JP2015003520A - Printing system, printing method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To utilize post-processing by an in-line finisher capable of conveying sheets from a printing device through a sheet conveying passage without accompanying with printing by the printing device.SOLUTION: A printing system comprises: execution means for executing an in-line job for executing post-processing relative to a sheet printed by a printing device by a post-processing device and an off-line job for executing the post-processing relative to the sheet by the post-processing device without accompanying with printing by the printing device; and control means for restricting execution of the in-line job when the sheets are set on a paper feeding part which is a paper feeding source of the off-line job executed by the execution means.

Description

  The present invention relates to a printing system, a printing system control method, and a program.

  Conventionally, a POD (Print On Demand) printing system using an electrophotographic printing apparatus or an inkjet printing apparatus has been proposed (see Patent Document 1). Such a POD printing system eliminates the need for block composition and other complicated operations.

US Patent Publication US-2004-0190057

However, the conventional printing system is not configured to use post-processing by a post-processing device (inline finisher) capable of transporting a sheet from a printing device via a sheet transport path without printing by the printing device. It was.
Accordingly, it has not been possible to cope with a further problem that occurs when post-processing by an inline finisher can be used without printing. Here, regarding a further problem, a job that performs post-processing by the post-processing device with printing by the printing device is defined as an inline job, and a job that performs post-processing by the post-processing device without printing by the printing device is offline Define and describe as a job.

  For example, in order to execute an offline job, the user sets a sheet processed by the execution of the offline job in an inserter provided in the post-processing apparatus. In such a situation, if the inline job is executed by the printing apparatus before the offline job is executed, the sheet for the offline job set in the inserter may be used for the inline job. .

  The present invention has been made to solve the above problems. It is an object of the present invention to receive and store a first type job received while execution of the first type job is restricted, and store it after execution of the second type job is completed. It is to provide a mechanism for executing a first type job.

The printing apparatus of the present invention that achieves the above object has the following configuration.
A printing apparatus prints an image on a sheet, conveys the sheet to a sheet processing apparatus, and the sheet processing apparatus executes sheet processing on the sheet, and the printing apparatus prints an image on the sheet. Execution means for executing a second type job for executing sheet processing on a sheet by the sheet processing apparatus without printing, and the second type job according to receiving a request for executing the second type job. Control means for restricting execution of one type of job and executing the second type of job in a state in which execution of the first type of job is restricted; and the first type by the control means Receiving means for receiving the first type job while the execution of the job is restricted, and receiving by the receiving means Storage means for storing the first type job, and the control means executes the first type job stored in the storage means after the execution of the second type job is completed. It controls to do.

  According to the present invention, the first type job received while the execution of the first type job is restricted is stored, and after the execution of the second type job is completed, the stored first type is stored. A type of job can be executed.

It is a figure which shows the example of whole structure of the printing environment containing a printing system. It is a block diagram explaining the structure of the printing system shown in FIG. It is sectional drawing which shows the structure of the sheet processing apparatus connected to the printing apparatus. It is sectional drawing explaining the structure of a glue binding machine. It is sectional drawing explaining the internal structure of a saddle stitch binding machine. It is sectional drawing explaining the internal structure of a large capacity inserter. It is a top view explaining the structure of an operation part. It is a figure which shows an example of UI displayed on a touch panel part. It is a figure which shows an example of UI displayed on a touch panel part. It is a flowchart which shows the control procedure of an image processing apparatus. It is a flowchart which shows the control procedure of an image processing apparatus.

Next, the best mode for carrying out the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is a diagram for explaining an example of the overall configuration of a printing environment including printing systems 1000 and 1001 to be controlled in the present embodiment.
A printing system 1000 shown in FIG. 1 includes the printing system 1000 of this embodiment, a PC (server computer) 103, and a PC (client computer) 104 as components. Also provided are a paper folding machine 107, a cutting machine 109, a saddle stitch bookbinding machine 110, a case binding machine 108, a network scanner 102, and the like. As described above, a plurality of apparatuses are prepared in the printing system 1000. Further, devices other than the saddle stitch binding machine 110 constituting the printing system are connected via a network 101.

The printing systems 1000 and 1001 shown in this example include a printing apparatus 100 and a sheet processing apparatus 200 as shown in FIG.
In this embodiment, the printing apparatus 100 will be described by taking an MFP (Multi Function Peripheral) having a plurality of functions such as a copy function and a printer function as an example. However, the printing apparatus 100 may be a single function type (SFP (Single Function Peripheral)) printing apparatus having only a copy function or only a printer function.

The PC 103 manages data transmission / reception with various devices connected to the network 101. The PC 104 transmits image data to the printing apparatus 100 and the PC 103 via the network 101. Further, the paper folding machine 107 performs a folding process on the sheet printed by the printing apparatus 100.
The case binding machine 108 performs a case binding process on the sheet printed by the printing apparatus 100. The cutting machine 109 performs a cutting process on a sheet printed by the printing apparatus 100 for each sheet bundle including a plurality of sheets. The saddle stitch bookbinding machine 110 performs a saddle stitch bookbinding process on a sheet printed by the printing apparatus 100.

When using the paper folding machine 107, the case binding machine 108, the cutting machine 109, and the saddle stitch binding machine 110, the user takes out the sheet printed by the printing system 1000 or 1001, sets it in the apparatus to be used, and uses the apparatus. Execute the process. The printing system 1001 has the same mechanism as that of the printing system 1000, but is not limited thereto.
Next, the configuration of the printing systems 1000 and 1001 will be described with reference to the system block diagram of FIG.

FIG. 2 is a block diagram illustrating the configuration of the printing systems 1000 and 1001 shown in FIG. Of the units shown in FIG. 2, units other than the sheet processing apparatus 200 are included in the printing apparatus 100. An arbitrary number of sheet processing apparatuses 200 can be connected to the printing apparatus 100.
The printing systems 1000 and 1001 are configured so that sheet processing (also referred to as post-processing) for a sheet printed by the printing apparatus 100 can be executed by the sheet processing apparatus 200 connected to the printing apparatus 100.
The sheet processing apparatus 200 is configured to be communicable with the printing apparatus 100, and can execute sheet processing as described below in response to an instruction from the printing apparatus 100. The scanner unit 201 reads an image on a document, converts it into image data, and transfers it to another unit.
The external I / F 202 transmits and receives data to and from other devices connected to the network 101. The printer unit 203 prints an image based on the input image data on a sheet. The operation unit 204 includes a key input unit 4002 and a touch panel unit 4001 which will be described later with reference to FIG. 7, and receives instructions from the user via them. In addition, the operation unit 204 performs various displays on the touch panel included in the operation unit 204.

