JP2017220816A - Image forming system and image forming method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming system and an image forming method that, when performing image formation by compositing objects in a plurality of pieces of print data on a single surface of a single sheet, can perform image formation by optimally using color reproduction areas included respectively in a plurality of color image forming apparatuses.SOLUTION: In printing a plurality of pieces of print data (job 1 and job 2) on a single surface of a single sheet, an image forming system determines whether color information included in the print data is close to a color reproduction area G1 of a master unit or a color reproduction area G2 of a slave unit (step S16). The image forming system allocates the job 1 and job 2 to the master unit and slave unit on the basis of a result of the determination (step S17 and S18), and forms different images based on the job 1 and job 2 in different areas on the single surface of the sheet.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an image forming system and an image forming method, and more particularly, to a tandem type image forming system configured by connecting a plurality of image forming apparatuses in series and an image forming method in the image forming system.

  There is a tandem image forming system in which a plurality of image forming apparatuses such as printers and copiers that form images on paper are connected in series. In this type of image forming system, for example, the image forming process on the front and back sides of the paper is performed by different image forming apparatuses so that the image is formed on the front and back sides of the paper with one image forming apparatus. In comparison, productivity can be improved.

  In an image forming system having a plurality of color image forming apparatuses, not limited to the tandem method, each of the plurality of color image forming apparatuses (hereinafter simply referred to as “image forming apparatus”) has a unique color reproduction. Have an area. For this reason, for the purpose of reproducing the same color in a plurality of image forming apparatuses, a common area is obtained by ANDing the color reproduction areas based on the plurality of color reproduction areas of the plurality of image forming apparatuses. The color reproduction region is generated and printed (for example, see Patent Document 1).

JP 2004-48815 A

  By the way, there is a case where image formation is performed by combining a plurality of print data (job) objects on the same side of the same sheet, such as label printing for forming an image on a sticky sheet having adhesiveness on the back side. In the case of performing image formation using a plurality of color image forming apparatuses having different color reproduction areas, the color information of each job is rounded into a common color reproduction area by color matching processing in the prior art described in Patent Document 1. Therefore, it is impossible to form an image by optimally using the color reproduction areas of each of the plurality of color image forming apparatuses.

  According to the present invention, when a plurality of print data objects are combined on the same side of the same sheet to form an image, the image formation is performed by optimally using the color reproduction regions of each of the plurality of color image forming apparatuses. An object of the present invention is to provide an image forming system and an image forming method.

In order to achieve the above object, an image forming system of the present invention includes:
A tandem image forming system configured by connecting a plurality of color image forming apparatuses having unique color reproduction regions in series,
A determination unit configured to determine which color information of the print data is close to which of the color reproduction regions of the plurality of color image forming apparatuses when printing a plurality of print data on the same surface of the same sheet;
A control unit that performs control for allocating a plurality of print data to a plurality of color image forming apparatuses based on the determination result and forming different images based on the plurality of print data in different regions on the same surface of the paper;
It is characterized by providing.

The image forming method of the present invention includes
An image forming method in a tandem image forming system configured by connecting a plurality of color image forming apparatuses having unique color reproduction regions in series,
When printing a plurality of print data on the same surface of the same sheet, it is determined which color information that the print data has is close to the color reproduction area that the plurality of color image forming apparatuses have,
Based on the determination result, a plurality of print data is allocated to a plurality of color image forming apparatuses, and different images based on the plurality of print data are formed in different areas on the same side of the sheet.

  By allocating a plurality of print data to a plurality of color image forming apparatuses based on the determination result of which color reproduction region the plurality of color image forming apparatuses have, the color information of each print data is allocated Rounding is performed to the color reproduction region of the color image forming apparatus. As a result, the rounding amount can be reduced as compared with the case where the area obtained by the logical product of the respective color reproduction areas is rounded into the common color reproduction area, and the color reproduction areas possessed by each of the plurality of color image forming apparatuses can be reduced. It is possible to form an image by using it optimally.

  According to the present invention, when an image is formed by synthesizing a plurality of print data objects on the same surface of the same sheet, the image formation is performed by optimally using the color reproduction regions of each of the plurality of color image forming apparatuses. It can be performed.

