JP2015203711A - Sheet processing system, control method thereof, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a subsequent second sheet wait for a first sheet, for which sheet processing is set, to join a normal conveyance path when the sheet processing is not set for the second sheet conveyed following the first sheet.SOLUTION: A sheet processing system and a control method thereof include a printer capable of accepting a print job and a sheet processor that performs sheet processing on a sheet. The system and the method analyze a print job to determine whether or not sheet processing is set in the page data of each page specified in the print job, allow the printer to output and print the data of a subsequent second page prior to the data of a first page when determining that the sheet processing is set in the data of the subsequent second page following the data of the first page in a prescribed range, and perform a control so that a preceding sheet having the data of the second page printed thereon and a sheet having the data of the first page printed thereon are ejected from the sheet processor in the specified order in the print job.

Description

  The present invention relates to a sheet processing system, a control method thereof, and a program.

  A printing system that performs high-production and high-efficiency printing such as POD (Print on Demand) includes a large printing apparatus, and various sheet processing apparatuses are connected to the printing apparatus. In such a printing apparatus, there is a printer that switches between a single-sided printing and a sheet conveyance path during double-sided printing. In this case, at the time of double-sided printing, after the printing of the first side of the sheet is performed, the sheet on which only one side is printed is reversed while being circulated through the double-sided conveyance path, and the sheet is joined to the original conveyance path. The second page is printed. In the sheet feeding control at the time of duplex printing, since the sheet on which the first side is printed is joined to the conveyance path, the succeeding sheets are controlled to have a feeding interval corresponding to the length of the joined sheets. . In other words, when a plurality of sheets are continuously printed on both sides, the sheet feeding interval is controlled to be twice that in a case where single-sided printing is continued.

  Here, when the next sheet of the sheet for duplex printing is single-sided printing, as described above, the sheet for duplex printing is printed on the first side and then merged with the original conveyance path through the duplex conveyance path. Is done. For this reason, there is a problem in that the next sheet to be printed on one side cannot be fed to the conveyance path, and there is a gap between the sheets. In particular, a printing system such as POD has a large printing apparatus, so the conveyance path for double-sided printing is often long, and more complicated jobs such as single-sided printing and double-sided printing may be handled. It is important to solve such problems.

  Therefore, a printing system that can prevent productivity from being impaired even when duplex printing and simplex printing are switched has been conventionally considered. For example, in Patent Document 1, when single-sided printing is instructed while double-sided printing continues, the single-sided printed sheet is conveyed to the conveyance path for double-sided printing, but printing on the second side is not performed. Thus, a technique is described that does not reduce the productivity by eliminating the switching of the conveyance path.

  In Patent Document 2, when double-sided printing is instructed while single-sided printing continues, the presence / absence of double-sided printing and the state of the conveyance path for double-sided printing are checked before single-sided printing is performed. If there is, the first page of the duplex printing is printed first. And the technique which prints the 1st surface of the preceding single-sided printing, and then prints the 2nd surface of the double-sided printing previously printed is described.

  On the other hand, there are various sheet processing apparatuses in the printing system handled by the POD as described above. Among them, a sheet whose sheet conveyance path is switched depending on whether or not the sheet processing is executed. There is a processing device. Further, among the sheet processing apparatuses with which the conveyance path is switched, the configuration is such that even after the sheet processing is performed, the sheet processing is transported to the subsequent sheet processing apparatus in the same manner as a sheet that has not been subjected to sheet processing. There is also an improved sheet processing apparatus. For example, in the case of a sheet processing apparatus dedicated to punching, a punching apparatus including a first transport path that transports a sheet for performing punch processing and a second transport path that transports a sheet that does not perform punch processing. Exists. Further, in such a punching device, the first and second conveying paths are joined so that the sheet can be conveyed to the subsequent sheet processing device regardless of whether or not punching is performed. There is a processing device. Further, when the first conveyance path for conveying a sheet that does not require punching and the second conveyance path for conveying a sheet that performs punching are different in size and type of sheets that can be guaranteed as a sheet processing apparatus. There is. Accordingly, there are many cases where it is not preferable to always use the second conveyance path for conveying the sheet for performing the punching process.

JP-A-8-262814 Japanese Patent Laid-Open No. 9-230637

  Here, in a printing system to which a sheet processing apparatus such as the above-described punch processing apparatus is connected, a second sheet not set with sheet processing is conveyed following the first sheet set with sheet processing. Consider the case. In this case, since the conveyance path of the first sheet is long and sheet processing such as punching is performed, the first sheet subjected to sheet processing is the normal conveyance path for the subsequent second sheet. It is waited until it joins. As a result, there is a problem that productivity is lowered because a long paper space is left between the first sheet and the second sheet.

  An object of the present invention is to solve the above-described problems of the prior art.

  A feature of the present invention is to provide a technique capable of increasing processing efficiency when a first sheet for which sheet processing is set and a second sheet for which sheet processing is not set are mixed.

In order to achieve the above object, a sheet processing system according to an aspect of the present invention has the following configuration. That is,
A sheet processing system including a printing apparatus capable of receiving a print job and a sheet processing apparatus that performs sheet processing on a sheet,
Determining means for analyzing the print job and determining whether or not sheet processing is set for the page data of each page specified in the print job;
When the determination unit determines that the sheet processing is set for the second page data that follows the first page data within a predetermined range, the subsequent second page data is printed prior to the first page data. Preceding control means for controlling the apparatus to output and print the apparatus;
The sheet printed with the second page data preceded by the preceding control means and the sheet printed with the first page data are output from the sheet processing apparatus in the order specified in the print job. And a paper feed control means for controlling the paper feed.

  According to the present invention, when the first sheet for which sheet processing is set and the second sheet for which sheet processing is not set are mixed, there is an effect that the processing efficiency can be improved.

  Other features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings. In the accompanying drawings, the same or similar components are denoted by the same reference numerals.