A control unit 205 comprehensively controls processing and operations of various units included in the printing systems 1000 and 1001. That is, the control unit 205 also controls the operation of the printing apparatus 100 and the sheet processing apparatus 200 connected to the printing apparatus 100. The ROM 207 stores various computer programs executed by the control unit 205. For example, the ROM 207 stores a program for causing the control unit 205 to execute various processes in the flowcharts described later, and a display control program necessary for displaying various setting screens described later.
The ROM 207 stores a program for executing an operation of interpreting PDL (page description language) code data received from the PC 103, the PC 104, or the like, and developing the raster image data into raster image data. In addition, the ROM 207 stores a boot sequence, font information, and the like. The RAM 208 stores image data sent from the scanner unit 201 and the external I / F 202, various programs loaded from the ROM 207, and setting information.

The RAM 208 also includes information regarding the sheet processing apparatus 200 (number of sheet processing apparatuses 200 (0 to n) connected to the printing apparatus 100, information regarding the function of each sheet processing apparatus 200, and each sheet processing apparatus 200). Connection order, etc.).
An HDD (Hard Disk Drive) 209 includes a hard disk and a drive unit that reads / writes data from / to the hard disk. The HDD 209 is a large-capacity storage device for storing image data input from the scanner unit 201 or the external I / F 202 and compressed by the compression / decompression unit 210. The control unit 205 can print the image data stored in the HDD 209 by the printer unit 203 based on an instruction from the user.

The control unit 205 can also transmit image data stored in the HDD 209 to an external device such as the PC 103, the printing system 1000, or 1001 via the external I / F 202 based on an instruction from the user. Similarly, the control unit 205 can acquire image data from an external device such as the PC 103 or the printing system 1000 or 1001 via the external I / F 202. The control unit 205 can also search for an external device connected to the network 101 via the external I / F 202.
The compression / decompression unit 210 performs compression / decompression operations on image data and the like stored in the RAM 208 and the HDD 209 by various compression methods such as JBIG and JPEG.
Next, the configuration of the printing system 1000 will be described with reference to FIG.
FIG. 3 is a cross-sectional view illustrating the configuration of the printing apparatus 100 illustrated in FIG. 1 and the sheet processing apparatus 200 connected to the printing apparatus 100. Note that the printing system 1001 can have the same configuration.

In FIG. 3, an automatic document feeder (ADF) 301 separates a bundle of documents set on a stacking surface of a document tray from a first page document in order of pages, and scans the document with a scanner 302. Transport to the platen glass. A scanner 302 reads an image of a document conveyed on a platen glass and converts it into image data by a CCD.
A rotating polygon mirror (polygon mirror or the like) 303 receives a light beam such as a laser beam modulated according to image data, and irradiates the photosensitive drum 304 as reflected scanning light through a reflection mirror. The latent image formed by the laser beam on the photosensitive drum 304 is developed with toner, and the toner image is transferred to the sheet material attached on the transfer drum 305. A series of image forming processes is sequentially performed on yellow (Y), magenta (M), cyan (C), and black (K) toners to form a full-color image. After the four image forming processes, the sheet material on the transfer drum 305 that has been printed in full color is separated by the separation claw 306 and conveyed to the fixing device 308 by the pre-fixing conveyance device 307.

The fixing device 308 is configured by a combination of a roller and a belt, and has a built-in heat source such as a halogen heater, and melts and fixes the toner on the sheet material on which the toner image is transferred by heat and pressure.
The paper discharge flapper 309 is configured to be swingable about a swing shaft, and defines the sheet material conveyance direction. When the paper discharge flapper 309 is swinging in the clockwise direction in the figure, the sheet material is conveyed straight and is discharged out of the apparatus by the paper discharge roller 310. The control unit 205 controls the printing apparatus 100 to execute single-sided printing according to a series of sequences as described above.

On the other hand, when forming images on both sides of the sheet material, the paper discharge flapper 309 swings counterclockwise in the figure, and the sheet material is changed in the downward direction and sent to the double-sided conveyance unit.
The double-sided conveyance unit includes a reverse flapper 311, a reverse roller 312, a reverse guide 313, and a double-sided tray 314. The reverse flapper 311 swings around the swing shaft and defines the sheet material conveyance direction.
When processing a double-sided print job, the control unit 205 swings the sheet printed on the first surface of the sheet by the printer unit 203 in the counterclockwise direction of the reverse flapper 311 through the reverse roller 312. Then, control is performed so as to feed the reversing guide 313.

Then, the reverse roller 312 is temporarily stopped in a state where the rear end of the sheet material is held between the reverse rollers 312, and then the reverse flapper 311 is swung clockwise in the drawing. In addition, the reverse roller 312 is rotated in the reverse direction.
Thus, the sheet is switched back and conveyed, and the sheet is controlled to be guided to the double-sided tray 314 in a state where the trailing edge and the leading edge of the sheet are switched. The sheet material is once stacked on the double-sided tray 314, and then the sheet material is fed again to the registration roller 316 by the refeed roller 315.

At this time, the sheet material is fed with the surface opposite to the transfer process on the first surface facing the photosensitive drum. Then, the second image is formed on the second surface of the sheet in the same manner as described above.
Then, images are formed on both surfaces of the sheet material, and the sheet is discharged from the inside of the printing apparatus 100 main body to the outside through the discharge roller 310 through a fixing process. The control unit 205 controls the printing apparatus 100 to execute double-sided printing according to the series of sequences as described above.
In addition, the printing apparatus 100 includes a paper feeding unit that stores sheets required for printing processing. The sheet feeding unit includes sheet feeding cassettes 317 and 318 (for example, each capable of storing 500 sheets), a sheet feeding deck 319 (for example, capable of storing 5000 sheets), a manual feed tray 320, and the like.