1 is a schematic diagram showing an overall configuration of a tandem image forming system according to an embodiment of the present invention. 1 is a system configuration diagram illustrating an example of a printing system that uses a tandem image forming system. FIG. 10 is a conceptual diagram when a common color reproduction area obtained by logical product of the color reproduction areas of the parent device and the child device is used for color matching processing. FIG. 5 is a conceptual diagram when a color reproduction area possessed by each parent device / child device is used for color matching processing. 6 is a flowchart illustrating an example of a label printing processing procedure according to the first exemplary embodiment in which an image is formed in units of one page. It is a figure which shows an example of the heterogeneous multiple imposition of 1 page. It is explanatory drawing about the color difference total amount calculated from the color matching process result of a monitor / master / slave. It is a figure which shows an example of the setting input user interface which performs a different kind | species imposition setting. 1 is a schematic diagram illustrating an overall configuration of a tandem image forming system that forms an image on roll paper. FIG. 10 is a flowchart illustrating an example of a label printing processing procedure according to the second embodiment for forming an image on roll paper. It is a figure which shows the pattern 1 of the different surface imposition in roll paper. It is a figure which shows the pattern 2 of the different imposition on roll paper.

  Hereinafter, modes for carrying out the present invention (hereinafter referred to as “embodiments”) will be described in detail with reference to the drawings. The present invention is not limited to the embodiment, and various numerical values in the embodiment are examples. In the following description and each drawing, the same reference numerals are used for the same elements or elements having the same functions, and duplicate descriptions are omitted.

[Overall configuration of tandem image forming system]
An outline of a tandem image forming system according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic diagram showing the overall configuration of a tandem image forming system according to an embodiment of the present invention.

  The image forming system 1 according to the present embodiment includes a plurality of color image forming apparatuses, for example, two first image forming apparatuses 20 and second image forming apparatuses 40. The image forming system 1 according to the present exemplary embodiment includes a sheet feeding device 10, a first image forming device 20, an intermediate device 30, a second image forming device 40, a post-processing device 50, and the like from the upstream side of the sheet conveyance path. Are connected in series.

  When the first image forming apparatus 20 and the second image forming apparatus 40 are connected, a master unit (main unit) that manages the image forming system 1 in an integrated manner, and a slave unit that operates according to instructions from the master unit ( It is set whether it is one of the sub-machines). In the present embodiment, it is assumed that the first image forming apparatus 20 provided on the upstream side in the sheet conveyance direction is set as a master unit and the second image forming apparatus 40 is set as a slave unit. Each of the first image forming apparatus 20 and the second image forming apparatus 40 has a unique color reproduction area.

  In the image forming system 1 according to the present embodiment, when executing a duplex mode job for forming images on both front and back sides of a sheet, the first image forming apparatus 20 forms an image on one side (for example, the front side) of the sheet. The second image forming apparatus 40 functions as an apparatus that forms an image on the other side (for example, the back side) of the sheet. Specifically, the first image forming apparatus 20 forms an image on the front surface of the sheet supplied from the sheet feeding device 10 or the sheet feeding unit in the first image forming apparatus 20. Then, the sheet on which the image on the front surface is formed is reversed by the reversing unit in the first image forming apparatus 20, and then is conveyed to the second image forming apparatus 40 through the intermediate apparatus 30. An image is formed on the back surface and conveyed to the post-processing device 50.

  When a single-side mode job for forming an image on one side of a sheet is executed, the first image is formed on one side of the sheet supplied from the sheet feeding unit 10 or the sheet feeding unit in the first image forming apparatus 20. Device 20 forms an image. Then, the sheet on which the image is formed on one side passes through the intermediate device 30 and the second image forming device 40 and is conveyed to the post-processing device 50. In addition, the image forming system 1 according to the present embodiment can cope with a case where image formation is performed by combining a plurality of print data (job) objects on the same surface of the same sheet, such as label printing (the like). Details will be described later).