The accompanying drawings are included in the specification, constitute a part thereof, show an embodiment of the present invention, and are used to explain the principle of the present invention together with the description.
The figure explaining the POD system which concerns on this embodiment. 1 is a block diagram illustrating a configuration of a printing system according to an embodiment. 1 is a diagram illustrating a configuration of a printing system according to an embodiment. FIG. 3 is an overview diagram illustrating an operation unit included in the printing apparatus according to the embodiment. 6 is a flowchart for explaining processing when the printing system according to the embodiment receives a job. 5 is a flowchart for explaining sheet feeding control to the printing apparatus main body in the printing system according to the first embodiment. 7 is a flowchart for describing processing for determining whether there is a page that can be fed in advance in S607 in FIG. 6. 9 is a flowchart for explaining control of a printing apparatus main body in a printing system according to a second embodiment of the invention. FIG. 5 is a diagram for explaining an example of changing the output order of the print job according to the first embodiment and the data of each page for which printing is designated in the print job. FIG. 10 is a diagram for explaining an example of changing the output order of the print job according to the second embodiment and the data of each page for which printing is designated in the print job.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments do not limit the present invention according to the claims, and all combinations of features described in the embodiments are not necessarily essential to the solution means of the present invention. .

  This embodiment assumes a printing environment different from the office environment, such as a POD environment, in order to cope with the problems described in the background art. Accordingly, here, a sheet processing system for the entire site in the POD environment including the printing system 1000 will be described. Such a printing environment itself is one of the features of this embodiment. In this embodiment, a printing environment to which the printing system 1000 can be applied is referred to as a POD system 10000 because it is suitable for a POD environment.

  FIG. 1 is a diagram illustrating a POD system according to the present embodiment.

  The POD system 10000 includes a printing system 1000 according to the present embodiment, a server computer 103, and a client computer 104 (hereinafter referred to as a PC). A paper folding machine 107, a case binding machine 108, a cutting machine 109, a saddle stitch binding machine 110, a scanner 102, and the like are also provided. In this way, a plurality of devices are connected to each other via the network 101 to constitute the POD system 10000.

  The printing system 1000 includes a printing apparatus main body 100 and a sheet processing apparatus 200. As an example of the printing apparatus 100, in the present embodiment, a description will be given of a multi-function peripheral having a plurality of functions such as a copy function and a PC print function, but only a PC print function for printing print data from a PC. Alternatively, it may be a single function type printing apparatus having only a copy function. Hereinafter, this multi-function peripheral is also referred to as an MFP (multifunction processing apparatus).

  Here, the paper folding machine 107, the cutting machine 109, the saddle stitch binding machine 110, and the case binding machine 108 are defined as the sheet processing apparatus 200 provided in the printing system 1000. These apparatuses are devices that can execute sheet processing on sheets printed by the printing apparatus 100 included in the printing system 1000. For example, the paper folding machine 107 executes a folding process for a sheet printed by the printing apparatus 100. The cutting machine 109 executes a cutting process for a sheet printed by the printing apparatus 100 in units of a sheet bundle composed of a plurality of sheets. The saddle stitch bookbinding machine 110 executes a saddle stitch bookbinding process for a sheet printed by the printing apparatus 100. The case binding machine 108 executes case binding processing on the sheet bundle printed by the printing apparatus 100.

  However, in order to execute various sheet processes in these sheet processing apparatuses, a printed matter printed by the printing apparatus 100 according to a job is taken out from a paper discharge unit of the printing apparatus 100 by an operator, and the sheet processing apparatus to be processed In addition, it is necessary to set the printed material. As described above, when a sheet processing apparatus other than the sheet processing apparatus 200 (FIG. 3) included in the printing system 1000 is used, an intervention operation by an operator is required after the printing process by the printing apparatus 100.

  On the other hand, when sheet processing is performed on a sheet printed by the printing apparatus 100 using the sheet processing apparatus 200 (FIG. 3) included in the printing system 1000, after the printing process is performed by the printing apparatus 100. No operator intervention is required. This is because a sheet printed by the printing apparatus 100 can be directly fed from the printing apparatus 100 to the sheet processing apparatus 200.

  Specifically, the sheet conveyance path inside the printing apparatus 100 is configured to be connectable to the sheet conveyance path of the sheet processing apparatus 200. As described above, the sheet processing apparatus 200 and the printing apparatus 100 included in the printing system 1000 are physically connected to each other. In addition, both the printing apparatus 100 and the sheet processing apparatus 200 include a CPU and are configured to be capable of data communication. As described above, the printing apparatus 100 and the sheet processing apparatus 200 are electrically connected to each other.

  In the present embodiment, the control unit provided in the printing system 1000 controls the printing apparatus 100 and the sheet processing apparatus 200 in an integrated manner.

  Next, the configuration of the printing system 1000 according to the present embodiment will be described with reference to FIG.

  FIG. 2 is a block diagram illustrating a configuration of the printing system 1000 according to the embodiment. 2, all units included in the printing system 1000 are included in the printing apparatus 100 except for the sheet processing apparatus 200 (a series of sheet processing apparatuses that can be configured by a plurality of inline type sheet processing apparatuses). ing. That is, the sheet processing apparatus 200 is a sheet processing apparatus that can be attached to and detached from the printing apparatus 100, and is configured to be provided as an option of the printing apparatus 100. As a result, it is possible to provide the necessary number of inline finishers for the required number in the POD environment.

  The printing apparatus 100 includes a non-volatile memory such as a hard disk 209 (hereinafter referred to as HDD) that can store data of jobs to be processed. Further, the image forming apparatus 100 has a copy function for temporarily storing image data from the scanner unit 201 included in the printing apparatus 100 in the HDD 209, reading out the image data from the HDD 209, and printing it by the printer unit 203. In addition, job data received from an external device such as the PC 103 or 104 via the external I / F unit 202 unit is stored in the HDD 209 and then printed by the printer unit 203. In other words, the printing apparatus 100 according to the present embodiment may be a printing apparatus capable of color printing or a printing apparatus capable of monochrome printing, and may have any configuration as long as various controls described in the present embodiment can be executed. .