The sheet feeding cassettes 317 and 318 and the sheet feeding deck 319 can set various sheets of different sizes and materials for each sheet feeding unit. Various sheets including special sheets such as an OHP sheet can be set on the manual feed tray 320.
The paper feed cassettes 317 and 318, the paper feed deck 319, and the manual feed tray 320 are respectively provided with paper feed rollers, and the sheets are continuously fed one by one by the paper feed rollers.

Next, the sheet processing apparatus 200 shown in FIG. 3 will be described. As long as the sheet processing apparatus 200 in the printing system 1000 according to the present embodiment can convey a sheet from an upstream apparatus to a downstream apparatus via a sheet conveyance path, an arbitrary number of apparatuses of any type can be connected. it can.
For example, as shown in FIG. 3, the large capacity stacker 200-a, the inserter 200-d, the gluing bookbinding machine 200-b, and the saddle stitch bookbinding machine 200-c are connected in the order close to the printing apparatus 100. Each can be selectively used in the printing system 1000.
Each of the sheet processing apparatuses 200 includes a sheet discharge unit, and a user can take out a sheet that has been subjected to sheet processing from the sheet discharge unit of each sheet processing apparatus.
The control unit 205 prints an execution request for the type of sheet processing desired by the user from the types of sheet processing types that can be executed by the sheet processing apparatus 200 connected to the printing apparatus 100 via the operation unit 204. Accept with request.
Then, in response to receiving a print execution request for a job to be processed from the user via the operation unit 204, the control unit 205 causes the printer unit 203 to execute print processing required for the job.

Then, the control unit 205 conveys the sheet subjected to the printing process to a sheet processing apparatus capable of executing a sheet process desired by the user via the sheet conveyance path, and causes the sheet processing apparatus to execute the sheet process.
For example, when the printing system 1000 has the system configuration shown in FIG. 3, the job to be processed that has received a print execution request from the user is a job instructed to perform mass stacking processing by the large-capacity stacker 200-a. And This job is called a “stacker job”.
When processing this stacker job with the system configuration of FIG. 3, the control unit 205 passes the sheet corresponding to this job printed by the printing apparatus 100 through point A in FIG. -Transport to inside. Thereafter, the control unit 205 causes the large-capacity stacker 200-a to execute the job stacking process.
Then, the control unit 205 does not convey the printed matter corresponding to the job that has been loaded by the large-capacity stacker 200-a to another apparatus (for example, a subsequent apparatus), and the inside of the large-capacity stacker 200-a. It is held at the paper discharge destination X.
Further, in the system configuration of FIG. 3, a job to be processed that has received a print execution request from a user is a sheet process (for example, a case binding process or a sheet binding process). Assume that the job is instructed to perform bookbinding processing. This job is called a “glue binding job”.

When processing this gluing bookbinding job with the system configuration of FIG. 3, the control unit 205 glues the sheet printed by the printing apparatus 100 via points A, A ′, and B in FIG. 3. 200-b is transported inside.
Thereafter, the control unit 205 causes the glue binding apparatus 200-b to execute the glue binding process for the job. Then, the control unit 205 does not convey the printed material of this job, which has been subjected to the gluing bookbinding process by the gluing bookbinding machine 200-b, to another apparatus (for example, a subsequent apparatus), and directly inside the gluing bookbinding machine 200-b. At the paper discharge destination Y.

Furthermore, for example, it is assumed that the processing target job that has received a print execution request from the user in the system configuration of FIG. 3 is a job instructed to perform sheet processing by the saddle stitch binding machine 200-c.
Examples of sheet processing by the saddle stitch binding machine 200-c include saddle stitch binding, punching, cutting, shift paper discharge, and folding. Here, this job is referred to as a “saddle stitching job”.

When this saddle stitching job is processed with the system configuration shown in FIG. 3, the control unit 205 passes the points A, A ′, B, and C through the sheet of the job printed by the printing apparatus 100. Then, it is conveyed to the saddle stitch binding machine 200-c.
Thereafter, the control unit 205 causes the saddle stitch binding machine 200-c to execute the sheet processing of the job. Then, the control unit 205 holds the printed matter of the saddle stitch bookbinding job, which has been subjected to the sheet processing by the saddle stitch bookbinding machine 200-c, in the paper discharge destination Z of the saddle stitch bookbinding apparatus 200-c.
There are a plurality of delivery destination candidates in the delivery destination Z. This is used when the saddle stitch binding machine 200-c can execute a plurality of types of sheet processing and separates the paper discharge destination for each sheet processing.
Further, for example, it is assumed that a job to be processed that receives a print execution request from a user in the system configuration is a job instructed to perform sheet processing by the inserter 200-d.

This job is called an “inserter paper feed job”. This inserter paper feed job can further use a sheet processing apparatus connected downstream. A case where this inserter paper feed job is processed with the system configuration of FIG. 3 will be described.
The control unit 205 inserts the sheet fed from the inserter 200-d into the sheet of this job printed by the printing apparatus 100, and then conveys the sheet to the sheet processing apparatus according to the designated sheet processing. Process.
In FIG. 3, since the system is such that the glue binding machine 200-b and the saddle stitch bookbinding machine 200-c are connected downstream of the inserter 200-d, the glue binding job and saddle stitch bookbinding job described above are executed. can do.
Also, the inserter paper feed job does not necessarily need to be printed by the printing apparatus 100. That is, only the sheet fed from the inserter 200-d can be conveyed downstream, and the sheet processing can be performed using the designated sheet processing apparatus.
As described with reference to FIGS. 1 to 3, the printing system 1000 according to the present embodiment can connect a plurality of sheet processing apparatuses having different functions to the printing apparatus 100 in an arbitrary combination.
<Internal Configuration of Sheet Processing Apparatus 200>
Next, the internal configuration of the sheet processing apparatus 200 that can be connected to the printing apparatus 100 will be described by type with reference to FIGS. 4, 5, and 8.

  FIG. 4 is a cross-sectional view illustrating the configuration of the gluing bookbinding machine 200-b shown in FIG. The gluing bookbinding machine shown in this example selectively conveys a sheet conveyed from an upstream apparatus to three conveyance paths. One is a cover path, one is a body path 405, and one is a straight path 402. The gluing bookbinding machine 200-b has an inserter path 403. An inserter path 403 of the inserter 400 is a sheet conveyance path for conveying a sheet placed on the inserter tray 401 to the cover path 404.