(Paper feeder)
The paper feeder 10 is called a PFU (Paper Feed Unit), and includes a plurality of paper feed trays, a paper feed means including a paper feed roller, a separation roller, a paper feed / separation rubber, a feed roller, and the like. Prepare. Each sheet tray stores sheets identified in advance for each sheet type (sheet type, basis weight, sheet size, etc.), and the first image is formed by sheet feeding means one by one from the top of the sheet. The paper is fed to the paper transport unit of the apparatus 20. Information on the paper type (paper size, paper type, etc.) stored for each paper feed tray is stored in a nonvolatile memory provided in the first image forming apparatus 20. The paper feeding device 10 functions as a paper feeding unit of the first image forming device 20.

(First image forming apparatus)
The first image forming apparatus 20 reads an image from a document and forms the read image on a sheet. The first image forming apparatus 20 also receives print data and print setting data in a page description language format such as a PDL (Page Description Language) format and a Tiff format from an external device, and the received print data, print setting data, and the like. An image is formed on a sheet based on the above. The first image forming apparatus 20 includes an image reading unit 21, an operation display unit 22, a print unit 23, and the like.

  The image reading unit 21 includes an automatic document feeding unit called ADF (Auto Document Feeder) and a reading unit, and reads images of a plurality of documents based on setting information received by the operation display unit 22. The document placed on the document tray of the automatic document feeder is conveyed to a contact glass that is a reading location, and an image on one or both sides of the document is read by an optical system including an image sensor. The image here includes not only image data such as graphics and photographs but also text data such as characters and symbols.

  The operation display unit 22 includes an LCD (Liquid Crystal Display) 221, a touch panel provided to cover the LCD 221, various switches and buttons, a numeric keypad, an operation key group, and the like. The operation display unit 22 receives an instruction from the user and outputs the operation signal to the control unit 25 described later. Further, according to a display signal input from the control unit 25, various setting screens for inputting various operation instructions and setting information, and operation screens for displaying various processing results are displayed on the LCD 221.

  The print unit 23 performs electrophotographic image forming processing, and includes various functional units related to print output, such as a paper feed unit 231, a paper transport unit 232, an image forming unit 233, and a fixing unit 234.

  The sheet feeding unit 231 includes a plurality of sheet feeding trays and sheet feeding means including a sheet feeding roller, a separation roller, a sheet feeding / separating rubber, a feeding roller and the like provided for each sheet feeding tray. Each paper tray stores paper that can be fed in advance identified for each paper type (paper type, basis weight, paper size, etc.), and feeds paper one by one from the top of the paper. Paper is fed toward the paper transport unit.

  The paper transport unit 232 transports the paper fed from the paper feed device 10 or the paper feed unit 231 onto a paper transport path to the image forming unit 233 through a plurality of intermediate rollers, registration rollers, and the like. The paper transport unit 232 transports the paper to the transfer position of the image forming unit 233 and further transports the paper to the second image forming apparatus 40. The sheet temporarily stands by at the upstream side of the registration roller 233a for correcting the bending, and the conveyance to the downstream side of the registration roller 233a is resumed according to the image formation timing.

  The paper transport unit 232 includes a reversing unit 232b including a transport path switching unit 232a and a reversing roller. In accordance with the switching operation of the conveyance path switching unit 232a, the reversing unit 232b conveys the sheet that has passed through the fixing unit 234 to the apparatus connected downstream without being reversed, or switches back by a reversing roller or the like. Then, the paper is turned upside down and then conveyed to an apparatus connected downstream. Further, the reversing unit 232b may include a circulation path unit that reverses the front and back of the sheet that has passed through the fixing unit 234 and refeeds the image to the image forming unit 233 of the first image forming apparatus 20.

  The image forming unit 233 includes a photosensitive drum, a charging device, an exposure device, a developing device, a transfer device, a cleaning device, and the like, and forms a color image on a sheet surface based on print image data. The image forming unit 233 includes four image forming units corresponding to the respective colors in order to form toner images of the respective colors of yellow (Y), magenta (M), cyan (C), and black (K). FIG. 1 shows one image forming unit for simplification of the drawing.

  In the image forming unit 233, the surface of the photosensitive drum charged by the charging device is irradiated with light corresponding to the print image data from the exposure device, and an electrostatic latent image is written. Then, the electrostatic latent image written on the surface of the photosensitive drum is developed by attaching toner charged on the surface of the photosensitive drum by a two-component developing device using a two-component developer. The toner image attached on the photosensitive drum is transferred to the paper at the transfer position.