  The printing apparatus 100 also includes an operation unit 204 having a display unit, which is an example of a user interface unit (UI unit) included in the printing system 1000. Other examples of the user interface unit provided by the printing system 1000 include the display unit of the PCs 103 and 104, a keyboard, a pointing device, and the like.

  A controller unit (hereinafter referred to as a control unit) 205 corresponding to an example of a control unit included in the printing system 1000 comprehensively controls processes and operations of various units included in the printing system 1000. The ROM 207 stores various control programs executed by the CPU 211 of the control unit 205 according to the present embodiment. The ROM 207 also stores a display control program for displaying various UI screens on the display unit of the operation unit 204 including a user interface screen (hereinafter referred to as UI screen). The CPU 211 of the control unit 205 can execute various operations according to the present embodiment by reading and executing the program of the ROM 207. In addition, a program for interpreting PDL (page description language) code data received from an external device (PC 103, 104, etc.) via the external I / F 202 and executing an operation for developing it into raster image data (bitmap image data), etc. Stored in the ROM 207. A RAM 208 stores image data, various programs, and setting information acquired from the scanner unit 201 and the external I / F 202. The HDD 209 stores the image data compressed by the compression / decompression unit 210. The HDD 209 can hold a plurality of data such as print data of a job to be processed. The control unit 205 prints data of a job to be processed input via various input units such as the scanner unit 201 and the external I / F unit 202, and transmits the data to an external device via the external I / F 202. You can also In this way, the control unit 205 controls various output processes of job target data stored in the HDD 209. The compression / decompression unit 210 compresses / decompresses image data and the like stored in the RAM 208 and HDD 209 by various compression methods such as JBIG and JPEG.

  Based on the above configuration, the control unit 205 of the printing system 1000 also controls the operation of the inline type sheet processing apparatus 200.

  FIG. 3 is a diagram illustrating the configuration of the printing system 1000 according to the embodiment.

  In the figure, the printing apparatus 100 has an apparatus main body 301 and a fixing device 302. The apparatus main body 301 and the fixing device 302 print an image on a sheet. A large-capacity paper feed deck 320 is connected to the right side of the printing apparatus main body 301 as a paper feed device. A plurality of paper feed decks 320 can be connected. In FIG. 3, a second large-capacity paper feed deck 321 is further connected on the right side. As the sheet processing apparatus 200, a multi-hole puncher 351 is connected to the left side of the fixing apparatus 302. The multi-hole puncher 351 includes a conveyance path 353 that conveys a sheet that is not subjected to multi-hole punching, and a conveyance path 354 that conveys a sheet that is subjected to multi-hole punching. Then, the sheet subjected to the multi-hole punch is merged with the sheet conveyance path 353 where the multi-hole punch is not performed at the merge point 357 in order to be conveyed to the subsequent sheet processing apparatus. Thus, the multi-hole puncher 351 is a sheet processing apparatus that performs switching of sheet conveyance paths and sheet merging, and the characteristic control according to the present embodiment has a plurality of conveyance paths as described above. This is related to sheet conveyance control. In this embodiment, the multi-hole puncher 351 will be described. However, the present invention is not limited to the multi-hole puncher 351. For example, a crease having a similar conveyance path configuration and various folding processes can be executed. It can also be applied to a sheet processing apparatus such as a folding machine. Furthermore, a finisher 334 is connected to the left side of the multi-hole puncher 351.

  The printing apparatus main body 301 includes paper feed decks 305 and 306 therein, and these paper feed decks 305 and 306 operate as standard paper feed units. The developing units 307 to 310 develop images corresponding to colors of Y (yellow), M (magenta), C (cyan), and K (black), respectively, in order to form a color image. The developed image is primarily transferred to the intermediate transfer belt 311. The intermediate transfer belt 311 rotates clockwise in FIG. 3, and the image on the intermediate transfer belt 311 is secondarily transferred to the sheet conveyed through the paper conveyance path 304 at the secondary transfer position 312. The image transferred onto the sheet in this way is sent from the apparatus main body 301 to the fixing device 302 and is fixed on the sheet by being heated and pressurized by the fixing device 313. The sheet that has passed through the fixing device 313 is conveyed through a conveyance path 315 to a conveyance port 317 to the sheet processing apparatus. Depending on the type of sheet, if further heating or pressurization is required for fixing, the sheet passes through the fixing device 313 and is then conveyed to the second fixing device 314 using the upper conveying path 316. After being heated and pressurized, it is conveyed to a conveyance port 317 to the sheet processing apparatus. In the case of duplex printing, the fixed sheet is conveyed to the sheet reversing path 318 and reversed, and then is fed again to the printing apparatus main body 301 via the duplex conveyance path 319, and is printed on both sides at the secondary transfer position 312. Image formation is performed on the second surface.

  In addition to the standard paper feed unit of the printing apparatus main body 301, paper can be fed from each of the three stages of paper feed decks 322 to 324 of the large capacity paper feed deck 320. The sheet fed from here is conveyed through the sheet conveyance paths 325 and 326 and is sent to the printing apparatus main body 301 for image formation. When the second large-capacity sheet feeding deck 321 is connected, sheets can be fed from each of the three stages of sheet feeding decks 329 to 331, and the sheet conveyed through the sheet conveyance path 332 is conveyed by the conveyance port 333. Is delivered to the first large-capacity paper feed deck 320. These large-capacity paper feed decks 320 and 321 have a function of detecting double feeding when a plurality of sheets are stacked. When double feeding is detected, the sheet conveyance path is switched from the normal conveyance path 326 to the conveyance path 327, and the double-feed sheet is discharged to the escape tray 328.

  Next, the multi-hole puncher 351 that is a sheet processing apparatus will be described.

