluing position sensor 58 with the sample gluing position, and controls an index position adjustment mechanism (not shown) provided in the glue machine in the folding section 5 based on the amount of displacement of the gluing position to correct the gluing position.
Note that a camera may be employed for each of the sensors 54, 56, and 58, for example. In this case, the camera 51 is positioned such that the camera 51 can be used as the sensors 54, 56, and 58 immediately after the glue machine, which can reduce the cost and simplify the apparatus design.
In the case of the present embodiment, in addition to the correction of the register for print, the slotted position slotted by the slitter is detected, an amount of displacement of the slotting position is determined by comparing the detected slotting position against the sample slotting position, and the slotting position is corrected based on the amount of displacement. This can improve the quality of box production.
Further, the cutting position cut by the die cutting section 4 is detected, an amount of displacement of the cutting position is determined by comparing the detected cutting position against the sample cutting position, and the cutting position is corrected based on the amount of displacement. This can also improve the quality of box production.
Similarly, the gluing position glued by the glue machine is detected, an amount of displacement of the gluing position is determined by comparing the detected gluing position against the sample gluing position, and the gluing position is corrected based on the amount of displacement. This can also improve the quality of box production.
Although embodiments of the present invention have been described, the present invention is not limited to the embodiments described above and various modifications may be made without departing from the spirit of the present invention.
For example, although inspection units also function as the units that correct displacements in the elements to reduce the cost and simplify the apparatus design in the above embodiment, separate sensors (including cameras) 51, 54, 56, and 58 and separate control sections (controllers) 53, 55, 57, and 59 may be provided.
Further, while print color information are obtained from related print plate data for printing (print color information are obtained together with the print plate data) in the above embodiment, information on the print color may be manually supplied (e.g., may be entered by a human by means of entry buttons) in the absence of print color information.
The present invention can be applicable to a box producing apparatus that prints multiple colors on sheet faces and produces boxes, the box producing apparatus being provided with units to correct registers (adjust registers) for the print colors.
Number | Date | Country | Kind |
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2010-148179 | Jun 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/064870 | 6/29/2011 | WO | 00 | 3/13/2013 |