  The fixing unit 234 includes a fixing heater, a fixing roller, a fixing external heating unit, and the like, and thermally fixes the toner image transferred to the sheet.

(Intermediate device)
The intermediate device 30 is disposed between the first image forming device 20 and the second image forming device 40. That is, the intermediate device 30 is installed on the downstream side of the first image forming device 20 and the upstream side of the second image forming device 40 in the paper transport direction. The intermediate apparatus 30 conveys the sheet conveyed from the first image forming apparatus 20 to the second image forming apparatus 40 in accordance with an instruction from the second image forming apparatus 40.

  When the intermediate device 30 or the second image forming apparatus 40 instructs the sheet conveyance path 31 of the intermediate apparatus 30 to stop the sheet in the sheet conveyance path 31, the trailing edge of the sheet is not applied to the first image forming apparatus 20. Its length is set as follows. When viewed from the front side of the intermediate device 30, the sheet conveyance path 31 is configured to bend from the vicinity of the conveyance roller 311 on the sheet carry-in side to the vicinity of the conveyance roller 312 on the sheet discharge side.

(Second image forming apparatus)
The second image forming apparatus 40 includes a print unit 43 and the like, and forms an image on the sheet surface in cooperation with the first image forming apparatus 20. The sheet conveyed from the first image forming apparatus 20 is conveyed to the registration roller 433a via the conveyance roller 434a. The sheet temporarily stands by on the upstream side of the registration roller 433a, and the conveyance to the downstream side of the registration roller 433a is resumed according to the image formation timing.

  Note that the print unit 43 provided in the second image forming apparatus 40 is similar to the print unit 23 provided in the first image forming apparatus 20, a paper transport unit provided with a paper feed unit 431 and a reversing unit 432 b, an image forming unit, a fixing unit Each part relating to print output such as a part is configured. Since it overlaps, the explanation is omitted.

(Post-processing equipment)
The post-processing device 50 is installed on the downstream side of the second image forming apparatus in the paper transport direction, and includes various post-processing units such as a sorting unit, a stapling unit, a punching unit, a folding unit, and a bookbinding unit, and a paper discharge tray. (Large-capacity paper discharge tray T1 and sub-tray T2) and the like. The post-processing device 50 performs various post-processing on the paper conveyed from the second image forming device 40, and discharges the post-processed paper to the large-capacity paper discharge tray T1 and the sub-tray T2. The large-capacity discharge tray T1 has a stage that moves up and down, and accommodates a large amount of sheets stacked on the stage. On the sub-tray T2, the paper is exposed to the outside and discharged in a visible state.

[Printing system]
Next, a printing system using the tandem image forming system 1 configured as described above will be described with reference to FIG. FIG. 2 is a system configuration diagram illustrating an example of a printing system that uses the tandem image forming system 1.

  The printing system 100 according to this example includes a first image forming apparatus 20 and a second image forming apparatus 40 of the tandem image forming system 1, and three client PCs (personal computers) 61, 62, and 63, for example. The system configuration is connected via the network 70.

(Client PC)
The client PC 61 has a known personal computer configuration including a communication unit 611, a CPU (Central Processing Unit) 612, an HDD (Hard Disk Drive) 613, an OS (Operating System) 614, a printer driver 615, and the like. The communication unit 611 is an interface for connecting the client PC 61 to the network 70. A CPU 612, HDD 613, OS 614, and printer driver 615 are connected to the communication unit 611 via a bus line 616.

  The CPU 612 controls the first image forming apparatus 20 and the second image forming apparatus 40 and processes data. The HDD 613 stores various data. The OS 614 is software that manages the entire system. The printer driver 615 is software capable of converting a designated document file into print data, making detailed settings relating to printing, and instructing the first image forming apparatus 20 and the second image forming apparatus 40 to print. is there.