  The sheet on which image formation has been completed is input from the fixing device 302 to the sheet conveyance unit of the multi-hole puncher 351 through the conveyance port 317 to the sheet processing apparatus. When multi-hole punching is performed on the sheet, the sheet is conveyed to a multi-hole punching sheet conveyance path 354 by a conveyance path switching switch 352. Thereafter, the punch hole is punched by sandwiching the sheet between the convex multi-hole punch die 355 and the concave multi-hole punch receiving die 356. The sheet thus punched is merged with the sheet conveyed through the conveyance path 354 and conveyed through the conveyance path 353 at the sheet merge point 357, and the punched sheet is also regarded as an unpunched sheet. Similarly, the sheet is conveyed to a subsequent sheet processing apparatus. The dies 355 and 356 can be changed, and the user sets an optimum die. On the other hand, if there is no designation for executing multi-hole punching, the conveyance path 353 is selected by the conveyance path changeover switch 352, and the sheet sent to the conveyance port 317 is conveyed to the sheet joining point 357 via the conveyance path 353. Then, it is transported to the finisher 334 at the subsequent stage.

  The finisher 334 performs sheet processing on the printed sheet according to the function designated by the user. Specifically, it has functions such as stapling (1 and 2 binding) and saddle stitch binding. The finisher 334 has two paper discharge trays 335 and 336, and when the paper is discharged to the paper discharge tray 335, the sheet is discharged via the sheet conveyance path 341. The sheet passing through the conveyance path 341 cannot be subjected to processing such as stapling. When processing such as stapling is performed, the sheet is sent to the sheet processing unit 343 via the sheet conveyance path 342, subjected to finishing processing designated by the user, and discharged to the discharge tray 336. The sheet discharge trays 335 and 336 can be moved up and down, and the sheet discharge tray 335 is moved down so that the sheets processed by the sheet processing unit 343 are stacked from the lower sheet discharge port. You can also. Further, when an insertion sheet is designated by the user, the insertion sheet set in the inserter 338 is inserted into a predetermined page via the sheet conveyance path 340. Further, when saddle stitch bookbinding is specified, the saddle stitch processing unit 344 staples the sheet to the center of the sheet, and then folds the sheet in half and outputs it to the saddle stitch bookbinding tray 337 via the paper conveyance path 345. . The saddle stitch bookbinding tray 337 has a belt conveyor configuration, and the saddle stitch bookbinding stack loaded on the saddle stitch bookbinding tray 337 can be conveyed to the left whenever the bundle is stacked.

  As described above, the printing system 1000 executes processes such as paper feeding, printing, sheet processing, and paper discharge. In the present embodiment, the case where the printing apparatus 100 is a 4D (drum) type color MFP will be described. However, the configuration of the printing apparatus 100 is not limited to this, and a monochrome MFP may be a 1D (drum) type color MFP. But you can.

  FIG. 4 is an overview diagram illustrating the operation unit 204 included in the printing apparatus 100 according to the embodiment.

  The operation unit 204 includes a key input unit 402 that can accept user operations with hard keys, and a touch panel unit 401 as an example of a display unit that can accept user operations with soft keys (display keys).

  FIG. 5 is a flowchart for explaining processing when the printing system 1000 according to the embodiment receives a job. Note that a program for executing this processing is stored in the ROM 207, and the processing shown in this flowchart is executed by the CPU 211 executing this program.

  In step S501, the CPU 211 determines whether the print system 1000 has received a print job. If the CPU 211 determines that a print job has been received, the process advances to step S502. In step S502, the CPU 211 analyzes the received print job, temporarily stores job settings including at least the presence / absence of sheet processing settings set in the print job in the RAM 208, and proceeds to step S503. In step S503, the CPU 211 determines whether analysis of all pages included in the received print job has been completed. If it is determined that all pages have been analyzed, the process returns to step S501 and waits for reception of the next job. On the other hand, if the analysis of all pages is not completed in S503, the CPU 211 proceeds to S504. In step S504, the CPU 211 generates image data of the page, extracts setting information set in the page, and proceeds to step S505. In step S505, the CPU 211 stores the image data and setting information of each page generated in step S504 in the HDD 209 in page order, and returns to step S503.

  Thus, when a print job is received from a PC or the like, the image data of each page included in the print job and its setting information are stored in the HDD 209 in page order.

[Embodiment 1]
Next, paper feed control by the printing system 1000 according to the first embodiment will be described with reference to the flowchart of FIG.

  FIG. 6 is a flowchart for explaining sheet feeding control to the printing apparatus main body 100 in the printing system 1000 according to the first embodiment. Note that a program for executing this processing is stored in the ROM 207, and the processing shown in this flowchart is executed by the CPU 211 executing this program.

  FIG. 9 is a diagram for explaining an example of changing the output order of the print job according to the first embodiment and the data of each page for which printing is designated in the print job. Hereinafter, the flowchart of FIG. 6 will be described with reference to FIG. In the first embodiment, the case where the specific sheet processing is a multi-hole punch will be described as an example based on the configuration of FIG. 3. However, the sheet processing is not limited to this, and the sheet processing apparatus can switch the conveyance path. It can be applied to all sheet processes that occur.

  First, in step S601, the CPU 211 determines whether the analyzed page data is stored in the HDD 209 as a result of analyzing the received print job. If the analyzed page data is not stored, the CPU 211 executes the processing in step S601. When the analyzed page data is stored in the HDD 209 in S601, the process proceeds to S602.

  Reference numeral 901 in FIG. 9 shows an example of analyzed page data stored in the HDD 209. Here, it is composed of data for 12 pages, and it is assumed that multi-hole punching processing is designated for even pages.