A straight path 402 of the gluing bookbinding machine 200-b shown in FIG. 4 is a sheet conveyance path for conveying a sheet of a job that does not require gluing bookbinding by the gluing bookbinding machine 200-b to a subsequent apparatus. Further, a body path 405 and a cover path 404 of the gluing bookbinding machine 200-b shown in FIG. 4 are sheet conveyance paths for conveying sheets necessary for creating case-bound printed products.
For example, when creating a case binding print using the glue binding machine 200-b, the control unit 205 causes the printer unit 203 to print text image data to be printed on a text sheet of the case binding print. .

When a case-bound printed product for one book is created, a sheet bundle for one book of the body sheet is wrapped with one cover. In case binding, this sheet bundle for the body is called “body”. This “body” is sometimes called “text” and has the same meaning.
The control unit 205 performs control so that the sheet printed by the printing apparatus 100 serving as the body is conveyed to the body path 405 illustrated in FIG. 4. When the case binding process is performed, the control unit 205 executes a process of wrapping the body printed by the printing apparatus 100 with a cover sheet conveyed through the cover path 404.
For example, the control unit 205 sequentially stacks the main sheets conveyed from the upstream apparatus in the stack unit via the main body path 405 of FIG. When the number of sheets on which the body data is printed is stacked in the stack unit 411 corresponding to one sheet, the control unit 205 conveys one cover sheet required for the job via the cover path 404. Let

The control unit 205 shown in FIG. 2 controls the gluing unit 410 in FIG. 4 so as to perform gluing processing on the spine portion of the sheet bundle for one set corresponding to the main body.
Thereafter, the control unit 205 controls so that the back cover part of the main body and the center part of the cover part are joined by the glue part. When joining the main body to the cover, it is conveyed so that the main body is pushed into the lower part of the apparatus. As a result, the cover is folded so that the body is wrapped with a single cover. Thereafter, the sheet bundle for one set is stacked on the turntable 408 in FIG. 4 along the guide 412.

After the sheet bundle for one set is set on the turntable 408 in FIG. 4, the control unit 205 causes the cutter unit 406 in FIG. 4 to execute the sheet bundle cutting process. At this time, the cutter unit 406 can execute a three-way cutting process for cutting three ends other than the end corresponding to the spine portion of the sheet bundle for one set.
Thereafter, the control unit 205 pushes the sheet bundle that has been subjected to the three-way cutting process in the direction of the basket using the width adjusting unit 409 and stores the sheet bundle in the basket 407. In this way, it is created by the case binding process. In this gluing bookbinding machine, in addition to “case binding processing”, “top glue binding processing” can be selectively performed. “Temperature bookbinding” is a bookbinding in a form without a cover in case binding. In other words, the bookbinding is performed by gluing only the main body (text).

When this “sheet binding process” is executed, control is performed so that the cover sheet is not used in the process executed in the “case binding process”. That is, control is performed so that processing relating to the cover is not performed. The cover sheet used in the case binding mode is not fed from the sheet feeding unit itself.
In addition, this gluing bookbinding machine can not only process the sheet conveyed from the upstream apparatus, but also perform the case binding process using the sheet fed from the paper feeding unit of the own apparatus or the top glue binding process. . For example, a case will be described in which a case-bound printed material is created by using this gluing bookbinding machine alone. First, the operator sets a sheet to be processed on the inserter tray 401 shown in FIG.

Then, the control unit 205 feeds the sheet set on the inserter tray 401 by using the inserter 400 shown in FIG. Next, the control unit 205 controls to convey the body sheet to the body path shown in FIG.
Then, the control unit 205 performs a process of conveying the cover sheet, which is also fed from the inserter tray 401, through the cover path 404, and wrapping the body sheet. The subsequent processing is the same as described above. The gluing bookbinding machine 200-b includes a sensor for detecting whether or not a sheet is set on the inserter tray 401 of the inserter 400, and the detection result of the presence or absence of the sheet by the sensor is a signal line (not shown). To the control unit 205. Thereby, the control unit 205 can detect whether or not a sheet is set on the inserter tray 401.

Next, the internal configuration of the saddle stitch binding machine 200-c will be described with reference to FIG.
In FIG. 5, the saddle stitch bookbinding machine 200-c performs stapling, cutting, punching, Z-folding (also referred to as one-sleeve folding) processing, shift paper discharge processing, and saddle stitching on sheets from the printing apparatus 100. Various units that selectively execute processing and the like are provided. Further, the saddle stitch bookbinding machine 200-c does not have a straight path that functions as a sheet conveying function to a subsequent apparatus. For this reason, when a plurality of sheet processing apparatuses are connected to the printing apparatus 100, the saddle stitch binding machine 200-c is connected at the end as shown in FIG.

  Further, as shown in FIG. 5, the saddle stitch binding machine 200-c includes a sample tray 500 and a stack tray 501 outside the apparatus, and a booklet tray 503 inside the apparatus. When the control unit 205 executes a job instructed to be stapled by the saddle stitch bookbinding machine 200-c, the control unit 205 converts the sheet printed by the printing apparatus 100 into a processing tray inside the saddle stitch bookbinding machine 200-c. 504 is sequentially stacked. When a bundle of sheets is stacked on the processing tray 504, the control unit 205 causes the stapler 505 to perform stapling. Thereafter, the control unit 205 discharges the stapled sheet bundle from the processing tray 504 to the stack tray 501 in FIG.

Further, when executing a job instructed to perform Z folding by the saddle stitch binding machine 200-c, the control unit 205 performs Z printing on the sheet printed by the printing apparatus 100 by the Z folding unit 506. The folding process is executed in a letter shape. The control unit 205 controls the folded sheet to pass through the saddle stitch binding machine 200-c and be discharged onto a discharge tray such as the stack tray 501 and the sample tray 500.
In addition, when the control unit 205 executes a job instructed to perform punch processing setting by the saddle stitch bookbinding machine 200-c, the punch unit 507 performs punch processing on a sheet printed by the printing apparatus 100. Execute. Then, the control unit 205 controls to pass through the saddle stitch binding machine and discharge the sheets to a discharge tray such as the stack tray 501 and the sample tray 500.