  Similarly to the client PC 61, the client PC 62 and the client PC 63 include a communication unit 611, a CPU 612, an HDD 613, an OS 614, a printer driver 615, and the like. In the client PC 61/62/63, when performing label printing to be described later, different types of multi-sided layout setting is performed under the operation of the user. Details of the setting input user interface for performing different types of multi-page layout setting will be described later.

(Image forming device)
As described above, the first image forming apparatus (master unit) 20 includes an image reading unit 21 that reads an image of an original, an operation display unit 22 that is an interface for performing various settings under user operations, and printing. And a printing unit 23 having functional units related to output. The functional units relating to the print output are a paper feed unit 231, a paper transport unit 232, an image forming unit 233, a fixing unit 234, and the like.

  The first image forming apparatus 20 further includes a communication unit 24, a control unit 25, an image processing unit 26, a print processing unit 27, a paper feed processing unit 28, and a color conversion processing unit 29. The communication unit 24 is an interface for connecting the first image forming apparatus 20 to the network 70. For this communication unit 24, an image reading unit 21, an operation display unit 22, a print unit 23, a control unit 25, an image processing unit 26, a print processing unit 27, a paper feed processing unit 28, and a color conversion processing unit 29 are connected to a bus line. Connected via BL.

  The control unit 25 includes a CPU 251, a ROM (Read Only Memory) 252 for storing a program executed by the CPU 251, and a RAM (Random Access Memory) 253 used as a work area of the CPU 251. The control unit 25 controls the entire first image forming apparatus 20 under the control of the CPU 251.

  The image processing unit 26 performs processing for generating image data based on print data received via the communication unit 24. The print processing unit 27 performs a process for printing the image data generated by the image processing unit 26. The paper feed processing unit 28 performs a process of feeding paper to the printing unit 23. The color conversion processing unit 29 performs matching processing of color information expressed on a monitor with color information reproduced on the first image forming apparatus 20 by a known color management system (CMS).

  The second image forming apparatus (slave unit) 40 basically has the same configuration as that of the first image forming apparatus (master unit) 20. That is, the second image forming apparatus 40 includes an image reading unit 41, an operation display unit 42, a print unit 43, a communication unit 44, a control unit 45, an image processing unit 46, a print processing unit 47, and a color conversion processing unit 49. Yes. However, the second image forming apparatus 40 includes a paper discharge processing unit 48 that performs a process of discharging the printed paper to the post-processing device 50 instead of the paper feed processing unit 28 of the first image forming apparatus 20. .

  A specific example of the image forming process (printing process) executed in the printing system 100 configured as described above will be described below.

[Example 1]
Example 1 is an example of label printing in which an image is formed in units of one page on a sticky sheet having adhesiveness on the back surface. In label printing according to the first embodiment, an image is formed by combining a plurality of print data, for example, objects of job 1 and job 2 on the same side of the same sheet. In this label printing, since the first image forming apparatus 20 and the second image forming apparatus 40 each have a unique color reproduction region, color matching processing is performed.

  In the following, the color reproduction area of the first image forming apparatus 20 (hereinafter referred to as “parent machine”) as the master is G1, and the second image forming apparatus 40 (hereinafter referred to as “slave”) as the slave. The color matching process will be described with the color reproduction region of (described) as G2.

  In the color matching process, for example, an area obtained by ANDing the color reproduction areas G1 and G2 of each of the master unit and the slave unit is set as a common color reproduction area G3, and the common color reproduction area G3 is used for the color matching process. A conceptual diagram of this case is shown in FIG. In FIG. 3, the ● mark represents the color information of the job 1 object, and the ■ mark represents the color information of the job 2 object. The same applies to the following.

  As described above, when the common color reproduction area G3 obtained by the logical product of the color reproduction areas G1 and G2 of each of the parent device and the child device is used for the color matching process, the color information of the job 1 / job 2 object is: Since the image is rounded to the common color reproduction region G3, it is impossible to form an image by optimally using the color reproduction regions G1 and G2 possessed by the parent device and the child device.

  Therefore, in the image forming system 1 according to the present embodiment, when image formation is performed by combining a plurality of print data, for example, objects of job 1 and job 2 on the same surface of the same sheet, first, the object of job 1 It is determined which color information is closer to the color reproduction regions G1 and G2 of the parent device / child device.