  In step S <b> 602, the CPU 211 requires the multi-hole puncher 351 to reach the joining point 357 after the sheet on which the multi-hole punch is designated is conveyed from the conveyance port 317 and punched. Get time. In addition, the time required for a sheet, for which the multi-hole punch is not designated, to be conveyed from the conveyance port 317 and reach the joining point 357 is acquired. These times are fixed in the structure of the multi-hole puncher 351, and are assumed to be stored in the HDD 209 in advance. Then, the time difference is stored in the HDD 209 in association with the page, and the process proceeds to S603. This time difference is the difference in arrival time of the sheets up to the merge point 357 depending on whether or not sheet processing is performed. If the sheet conveyance speed is constant in the conveyance paths 353 and 354 and the time required for the punching process is negligible with respect to the conveyance time, this time difference is that of the conveyance path in which the sheet is conveyed corresponding to the presence or absence of the sheet processing. It may be considered as a difference in length. Therefore, for convenience, it is easy to understand that the difference between the lengths of the transport paths 353 and 354 is expressed by the number of sheets based on a predetermined paper size such as A4 size, for example. Expressed as the number of corresponding sheets. That is, in the case of the multi-hole puncher 351 according to the present embodiment, the number of sheets corresponding to the difference between the lengths of the sheet conveyance path 354 and the conveyance path 353 is calculated. This number is a value uniquely determined for each sheet processing apparatus. For example, if the number of sheets is set to “4” as the time difference, the A4 size sheet subjected to the punching process is delayed by four A4 size sheets than the A4 size sheet not subjected to the punching process. This means that the merging point 357 is reached.

A state in which the remaining merging time is stored in association with the page is indicated by reference numeral 905 in FIG.
Here, for example, since the sheet printed on the first page can reach the merge point immediately, the remaining merge time is “0”, and the sheet printed on the second page passes through the conveyance path 354 and is four sheets more than the sheet that is not punched. Due to the delay, the remaining merging time is “5”. Similarly, since the sheet printed on the third page can be merged after the sheet on the first page, the remaining merge time is “2”, and the sheet printed on the fourth page passes through the conveyance path 354, so the sheet printed on the second page Two more times later, the remaining merging time becomes “7”. Hereinafter, the remaining merging time of the sheet on which each page is printed in the same manner is shown at 905 in FIG.

  In step S <b> 603, the CPU 211 initializes a pointer P for acquiring data of each page to “1”. The pointer P is provided in the RAM 208. In step S604, the CPU 211 acquires page data indicated by the pointer P. In step S <b> 605, the CPU 211 determines whether sheet processing, that is, punch processing is set for the page data. If sheet processing is set, the process proceeds to S612, and the page data is output. On the other hand, if sheet processing is not set for the page data, the process proceeds to S616. In step S606, the CPU 211 acquires the remaining merging time of the page data younger than the target page data acquired in step S604, and proceeds to step S607. Here, at the beginning, the remaining merging time is “0”. In step S <b> 607, the CPU 211 determines whether there is a page that can precede the target page in the subsequent pages of the target page acquired in step S <b> 604. Is replaced with succeeding possible page data. The preceding page determination process in S607 will be described with reference to the flowchart of FIG.

  FIG. 7 is a flowchart for describing processing for determining whether or not there is a page that can be fed in advance in S <b> 607 in FIG. 6.

  First, in step S <b> 701, the CPU 211 obtains the difference (A (here, A = 4)) in the number of sheets that can be retained in the A4 size conversion between the multi-hole puncher sheet conveyance path 354 and the conveyance path 353, and proceeds to step S <b> 702. In step S <b> 702, the CPU 211 acquires the subsequent page data of the target page for the number of sheets within a predetermined range corresponding to the difference (A sheets) in the stayable number acquired in step S <b> 701, and multi-hole punch is specified in the page data. Determine whether or not. If there is a page for which multi-hole punch is designated, the process proceeds to S703. If there is no page for which multi-hole punch is designated, the process proceeds to S706, and it is determined that there is no page that can be fed in advance, and the process is terminated.

  In 904 of FIG. 9, since there is a page in which multi-hole punch is designated on the second page, the process proceeds to S703. In step S <b> 703, the CPU 211 obtains a paper interval from the target page to a page in which a multi-hole punch subsequent to the target page detected in step S <b> 702 is designated (this is N between papers including the target page). The process proceeds to S704.

  In the example of FIG. 9, N = 2 because there is a punch designation on the second page.

  Next, proceeding to S704, the CPU 211 determines that the multi-hole is within the range of the page corresponding to the difference (four sheets) in the stayable number acquired in S701, including the page in which the subsequent multi-hole punch acquired in S703 is specified. The number of pages (M) for which punching is designated is acquired, and the process proceeds to S705.

  In the example of FIG. 9, M = 2 because there are punch designations on the second and fourth pages.

  In step S <b> 705, the CPU 211 adds the number of preceding paper feed candidate pages to be overtaken (N sheets) and the number of next preceding paper feed candidate pages after the preceding paper feed candidate pages (M sheets). Then, it is determined whether the addition result exceeds the conveyance path difference (A = 4) depending on whether or not sheet processing is performed. If ((N + M)> 4), the process advances to step S706 to determine that there is no preceding page data. In this case, it is determined whether or not an extra waiting time occurs when the subsequent sheet processing is preceded by page data that is on. On the other hand, in the case of ((N + M) ≦ 4), the process proceeds to S707, where it is determined that the N-th preceding paper feed candidate page can be fed in advance, becomes a paper feed candidate target page, and the print order is determined to be changed. Return to the process.

  Returning to FIG. 6 again, the process advances to step S608, and the CPU 211 determines in step S607 whether there is page data that can precede the page data subsequent to the target page data. If it is determined that there is no page data that can be preceded, the process proceeds to S609. If it is determined that there is page data that can be preceded, the process proceeds to S616.

  In step S <b> 616, the CPU 211 determines whether there is page data that is longer than “0”, that is, page data that has not reached the sheet merging point 351. If it is determined that there is no unreachable page data, the process proceeds to S612. If it is determined that there is unreachable page data, the process proceeds to S617.