In addition, when executing a job for which the saddle stitch bookbinding machine 200-c has received an instruction to perform saddle stitch binding processing, the control unit 205 causes the saddle stitcher unit 508 to execute a job from a plurality of sheets for one set. Two-point binding is performed at the central portion of the sheet bundle.
Thereafter, the control unit 205 causes the roller to bite the central portion of the sheet bundle, thereby causing the sheet to be folded in half based on the central portion of the sheet. Thereby, a booklet like a pamphlet can be created. In this manner, the sheet bundle that has been subjected to saddle stitch binding processing by the saddle stitcher unit 508 is conveyed to the booklet tray 503.

  In addition, when an instruction to perform a cutting process is received for a job that has been instructed to perform the saddle stitch bookbinding process, the control unit 205 receives the sheet bundle that has been saddle stitched from the booklet tray 503. Transport to trimmer 509. Thereafter, the control unit 205 causes the cutter unit 510 to cut the sheet bundle conveyed to the trimmer 509 and causes the booklet holding unit 511 to hold the sheet bundle. The saddle-stitch bookbinding machine in FIG. 5 is also configured to perform three-way cutting of a sheet bundle that has been saddle-stitched.

When the saddle stitch bookbinding machine 200-c does not have the trimmer 509, the sheet bundle bound by the saddle stitcher unit 508 can be taken out from the booklet tray 503.
Further, the saddle stitch bookbinding machine 200-c can attach the sheet set on the inserter tray 513 of the inserter 512 of FIG. 5 to a sheet conveyed (printed by the printing apparatus 100) from the printing apparatus 100. It is configured. The sheet set on the inserter tray 513 is, for example, a printed cover sheet in advance.
Furthermore, the saddle stitch binding machine 200-c not only processes the sheet conveyed from the upstream apparatus. For example, stapling processing, cutting processing, punching processing, Z folding processing, shift paper discharge processing, saddle stitch binding processing, and the like can be performed using a sheet fed from the paper feeding unit of the apparatus itself. However, referring to FIG. 5, the saddle stitch binding machine 200-c is configured not to have a path for transporting a sheet fed using the inserter 512 to the Z-folding unit 506. For this reason, the Z-folding process cannot be realized with a saddle stitch binding machine alone.

However, the saddle stitch binding machine 200-c is configured to be able to convey the sheet conveyed from the upstream to the Z-folding unit 506 in FIG. Therefore, a sheet can be fed using an inserter or the like provided in a sheet processing machine connected upstream, and the sheet processing can be executed by the Z-folding unit 506 in FIG. Therefore, only the sheet processing can be executed without using the printing apparatus 100.
Note that the saddle stitch bookbinding machine 200-c includes a sensor for detecting whether or not a sheet is set on the inserter tray 513 of the inserter 512, and a detection result of the presence / absence of the sheet by the sensor is not illustrated. It transmits to the control part 205 via a line. Accordingly, the control unit 205 can detect whether or not a sheet is set on the inserter tray 513.

Next, the internal configuration of a large-capacity inserter 200-d applicable to the sheet processing apparatus 200 will be described with reference to FIG.
In FIG. 6, the large capacity inserter 200-d conveys the sheet conveyed from the upstream apparatus to the downstream through the straight path 800. The large-capacity inserter 200-d feeds sheets set in each paper feed stage (paper feed deck 1, paper feed deck 2, paper feed deck 3) using the paper feed motors 802 to 804. Then, it is conveyed downstream through the straight path 800. Each of the sheet feeding deck 1, the sheet feeding deck 2, and the sheet feeding deck 3 includes a sensor for detecting whether or not a sheet exists in the sheet feeding deck, and the result detected by the sensor is used as a control unit. 205 is notified. Thereby, the control unit 205 can detect whether or not a sheet is set in each paper feed stage (paper feed deck 1, paper feed deck 2, paper feed deck 3).

An escape path 801 is a sheet conveyance path for discharging a sheet to the escape tray 805.
Next, the configuration of the operation unit 204 will be described with reference to FIG.
In FIG. 7, the operation unit 204 includes a touch panel unit 4001 and a key input unit 4002. The touch panel unit 4001 includes an LCD (Liquid Crystal Display) and a transparent electrode pasted thereon, and displays various setting screens for receiving instructions from the user.
The touch panel unit 4001 has both a function for displaying various screens and an instruction input function for receiving instructions from the user. The key input unit 4002 includes a power key 5001, a start key 5003, a stop key 5002, a user mode key 5005, and a numeric keypad 5006.

A start key 5003 is used when the printing apparatus 100 starts execution of a copy job or a transmission job. A numeric keypad 5006 is used for setting numerical input such as the number of copies to be printed. A user mode key 5005 is a key for performing various device settings.
The control unit 205 controls the printing system 1000 to perform various processes based on user instructions received via various screens displayed on the touch panel unit 4001 and user instructions received via the key input unit 4002.
The printing system 1000 as described above executes an inline job that causes the sheet processing apparatus 200 to perform post-processing on a sheet printed by the printing apparatus 100 based on an instruction from the user. Also, the printing system 1000 executes an offline job that causes the sheet processing apparatus 200 to perform post-processing on a sheet without printing by the printing apparatus 100 based on an instruction from the user.

FIG. 8 is a diagram showing an example of a user interface displayed on the touch panel unit 4001 shown in FIG. This example is a display example of a setting screen for allowing the user to select the type of sheet processing to be performed on a sheet printed by the printing apparatus 100 illustrated in FIG.
In FIG. 8, when the user presses the sheet processing setting key 609 shown in FIG. 7 on the screen displayed on the touch panel unit 4001, the control unit 205 displays the screen in FIG. 8 on the touch panel unit 4001. The screen in FIG. 8 is a setting screen configured so that the user can set the types of sheet processing that can be executed using the sheet processing apparatus 200 included in the printing system 1000. For example, the user can set to perform a stapling process 701, a punching process 702, a cutting process 703, a shift paper discharge process 704, a saddle stitch bookbinding process 705, a folding process 706, and the like. Further, the user can set to perform the gluing bookbinding process 707, the gluing bookbinding process 708, the mass stacking process 709, and the insert process 712.