  Based on the determination result, the objects of job 1 and job 2 are allocated to the parent device / child device, and different images based on the objects of job 1 and job 2 are formed in different areas on the same side of the sheet. To. Specifically, when the color information of the object of job 1 is in the color reproduction area G1 of the parent machine (or the difference from the color reproduction area G1 of the parent machine is closer to that of job 2), the object of job 1 Is printed on the parent machine, and the object of job 2 is printed on the child machine.

  As a result, as shown in FIG. 4, the color information of the object of job 1 is rounded to the color reproduction area G1 of the parent machine, and the color information of the object of job 2 is rounded to the color reproduction area G2 of the child machine. The rounding amount can be reduced as compared with the case of rounding to the color reproduction region G3. Then, it is possible to form an image by optimally using the color reproduction regions G1 and G2 of the parent device and the child device on the same surface of the same sheet of the objects of job 1 and job 2.

(Label printing procedure)
Hereinafter, an example of a label printing processing procedure according to the first embodiment will be described with reference to the flowchart of FIG. This process is executed under the control of the CPU 251 of the control unit 25 of the parent device (first image forming apparatus 20).

  The CPU 251 receives a plurality of print data (for example, job 1 and job 2) created by the client PC 61/62/63 connected to the network 70 via the communication unit 24 (step S11), It is determined whether or not to perform multiple imposition (step S12). When label printing is performed, as shown in FIG. 6, images can be formed by applying different types of images on the same surface of the same sheet. Cost reduction can be achieved by performing dissimilar multiple imposition, cutting and delivering. This heterogeneous multiple layout is set by the user on the client PC 61/62/63 through a setting input user interface described later.

  Next, if the multi-sided layout is performed (Yes in S12), the CPU 251 acquires the device profile of the monitor / parent device / slave device (step S13), and then uses a well-known color management system (CMS). Color matching processing of the monitor / base unit / slave unit is performed (step S14).

In general, when color matching is performed using a color management system (CMS), a connection color space (for example, XYZ or the like) is changed from a color space (for example, sRGB or Adobe (registered trademark) RGB) that a user views on a monitor. L ^* a ^* b ^* ). Then, for example, based on the L ^* a ^* b ^* value, the image forming apparatus converts the color space into an output destination color space (for example, CMYK).

  Next, the CPU 251 calculates the total sum (difference total amount) of the rounding difference amounts in one page from the color matching processing results of the monitor / parent device / slave device (step S15).

  Here, when color space compression is applied to the color information a (*** *** ***) expressed on the monitor by the color management system that matches the color reproduced on the master / slave unit, As shown in FIG. 7, the color information a is rounded to the color reproduction region G1 of the parent device to become color information a ′, and the child device is rounded to the color reproduction region G2 to become color information a ″. a (*** *** ***) represents a three-dimensional coordinate value.

In step S15, the rounding difference total amount is obtained by adding the rounding difference amounts in one page.
Total difference of parent device = | (a′−a) | + | (b′−b) | + | (c′−c) | + | (d′−d) |
Slave unit total amount = | (a ″ −a) | + | (b ″ −b) | + | (c ″ −c) | + | (d ″ −d) |

  Next, the CPU 251 determines which color information of the job 1 is closer to the color reproduction region G1 of the parent device or the color reproduction region G2 of the child device (step S16).

  Here, the calculation and comparison of the difference amount in one page of rounding will be described by taking specific numerical values as examples and using the following (1) to (3) as conditions. However, the numerical value shown here is an example, and is not necessarily rounded to this value.

(1) The color of the original image is represented by an RGB value a (30, 90, 5) and an L ^* a ^* b ^* value a (33, -35, 38).
(2) When the color of the original image is rounded to the color reproduction area of the master unit with a value outside the color reproduction area of the image forming apparatus L ^* a ^* b ^* value a (33, −35, 38) is L ^* a ^* b ^* Values are rounded to a ′ (30, −27, 35).
(3) When rounding into the color reproduction area of the slave unit with a value outside the color reproduction area of the image forming apparatus L ^* a ^* b ^* value a (33, −35, 38) is L ^* a ^* b ^* value a ′ '(27, -18, 33).