  In the example of FIG. 9, it is determined that the data of the second page can be preceded, and the order of the page data is changed as indicated by 906 in FIG. In this case, it is determined in S616 that there is no page data having a remaining merge time greater than “0”, the process proceeds to S612, the data of the second page determined to be capable of preceding is output, and the process proceeds to S613. In step S613, the CPU 211 acquires all the remaining merging times stored in the HDD 209, updates all the acquired remaining merging times by subtracting only the page data output in step S612, stores the updated data in the HDD 209, and stores one page. End the processing of the page data of the eye. 907 in FIG. 9 indicates the remaining merging time at this time.

  In step S614, the CPU 211 increments the pointer P by one. In step S615, the CPU 211 determines whether the value of the pointer P is greater than the last page number, that is, in the example of FIG. If the processing of the data for all pages has not been completed, the process returns to S604.

  Next, processing for the data of the next page in the state 906 of FIG. 9 will be described.

  In S604, page data of the target page (second page) is acquired. In step S606, the remaining merging time of the page that is younger than the second page data is “0”. In step S <b> 607, the CPU 211 determines whether there is a page that can precede the subsequent page data of the second page data. At this time, N = 3 is obtained in S703 of FIG. 7, and M = 2 is obtained in S704. As a result, it is determined in S705 that (N + M)> 4 and there is no page data that can be fed in advance. For this reason, it is determined as NO in S608, and the process proceeds to S609.

  In step S <b> 609, the CPU 211 selects a sheet corresponding to a page whose time to reach the confluence point 357 is later than the sheet on which the target page is printed, in the remaining merging time of the page data having a page number smaller than that of the target page data acquired in step S <b> 604. Determine if exists. If it is determined that there is no sheet whose arrival is delayed, the process proceeds to S612, and the target page data is output as it is.

  In the example of FIG. 9, since the data for the second page is determined NO in S609, the data for the second page is output in S612. Thereby, in S613, the page data output in S612 is subtracted to update the remaining merging time, stored in the HDD 209, and the processing of the page data for the second page is ended.

  908 in FIG. 9 indicates the remaining merging time at this time. At this time, the order of page data remains 906 in FIG.

  Next, processing for the data of the third page in the state 906 of FIG. 9 will be described.

  In S604, the data of the third page is acquired, and the process proceeds to S606. The remaining merging time of the page data younger than the third page data is “0”. In step S607, the CPU 211 determines whether there is a page that can precede the subsequent page data of the third page data. At this time, N = 2 is obtained in S703 of FIG. 7, and M = 2 is obtained in S704. As a result, (N + M) = 4 is set in S705, and the flow advances to S707 to determine that there is page data that can be fed in advance. For this reason, it determines with YES by S608, and progresses to S616. In S616, it is determined whether there is page data that has already been fed and the merge time is longer than “0”. Here, as indicated by reference numeral 908 in FIG. 9, since there is page data whose merging time is longer than “0”, the process proceeds to S617. In step S617, the CPU 211 determines how many sheets are not subjected to multi-hole punching between the page data having the longest remaining merge time and the preceding possible page data. Then, the sheet feeding process and the printing process are made to wait for the sheet feeding time of the sheet not subjected to the multi-hole punch so that the sheet not subjected to the multi-hole punch can be inserted between the sheets subjected to the multi-hole punch. And proceed to S611.

  In the example of FIG. 9, the remaining merging time of the first page is the largest, “3”, and there are two sheets between the fourth page, which is the preceding sheet that can be fed, so the space for two sheets is reduced. It will be free. An example of rearranging the page data in this way is shown at 911 in FIG.

  By controlling in this way, when a sheet that performs multi-hole punches merges with a normal conveyance path at a sheet merge point 357, a sheet that does not perform multi-hole punches between the sheets that perform multi-hole punches is collided. Therefore, a desired output can be obtained.

  In step S613, the CPU 211 updates the merge remaining time by subtracting two spaces. This state is shown at 910 in FIG. Here, the remaining merge time of the third page data is originally “0”, but it becomes “2” by preceding the subsequent fourth page data and opening 2 spaces, and the fourth page data. The remaining merging time of data is “5” by preceding.

  In step S612, page data is output. In step S613, the remaining merge time is updated. The result is shown at 912 in FIG.

In step S <b> 609, the CPU 211 determines whether there is page data in which the time to reach the merging point 357 is later than the sheet on which the target page data is printed, in the remaining merging time of page data having a page number smaller than that of the target page data. judge. If it is determined that there is no page data that is delayed in arrival, the process proceeds to S612, and the target page data is output as it is. On the other hand, if it is determined in S609 that there is page data whose arrival is delayed, the process proceeds to S610. In step S <b> 610, the CPU 211 obtains the sheet feeding start time of the sheet on which the target page data is printed from the remaining time until the sheet on which the page data that has arrived at the merging point 357 is delayed. Then, a setting is made to wait for the sheet feeding process and printing process of the sheet until the acquired sheet feeding start time, and the process proceeds to S611. In S610, as in S617 described above, a space is provided so that the sheet is delayed by the corresponding sheet.
In S611, the CPU 211 obtains the remaining merging time of all page data stored in the HDD 209, subtracts the waiting time added in S610 from the remaining merging time after the waiting page data, and stores it again in the HDD 209. The process proceeds to S614.

  Reference numeral 913 in FIG. 9 is a diagram for explaining the remaining merging time when the space for two sheets is thus opened.

  By controlling in this way, when the page data that has been output in advance must be output before the page data that has been overtaken, the page data that has been overtaken is kept waiting for the required time, so that the correct order is reached at the junction. Can be discharged.

  In the same manner, by changing the order of the page data in the same manner, it has been necessary to complete the print job indicated by 901 in the past, as indicated by 902 in FIG. In the embodiment, the time can be shortened as indicated by reference numeral 903.

  By controlling in this way, the sheet on which the page data on which the preceding page data has passed is printed can reach the joining point until the sheet on which the preceding page data is printed reaches the sheet joining point. In this way, a desired product can be obtained without the sheet on which the page data preceded at the junction point is printed colliding with the sheet on which the overtaken page data is printed.