  The control unit 205 receives a sheet processing setting to be executed in the job to be processed from the user via the screen of FIG. 8 and causes the sheet processing apparatus 200 to execute the sheet processing according to the setting. The settings made here are valid settings when executing an inline job. As an example of the setting procedure, first, the user sets the type of post-processing for an inline job to be executed via the setting screen. For example, the user can set the insert processing 712 to be executed as an inline job setting. The insert processing 712 refers to a sheet fed from the inserter 200-d, or from an inserter of the gluing bookbinding machine 200-b or the saddle stitch bookbinding machine 200-c at a predetermined position of the sheet printed by the printing apparatus 100. This is a process for inserting a sheet to be printed. When setting to execute the insert process 712, the user sets an insertion position of a sheet to be inserted and a paper supply source for feeding the sheet to be inserted.

  Based on the set content, the control unit 205 feeds the sheet from the set paper source to the set insertion position and inserts the sheet. As a sheet feeding source, the user can insert one of the sheet feeding deck 1, the sheet feeding deck 2 and the sheet feeding deck 3 included in the inserter 200-d, or the inserter included in the gluing bookbinding machine 200-b and the saddle stitch bookbinding machine 200-c. Can be set. The control unit 205 stores the sheet feeding source set by the user in the HDD 209 or the like, and feeds a sheet from the designated sheet feeding source when executing an offline post-processing job. For the specified type of post-processing. The sheet insertion position may be set based on the number of sheets to be printed, or may be set based on the number of pages of image data to be printed. When determining based on the number of sheets to be printed, the user sets the number of sheets to be inserted next. Further, when setting the number of pages of image data to be printed as a reference, the user sets what page the sheet is inserted next.

<Selection of type of post-processing (sheet processing)>
Next, an offline post-processing job setting screen for executing sheet processing by the sheet processing apparatus 200 without printing by the printing apparatus 100 will be described below.

FIG. 9 is a diagram showing an example of a user interface displayed on the touch panel unit 4001 shown in FIG. This example is a display example of a setting screen for allowing the user to select the type of post-processing to be executed without printing by the printing apparatus 100. Post-processing executed without printing by the printing apparatus 100 includes sheets fed from the inserter 200-d, and sheets fed from the inserter included in the gluing bookbinding machine 200-b and the saddle stitch bookbinding machine 200-c. This is post-processing executed for the sheet.
In FIG. 9, when the user presses a manual setting key 713 shown in FIG. 8 on the screen displayed on the touch panel unit 4001, the control unit 205 causes the touch panel unit 4001 to display the screen of FIG. The screen in FIG. 9 is a setting screen configured so that the user can select the type of sheet processing that can be executed as an offline post-processing job in this embodiment using the sheet processing apparatus 200 included in the printing system 1000. is there. For example, the user can set to perform stapling, punching, cutting, saddle stitching, folding, and the like. Further, the user can set to perform gluing bookbinding processing, gluing bookbinding processing, mass loading processing, and insert processing.

For example, in comparison with the display screen shown in FIG. 8, functions such as shift paper discharge and large-volume stacking that cannot be executed with this configuration cannot be selected. The reason is that a device that performs shift discharge and mass stacking processing exists upstream of the inserter 200-d, and shifts discharge and mass stacking processing of sheets fed from the inserter 200-d. This is because it cannot be conveyed to the apparatus. As described above, the control unit 205 can appropriately select the processing that can be selected in the inline job in FIG. 8 and the processing that can be selected in the offline post-processing job in FIG. It is like that.
In order to perform the display of FIGS. 8 and 9, the control unit 205 acquires the configuration of the sheet processing apparatus 200 connected to the printing apparatus 100 and stores it in a memory such as the RAM 208. Accordingly, the control unit 205 can recognize the presence / absence of each sheet processing apparatus and perform the display in FIGS. 8 and 9. Further, by storing the connection order of the sheet processing apparatus 200 together, the control unit 205 displays the unselectable processes on the screen shown in FIG. The control unit 205 may recognize the configuration and connection order of the sheet processing apparatus 200 based on a signal sent from the sheet processing apparatus 200 when the printing system 1000 is activated. Further, the control unit 205 may cause the operator to register information for specifying what type of sheet processing apparatus is connected in what connection order.

Further, when the user sets the type of post-processing to be executed in an offline job, the sheet supply source of the sheet to be subjected to the post-processing is also set. For example, the user can select one of the paper feed deck 1, the paper feed deck 2, and the paper feed deck 3 included in the inserter 200-d, or the gluing bookbinding machine 200-b and the saddle stitch bookbinding machine 200-c as a paper feed source. An inserter can be set. The control unit 205 stores the sheet feeding source set by the user in the HDD 209 or the like, and feeds a sheet from the designated sheet feeding source when executing an offline post-processing job. For the specified type of post-processing. Note that the printing system 1000 can store data of a plurality of jobs in the HDD 209. The control unit 205 reads and executes the job stored in the HDD 209 as appropriate.
With respect to the above points, these are exemplary, and any type of post-processing may be employed as post-processing that can be executed without printing. Further, as in the present embodiment, it may be configured not to be able to selectively execute all of the plurality of types of post-processing, and is not limited to this. For example, a configuration in which there is only one type of post-processing that can be executed without printing is also included in the present invention.

In this embodiment, when an offline job execution request is received from the operator, the control unit 205 passes the sheet set in the sheet feeding source to the post-processing unit in the sheet processing apparatus 200 via the printing apparatus 100 described above. Control to supply without doing anything.
Thereafter, the control unit 205 causes the processing unit to perform post-processing on the supplied sheet. In this way, the control unit 205 enables the sheet processing apparatus 200 to perform post-processing instructed by the user for the offline job without accompanying printing by the printing apparatus 100.