  The color matching process in step S14 described above is a process for acquiring the rounded values of the above (1) and (2).

In step S15, processing for calculating the difference amount of rounding is performed.
Difference a′−a between master color reproduction area and original image
= | 30-33 | + | (-27)-(-35) | + | 35-38 | = 14
Difference "a" -a between handset color reproduction area and original image
= | 27-33 | + | (-18)-(-35) | + | 33-38 | = 28

From the above calculation results (14 <28), it can be determined that the smaller the value, the smaller the difference amount. In the determination process in step S16, the difference amount is smaller when the job 1 and job 2 are printed by either the master unit or the slave unit by calculating the sum of all the color information of the print data. Can be judged. In this example, the difference amount is calculated using the L ^* a ^* b ^* value and compared. However, the difference amount may be calculated using the CMYK value of the output destination and compared.

  In the determination process of step S16, the CPU 251 determines that the relationship (total master unit difference of job 1 <total slave unit difference of job 1) is satisfied, that is, the color information of job 1 is close to the color reproduction region G1 of the master unit. Allocates the job so that it becomes job 1 on the parent device and job 2 on the child device (step S17). Further, the CPU 251 determines that the relationship of (total amount of master difference of job 1> total amount of slave device difference of job 1), that is, if the color information of job 1 is close to the color reproduction region G2 of the slave, The job is assigned to the job 2 so that it becomes the job 1 in the slave unit (step S18).

  Next, the CPU 251 prints job 1 / job 2 allocated by the parent device / child device to the designated area (step S19), and then determines whether all pages have been printed (step S20). ) When all pages have been printed (Yes in S20), a series of processes for label printing is terminated. If all the pages have not been printed (No in S20), the process returns to step S14 and the above-described processing is repeated. If it is determined in step S12 that different types of imposition are not performed (No in S12), the process proceeds to step S19 to execute printing.

  As is clear from the above description, when the CPU 251 prints a plurality of print data on the same surface of the same sheet, the color information of the print data is stored in any of the color reproduction areas of the master / slave. It has a function as a judgment part that judges whether it is close. Based on the determination result, the CPU 251 further serves as a control unit that performs control to allocate a plurality of print data to the master unit / slave unit and form different images based on the plurality of print data in different areas on the same side of the sheet. Has the function of Through the series of processes described above, a plurality of print data, for example, objects of job 1 and job 2 are optimally used on the same surface of the same sheet, and the color reproduction areas G1 and G2 respectively possessed by the master unit and the slave unit. Thus, image formation can be performed.

(Heterogeneous multi-imposition setting)
Here, the heterogeneous multiple layout setting performed by the user using the setting input user interface of the client PC 61/62/63 will be described with reference to FIG. FIG. 8 is a diagram illustrating an example of a setting input user interface for performing heterogeneous multi-page layout setting.

  The user performs the setting for different types of multi-page layout in the following steps on the setting input user interface. In the client PC 61/62/63, the user first selects whether or not to perform heterogeneous multi-page layout setting using the setting input user interface shown in FIG. 8 (step S101). Next, the user selects a job to be imposed from the registered job list (step S102). When a job is selected, a preview of each job object is displayed (step S103). The user selects an imposition rule from this preview (step S104).

[Example 2]
Example 2 is an example of label printing in which an image is formed on a roll paper in which a recording paper having adhesiveness is wound on a back surface.

  FIG. 9 is a schematic diagram illustrating an overall configuration of a tandem image forming system that forms an image on roll paper. The tandem-type image forming system 2 according to this example includes a roll paper feeding device 80 that supplies the roll paper S to the first image forming apparatus 20 on the upstream side of the first image forming apparatus 20 that is a master unit. A roll paper take-up device 90 that winds the roll paper S discharged from the second image forming apparatus 40 is provided on the downstream side of the second image forming apparatus 40 that is a slave.

(Label printing procedure)
Next, an example of a label printing processing procedure according to the second embodiment, which is executed by the printing system having the tandem image forming system 2 having the above-described configuration, will be described with reference to the flowchart of FIG. This process is also executed under the control of the CPU 251 of the control unit 25 of the master unit (first image forming apparatus 20).