  By configuring as described above, even if the sheet processing is switched for each page, the total processing time can be shortened by the preceding control. Furthermore, even if the sheet processing apparatus does not execute complicated control, it is possible to obtain a highly productive system simply by the printing apparatus changing the sheet feeding and printing order.

[Embodiment 2]
Next, as a second preferred embodiment of the present invention, a description will be given of printing / paper feeding control when the sheet processing setting is switched for each page.

  FIG. 8 is a flowchart illustrating control of the printing apparatus main body 100 in the printing system 1000 according to the second embodiment of the present invention. Note that a program for executing this processing is stored in the ROM 207, and the processing shown in this flowchart is executed by the CPU 211 executing this program. Further, the analysis processing of the print job received by the printing apparatus 100 is the same as that in the flowchart of FIG.

  The sheet processing apparatus 351 according to the second embodiment is configured such that a sheet that has been subjected to sheet processing can wait immediately before the sheet joining point 357 until a refeed instruction is received. The conveyance path 354 can accommodate a plurality of sheets, and the sheet standby processing is performed in the sheet processing apparatus. Therefore, in the second exemplary embodiment, the standby instruction for the sheet in the sheet processing apparatus is not executed by the CPU 211 and is not described in the flowchart of FIG. However, the present invention is not limited to this, and the CPU 211 of the printing apparatus may perform the standby instruction in the sheet processing apparatus. Hereinafter, with reference to the flowchart of FIG. 8, the control in the case where the multi-hole punch instruction is switched for each page will be described in detail.

  FIG. 10 is a diagram illustrating an example of changing the output order of the print job according to the second embodiment and the data of each page for which printing is designated in the print job. Hereinafter, the flowchart of FIG. 8 will be described with reference to FIG.

  First, in step S801, the CPU 211 determines whether or not analyzed page data is already stored in the HDD 209. If the analyzed page data is stored, the process proceeds to step S802. The analyzed data in this case is also the same as that indicated by 901 in FIG. In step S802, the CPU 211 initializes the pointer P provided in the RAM 208 to “1” as in step S602 in FIG. In step S <b> 803, the CPU 211 obtains the difference (A (A = 4)) in the number of sheets that can be retained in the A4 size conversion between the multi-hole puncher sheet conveyance path 354 and the conveyance path 353. In step S804, the CPU 211 acquires page data of the HDD 209 designated by the pointer P. First, page data for the first page is acquired.

  In step S805, the CPU 211 determines whether the page data includes sheet processing, here, multi-hole punch designation. If there is, the process proceeds to step S808. If not, the process proceeds to step S806. In step S806, the CPU 211 obtains subsequent page data of the target page for the page corresponding to the difference (four sheets) in the stayable number acquired in step S803, and page data in which multi-hole punching is specified for the page data. Determine if there is any. If there is no page data in which multi-hole punch is designated, the process proceeds to S814. If there is page data in which multi-hole punch is designated, the process proceeds to S807. In step S <b> 807, the CPU 211 determines that the first page data in which the multi-hole punch detected in step S <b> 806 is designated as preceding page data, changes the order of the page data with the target page data, and proceeds to step S <b> 808.

  This state is indicated by reference numeral 1001 in FIG.

  In step S <b> 808, the CPU 211 obtains the number of sheets staying in the conveyance path 354 that conveys the sheet to be punched with multiple holes, and has reached the stayable number of sheets (four sheets) in the conveyance path 354, that is, the conveyance path 354. Determine if is full. If the CPU 211 determines in S808 that the stayable number has been reached, the process proceeds to S810, and if it is determined that the stayable number has not been reached, the process proceeds to S809. In the second embodiment, the number of sheets staying in the transport path 354 is not limited to the number of sheets actually staying in the execution transport path, but has already been output by printing the page data. A sheet conveyed to the hole puncher execution conveyance path 354 is also included. In other words, the number of sheets that have not been instructed to be re-fed to be discharged to the merge point 357 after the multi-hole punch is completed among the already fed sheets for which multi-hole punch is executed is acquired. .

  In step S <b> 809, the CPU 211 increments the sheet counter of the sheet staying in the multi-hole puncher conveyance path 354, saves it in the HDD 209, and proceeds to step S <b> 811. On the other hand, in step S810, the CPU 211 sets a space before the page data in which the multi-hole punch is designated by the number of sheets waiting to be re-feeded at the top of the sheet waiting for re-feed in the multi-hole puncher conveyance path 354. Free up. Then, the multi-hole puncher 351 is notified of the re-feed timing of the sheet waiting for re-feed. Further, the sheet count staying in the conveyance path 354 of the multi-hole punch 351 is subtracted by the number of sheets waiting for refeeding at the head, and the sheet count staying by the number of sheets of the target page is added. The process proceeds to S811 after the file is saved again.

  In the example of FIG. 10, since page data for which punch processing for the fourth page is specified is found when P = 2, the page data comes before the original data for the first page. Further, when P = 3, page data for which punch processing for the sixth page is designated is found, so that page data comes before the original first page data. As a result, the page data output order is changed as indicated by 1003 in FIG.

  Next, when P = 4, the determination in S806 is NO, so the process proceeds to S814, and the page number of the first page data remaining in the sheet processing apparatus, that is, the original page data of the second page is acquired. In step S815, the page number “1” of the target page (originally the first page) is compared with the page number “2” of the remaining first page data. At this time, since the determination in S815 is NO, the process proceeds to S811, and the page data of the page number “1” of the target page (originally the first page) is output. This state is indicated by 1004 in FIG.

  Next, when P = 5, since sheet processing is set for the page data of the eighth page in S806, the page data of the eighth page is added before the page data of the target page (originally the third page) in S807. come. This state is indicated by 1005 in FIG.