Note that when an offline job is executed, a sheet used in the offline job may be supplied from a paper feed cassette provided in the printing apparatus 100.
In this case, the sheet is introduced into the sheet processing apparatus 200 via the conveyance path inside the printing apparatus 100. At this time, the control unit 205 performs printing on the fed sheet by the printing apparatus 100. Control to not. In this case, since the sheet feeding source is upstream of the large-capacity stacker 200-a, it is possible to select sheet processing such as shift discharge processing and mass stacking processing on the screen shown in FIG. It may be.
When the sheet is conveyed to the above-described sheet processing apparatus 200, the control unit 205 controls the post-processing to perform post-processing instructed by the user. Such a configuration may be used.

As described above, the user can cause the printing system 1000 to execute an offline job by making an execution start request with the start key 5003 after setting the offline job via the screen shown in FIG. For example, the user can execute a bookbinding process and a stapling process on a printed sheet by using a sheet printed in advance as a sheet to be fed in an offline job.
However, after setting an offline job, an inline job stored in the HDD 209 may be executed after the user sets a sheet in a sheet feeding unit (sheet feeding deck 1) that is a sheet feeding source of the offline job. In this case, the inline job is set to perform an insert process, and the sheet feed deck 1 may be set as a sheet feed unit serving as a sheet feed source for the insert process. When such an inline job is executed, a sheet set for the offline job by the user is used for the inline job, and a printed matter not intended by the user is output.
Therefore, the present embodiment provides a mechanism for preventing a sheet set for an offline job from being used by executing an inline job when an offline job is executed.

  FIG. 10 is a flowchart illustrating an example of a control procedure in the printing apparatus 100 according to the present exemplary embodiment. In the present embodiment, the control unit 205 of the printing apparatus 100 controls the processing and operation of each step illustrated in the flowchart illustrated in FIG. 10 is stored in advance as program data in the ROM 207 of the printing apparatus 100, for example. The control unit 205 reads out and executes the data, thereby causing the printing apparatus 100 to execute various processing operations illustrated in FIG.

First, in step S91, the control unit 205 determines whether or not the sheet processing setting key 609 shown in FIG. 7 on the screen displayed on the touch panel unit 4001 has been pressed by the operator. If the control unit 205 determines that the key 609 has been pressed by the operator, the process proceeds to S92.
In step S92, the control unit 205 causes the touch panel unit 4001 to display a sheet processing setting screen illustrated in FIG.
In step S <b> 93, the control unit 205 determines whether a request for displaying a sheet processing setting screen for an offline job that performs post-processing using the sheet processing apparatus 200 without printing by the printing apparatus 100 has been received. To do. Specifically, the control unit 205 determines whether or not the manual setting key 713 shown in the screen of FIG. 8 has been pressed.

If it is determined in S93 that a request for displaying a sheet processing setting screen for an offline job has been received, the process proceeds to S94. On the other hand, if it is determined that a request for displaying an offline job setting screen has not been received, the process proceeds to S101.
In step S94, the control unit 205 causes the touch panel unit 4001 to display the screen illustrated in FIG. The user sets the sheet processing to be executed on the screen shown in FIG. Specifically, the user sets an offline job type and a paper feed unit that is the paper feed source of the offline job. Then, a sheet to be used in an offline job is set in the set sheet feeding unit, and a start key 5003 is pressed to instruct the start of the set sheet processing.
In S95, the control unit 205 monitors whether or not a start instruction has been given. If it is determined that a start instruction has been given, the process proceeds to S96. In step S <b> 96, the control unit 205 determines whether there is an incomplete inline job.
Here, an incomplete in-line job refers to a job that has already started printing processing in the printing system 1000, a job that is waiting to start printing, or the like. If the control unit 205 determines that there is no unfinished inline job, the process advances to step S98, and the control unit 205 executes desired sheet processing by each sheet processing apparatus according to the post-processing setting set by the user. Next, the printing system 1000 is controlled.

On the other hand, if the control unit 205 determines that there are unfinished inline jobs in S96, the process proceeds to S97, and the control unit 205 controls the printing system 1000 to execute the suspend processing of those jobs.
Here, the suspend process refers to a process for temporarily stopping a job. As a specific control example, the control unit 205 saves a job to be executed in a save area in a storage unit such as the HDD 209. In the meantime, the control unit 205 can execute another job. The suspended job can be resumed after the execution of the offline job is completed. Alternatively, the user may resume the job in response to an instruction to resume the inline job. Specifically, the control unit 205 controls the printing system 1000 to stop printing for jobs that are being printed using the printing apparatus 100 and not print jobs that are in a print start waiting state.
However, if the job being printed is a job in which stapling designation in the saddle stitch binding machine 200-3b, case binding designation in the glue binding machine 200-3c, and the like are set, the processing of the sheet bundle to be bound is in progress. The job cannot be interrupted. Therefore, in such a case, the control unit 205 controls the printing system to wait until the break of the sheet bundle and stop printing.

Further, while the job is suspended, the job can be received from the PC 104 or the like on the network through the external interface 202 shown in FIG.
At this time, the control unit 205 stores the job received from the PC 104 or the like on the network in the HDD (hard disk drive) 209 and controls the printing apparatus 100 to perform the compression / decompression process by the compression / decompression unit 210 as necessary. .
Then, after suspending the inline job in S97, the control unit 205 executes post-processing by the sheet processing apparatus 200 in S98 according to the post-processing setting set by the user.

  On the other hand, when the process proceeds from S93 to S101, in S101, the control unit 205 determines whether or not an inline job start instruction has been received. If an inline job start instruction is accepted, the process proceeds to S102. In step S102, the control unit 205 determines whether or not the inline job suspend process is performed. If the inline job suspend process is not performed, the control unit 205 executes the inline job in step S103. On the other hand, when the suspend process of the inline job is being performed, the control unit 205 suspends the inline job in S104 and waits for the completion of the execution of the offline job.

Next, the processing after execution of an offline job is completed will be described in detail with reference to FIG.
FIG. 11 is a flowchart illustrating an example of a control procedure in the printing apparatus 100 according to the present embodiment. In this embodiment, the control unit 205 of the printing apparatus 100 controls the processing and operation of each step exemplified in the flowchart shown in FIG. Further, a program code for causing the printing apparatus 100 to execute the processing of the flowchart in FIG. 11 is stored in advance as program data in the ROM 207 of the printing apparatus 100, for example. The control unit 205 reads out and executes the data, thereby causing the printing apparatus 100 to execute various processing operations illustrated in FIG.