  The label printing process according to the second embodiment is the same as the label printing process according to the first embodiment. That is, the CPU 251 receives a plurality of print data (for example, job 1 and job 2) created by the client PC 61/62/63 via the communication unit 24 (step S21), and then performs heterogeneous multi-page layout. Whether or not (step S22). FIG. 11 shows a different imposition pattern 1 on the roll paper, and FIG. 12 shows a different imposition pattern 2 on the roll paper.

  Next, if different types of multi-page layout are to be performed (Yes in S22), the CPU 251 acquires a device profile of the monitor / parent device / slave device (step S23), and then performs color matching of the monitor / parent device / slave device. Processing is performed (step S24). Next, the CPU 251 calculates the total difference in rounding for each page from the color matching processing results of the monitor / base unit / slave unit (step S25). Next, the CPU 251 determines whether the color information of the job 1 is closer to the color reproduction region G1 of the parent device or the color reproduction region G2 of the child device (step S26), and based on the determination result, the parent device / child Job 1 / Job 2 are allocated to the machine (steps S27 and S28).

  Thereafter, the CPU 251 prints the job 1 / job 2 allocated by the parent device / child device to the designated area (step S29), and then determines whether all pages have been printed (step S30). ) When all pages have been printed (Yes in S30), a series of processing for label printing is terminated. If all pages have not been printed (No in S30), the process returns to step S24 and the above-described processing is repeated. If it is determined in step S22 that different types of imposition are not performed (No in S22), the process proceeds to step S29 to execute printing.

  Also in the case of the label printing process according to the second embodiment for forming an image on the roll paper described above, the same operation and effect as in the case of the label printing process according to the first embodiment for forming an image in units of one page can be obtained. it can. In other words, through the above-described series of processing, a plurality of print data, for example, objects of job 1 and job 2 are optimally used on the same surface of the same sheet and the color reproduction areas G1 and G2 possessed by the parent device and the child devices, respectively. Thus, image formation can be performed.

[Modification]
As mentioned above, although this invention was demonstrated using embodiment, this invention is not limited to the range as described in the said embodiment. That is, various changes or improvements can be added to the above-described embodiment without departing from the gist of the present invention, and embodiments to which such changes or improvements are added are also included in the technical scope of the present invention.

  For example, in the embodiment described above, label printing for forming an image on a sticky sheet having adhesiveness on the back surface has been described as an example. However, the present invention is not limited to this. That is, the present invention can be applied to general printing in which an image is formed by combining a plurality of print data (job) objects on the same surface of the same sheet.

  DESCRIPTION OF SYMBOLS 1, 2 ... Tandem-type image forming system 10 ... Paper feeding apparatus 20 ... 1st color image forming apparatus (master) 30 ... Intermediate | middle apparatus 40 ... 2nd color image forming apparatus (slave) 50 ... Post-processing device 61, 62, 62 ... Client PC (personal computer), 80 ... Roll paper supply device, 90 ... Roll paper winding device, 100 ... Printing system

Claims (4)

A tandem image forming system configured by connecting a plurality of color image forming apparatuses having unique color reproduction regions in series,
A determination unit configured to determine which color information of the print data is close to which of the color reproduction regions of the plurality of color image forming apparatuses when printing a plurality of print data on the same surface of the same sheet;
Control that allocates the plurality of print data to the plurality of color image forming apparatuses and forms different images based on the plurality of print data in different regions on the same surface of the sheet based on the determination result of the determination unit. A control unit to perform,
An image forming system comprising: The image forming system according to claim 1, wherein the sheet is a seal-like sheet having adhesiveness on a back surface. The image forming system according to claim 2, wherein the paper is roll paper. An image forming method in a tandem image forming system configured by connecting a plurality of color image forming apparatuses having unique color reproduction regions in series,
When printing a plurality of print data on the same surface of the same paper, it is determined which color information that the print data has is close to the color reproduction area of the plurality of color image forming apparatuses,
Based on the determination result, the plurality of print data is allocated to the plurality of color image forming apparatuses, and different images based on the plurality of print data are formed in different regions on the same surface of the paper. Image forming method.

Images