  If P = 6 and the page data of the target page (originally the third page), the determination in S806 is NO, and the first page data remaining in the sheet processing apparatus in S814, that is, the original four pages Get the page number of the page data of the eye. In step S815, the page number “3” of the target page (originally the third page) is compared with the page number “2” of the first page data remaining in the sheet processing apparatus. At this time, since the determination in S815 is YES, the process proceeds to S816, and a space for one sheet is made before the page data of the page number “3” of the target page (originally the third page). This state is indicated by 1006 in FIG. At the timing of this space, a sheet on which page data of the first page number “2” staying in the sheet processing apparatus is printed is output. In step S817, the number of page data remaining in the sheet processing apparatus is decreased by 1, and the process advances to step S811.

  In the second embodiment, the multi-hole puncher 351 is notified in advance of the refeed timing with a conveyance interval for a sheet waiting for refeeding, but the present invention is not limited to this. For example, a refeed instruction may be stacked until the multi-hole puncher 351 actually re-feeds, and the multi-hole puncher 351 may be instructed to re-feed at the actual re-feed timing.

  Alternatively, control may be performed so that the conveyance of all sheets is stopped at a convenient position immediately before the merge point 357, and then refeeding is performed on a sheet waiting for refeeding of the multi-hole puncher 351. good.

  In step S811, the CPU 211 determines a paper feed port, a paper discharge destination, and sheet processing according to the page data setting of the first page, issues a paper feed instruction to the determined paper feed port, and outputs page data to be printed. Stack and complete the sheet feeding process for one sheet. In step S812, the pointer P is incremented by one, and the processing advances to step S813. The CPU 211 determines whether the processing of all pages of data has been completed. If the processing has been completed, the CPU 211 ends the processing. Return to.

  In step S <b> 814, the CPU 211 obtains the page number of the sheet that has already been fed and is staying in the sheet processing apparatus, and the process advances to step S <b> 815. In step S815, the CPU 211 compares the page number acquired in step S814 with the page number of the current target page. If the CPU 211 determines that there is no page number younger than the target page, the CPU 211 proceeds to step S811, and continues the paper feed process. Execute.

  If the CPU 211 determines in step S815 that there is page data having a page number lower than that of the target page, the process advances to step S816. In step S816, the CPU 211 obtains the number of sheets to be refeeded and the paper size having a page number smaller than that of the target page detected in step S815, and sets the sheet feeding and printing intervals by the number of sheets to be refeeded. The setting is made so as to be free, and the process proceeds to S817. In step S817, the CPU 211 subtracts the number of sheets staying in the conveyance path 354 of the multi-hole puncher 351 stored in the HDD 209 by the amount corresponding to the empty space in step S816, and stores it again in the HDD 209 before proceeding to step S811.

  As described above, according to the second embodiment, even when the sheet processing setting is switched for each page, up to the point P = 12 in FIG. 10 with respect to the conventional required time as indicated by 902 in FIG. Can be executed by processing. As a result, a desired output can be obtained with less delay, and various sheet controls can be implemented flexibly.

(Other embodiment 2)
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, etc.) of the system or apparatus reads the program. It is a process to be executed.

  The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the spirit and scope of the present invention. Therefore, in order to make the scope of the present invention public, the following claims are attached.

  DESCRIPTION OF SYMBOLS 100 ... Printing apparatus main body, 200 ... Sheet processing apparatus, 204 ... Operation part, 205 ... Control part, 351 ... Multi-hole puncher, 353, 354 ... Sheet conveyance path

Claims (8)

A sheet processing system including a printing apparatus capable of receiving a print job and a sheet processing apparatus that performs sheet processing on a sheet,
Determining means for analyzing the print job and determining whether or not sheet processing is set for the page data of each page specified in the print job;
When the determination unit determines that the sheet processing is set for the second page data that follows the first page data within a predetermined range, the subsequent second page data is printed prior to the first page data. Preceding control means for controlling the apparatus to output and print the apparatus;
The sheet printed with the second page data preceded by the preceding control means and the sheet printed with the first page data are output from the sheet processing apparatus in the order specified in the print job. Paper feed control means to control,
A sheet processing system comprising:   The sheet processing apparatus includes a first sheet conveyance path that conveys a sheet when the sheet processing is performed, and a second sheet conveyance path that conveys a sheet when the sheet processing is not performed. The sheet processing system according to claim 1, wherein a length of the sheet conveyance path is longer than a length of the second sheet conveyance path.   The sheet processing system according to claim 2, wherein the predetermined range corresponds to a difference between a length of the first sheet conveyance path and a length of the second sheet conveyance path.   4. The sheet processing system according to claim 2, wherein the sheet processing apparatus joins and discharges the sheets conveyed through the first sheet conveyance path and the second sheet conveyance path at a merge point. 5. The paper feed control means
When the sheet on which the second page data is printed passes the sheet on which the first page data is printed at the joining point, the timing at which the sheet on which the second page data is printed reaches the joining point is delayed in sheet units. The sheet processing system according to claim 4.   The sheet feeding control unit can store a plurality of sheets in the first sheet conveyance path, and a page number corresponding to the first sheet of the plurality of sheets in the first sheet conveyance path is next to the first sheet conveyance path. When the page number corresponding to the sheet conveyed on the two-sheet conveyance path is younger, the conveyance of the sheet conveyed on the second sheet conveyance path is delayed for each sheet, and the leading sheet is output. The sheet processing system according to claim 4. A control method for controlling a sheet processing system including a printing apparatus capable of receiving a print job and a sheet processing apparatus that performs sheet processing on a sheet,
A determination step of analyzing the print job and determining whether or not sheet processing is set for the page data of each page specified in the print job;
If it is determined in the determination step that the sheet processing is set for the second page data that follows the first page data within a predetermined range, the subsequent second page data is printed prior to the first page data. A preceding control step for controlling the apparatus to output and print the apparatus;
The sheet printed with the second page data preceded in the preceding control step and the sheet printed with the first page data are output from the sheet processing apparatus in the order specified in the print job. A paper feed control process to be controlled,
A control method for a sheet processing system, comprising:   A program for causing a computer to execute the control method according to claim 7.

Images