After executing the offline job in S98 of FIG. 10, the control unit 205 executes the processing shown in the flowchart of FIG.
First, in steps S111 to S112, the control unit 205 continues to execute the offline job until the offline job being executed ends. If it is determined that the execution of the offline job has been completed, the control unit 205 advances the process to S113.
In step S <b> 114, the control unit 205 determines whether a sheet is set in the sheet feeding unit (here, the sheet feeding deck 2 of the inserter 200-d) designated as the sheet feeding source of the offline job. Judgment is made from the output state of the sensor of the paper deck 2. If it is determined that the sheet is set in the sheet feeding deck 2, the control unit 205 continues to limit the execution of the inline job. This is because there is a possibility that the user is going to execute another offline job using the sheet set in the sheet feeding deck 2. Therefore, the control unit 205 returns to S111 in order to wait for the execution of another offline job to end. In this case, in step S111, the control unit 205 controls to execute another offline job after waiting for an instruction to start execution of another offline job. As described above, while a sheet is detected in the paper feed deck 2 that is a paper feed source set as the paper feed source of the offline job, execution of the inline job is restricted.

On the other hand, if the control unit 205 determines in S113 that there is no paper in the inserter 200-d, the process proceeds to S114. In step S114, the control unit 205 determines whether there is a suspended inline job. Whether or not there is a suspended inline job is held in a table managed by the control unit 205 on the RAM 208.
If the control unit 205 determines that there is a suspended inline job, the process advances to step S116, and the control unit 205 controls the inline job to be instructed to be resumed. On the other hand, if the control unit 205 determines in S115 that there is no suspended inline job, the process ends.

By performing such an operation, it is possible to prevent the paper set in the post-processing apparatus for the offline job from being erroneously used in the inline job.
In the above-described embodiment, when there is an incomplete inline job in S96, the case where the inline job is suspended in S97 has been described. However, if the inline job is not set to execute processing for inserting a sheet, the sheet set for the offline job is not used for the inline job. For this reason, for example, the control unit 205 first determines whether or not an inline job set to execute the insert process exists in the inline jobs stored in the HDD 209.

  Then, the control unit 205 controls to suspend the inline job when it is set to execute the insert process, and to allow the execution of the inline job when it is not set to execute the insert process. To do. Accordingly, an inline job that does not execute the insert process can be executed without being suspended in the middle of the print process, for example. Then, the control unit 205 executes the offline job after the execution of the inline job is completed. If there are a plurality of inline jobs that do not execute the insert process, the control unit 205 may execute the offline job after executing the insert process.

  If the paper source set to be used for inline job insert processing is different from the paper source set to be used for offline job insert processing, inline jobs may be executed. . Therefore, the control unit 205 may control as follows. If the control unit 205 is set to execute the insert process in the inline job stored in the HDD 209, the control unit 205 determines the sheet supply source of the sheet to be inserted by the insert process of the inline job. Then, the control unit 205 suspends the inline job that is set to use the same sheet feeding unit as the sheet feeding unit that is set to be used in the insert processing of the offline job. On the other hand, the control unit 205 executes an inline job that is set to use a paper feeding unit that is different from the paper feeding unit that is set to be used in the offline job insertion process. With such control, when a sheet used in an offline job insert process is not used in an inline job, the inline job can be executed without being suspended.

In the above-described embodiment, the case where FIGS. 8 and 9 are displayed on the operation unit 204 of the printing system 1000 has been described. However, the present invention is not limited to this, and the present invention can also be applied to a case where an instruction from a user is received via the operation unit of the PC 103 by being displayed on the display of the PC 103. In this case, the PC 103 transmits the print setting, the image data, and the inline job to the printing system 1000 based on the instruction received from the user, and executes the print setting. Alternatively, the print setting is transmitted to the printing system 1000 as an offline job and executed.
The object of the present invention can also be achieved by executing the following processing. That is, a storage medium that records a program code of software that realizes the functions of the above-described embodiments is supplied to a system or apparatus, and a computer (or CPU, MPU, etc.) of the system or apparatus is stored in the storage medium. This is the process of reading the code. In this case, the program code itself read from the storage medium realizes the functions of the above-described embodiments, and the program code and the storage medium storing the program code constitute the present invention.

100, 101 printing device
108 Walnut Binding Machine 110 Saddle Stitch Binding Machine

  The present invention relates to a printing system, a printing method, and a program.

  The object of the present invention is to restrict the execution of the printing process by the printing unit when the binding process is performed on a sheet that has not been subjected to the printing process by the printing unit, and is accepted while the limitation is being made. It is to provide a mechanism that can execute a printing process based on the requested request at an appropriate timing.

  The printing system of the present invention that achieves the above object includes: a receiving unit that receives a request for a printing process; a printing unit that performs an image printing process on a sheet based on the request received by the receiving unit; and a printing process performed by the printing unit A binding process capable of executing a binding process on a sheet that has been subjected to printing, a binding process that is performed on a sheet that has not been printed by the printing unit, and a binding process that is performed on a sheet that has not been printed by the printing unit. A restriction unit that restricts execution of the printing process by the printing unit when executed, and the printing unit receives the request while the restriction unit is restricted, Executing a binding process for a sheet that has not been subjected to a printing process by the printing unit, based on the received request And to execute after completing.

  According to the present invention, when a binding process is performed on a sheet that has not been subjected to a printing process by the printing unit, the execution of the printing process by the printing unit is restricted and accepted while the restriction is being made. The printing process based on the request can be executed at an appropriate timing.

Claims (1)

A printing apparatus prints an image on a sheet, conveys the sheet to a sheet processing apparatus, and the sheet processing apparatus executes sheet processing on the sheet, and the printing apparatus prints an image on the sheet. Execution means for executing a second type job for executing sheet processing on a sheet by the sheet processing apparatus without printing;
The execution of the first type job is restricted in accordance with the reception of the request for executing the second type job, and the execution of the first type job is restricted in the state where the execution of the first type job is restricted. Control means for controlling to execute
Accepting means for accepting the first type job while execution of the first type job is restricted by the control means;
Storing means for storing the first type job received by the receiving means;
The printing apparatus controls the execution of the first type job stored in the storage unit after the execution of the second type job is completed.

Images