The entire disclosure of Japanese patent Application No. 2017-245083, filed on Dec. 21, 2017, is incorporated herein by reference in its entirety.
The present invention relates to a post-processing apparatus, an image forming system, and a control program for the post-processing apparatus.
There are known post-processing apparatuses capable of performing a plurality pieces of post-processing solo by switching a plurality of functional units that perform post-processing such as cutting papers, forming creasing and perforation.
JP 2005-239308 A discloses a paper processing apparatus that performs processing on a paper while conveying the paper, the apparatus including an optional processing device that performs processing of optionally selected contents as a functional unit, in which the optional processing device is provided freely attachably to and detachably from the main body of the apparatus. Moreover, JP 2005-239312 A discloses a paper processing apparatus having a cutting device and a creasing forming device as functional units, in which the cutting device and the creasing forming device are provided freely attachably to and detachably from the main body of the apparatus.
In the paper processing apparatus of JP 2005-239312 A, the cutting device and the creasing forming device are arranged in series along a conveyance path to allow these pieces of processing to be sequentially performed. In this manner, by increasing the number of functional units to be loaded in a post-processing apparatus and combining the units, more complex post-processing functions can be implemented.
However, as the number of functional units increases and combinations become complicated, there are cases where post-processing cannot be performed depending on the paper size even when the same post-processing is performed. A user of the post-processing apparatus deals with such a case by switching the functional units.
Particularly, since in post-processing into a direction orthogonal to a paper conveyance direction (hereinafter referred to as “cross direction (CD)”), it is necessary to temporarily stop the paper conveyance, there are constraints such as that a paper is pulled by a post-processing apparatus connected in a later stage. As a result, post-processing may not be performed accurately in some cases. In order to avoid such constraints, the user switches functional units.
However, there is a problem that it is difficult for a user to confirm, at the time of switching the functional units, whether desired post-processing can be performed by the current combination of functional units.
There is also another problem that it is difficult for the user to grasp all of the constraints or prohibition conditions since constraints or prohibition conditions of post-processing functions differ depending on a loading position even with the same functional units.
The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a post-processing apparatus that presents whether post-processing desired by a user can be performed, an image forming system, and a control program of the post-processing apparatus.
To achieve the abovementioned object, according to an aspect of the present invention, a post-processing apparatus that performs, by one or more functional units which can be switched one another, predetermined post-processing corresponding to a function of the one or more functional units on a conveyed paper, reflecting one aspect of the present invention comprises: a plurality of slots in which the one or more functional units can be loaded at respective loading positions along a conveyance path; a loading detector that detects that the one or more functional units are loaded in the slots; and a condition output part that outputs a condition that allows the post-processing depending on the loading positions of the slots in which the one or more functional units are loaded.
The advantages and features provided by one or more embodiments of the invention will become more fully understood from the detailed description given hereinbelow and the appended drawings which are given by way of illustration only, and thus are not intended as a definition of the limits of the present invention:
Hereinafter, one or more embodiments of the present invention will be described with reference to the drawings. However, the scope of the invention is not limited to the disclosed embodiments. Note that in the description of the drawings, the same elements are denoted by the same symbol, and redundant descriptions are omitted. Dimension ratios of the drawings are exaggerated for convenience of explanation and may be different from the actual ratios.
<Image Forming System 100>
As illustrated in
<Image Forming Apparatus 200>
The image forming apparatus 200 reads an image from a document and forms (prints) the read image on a paper. Alternatively, the image forming apparatus 200 receives a print job including print data in the page description language (PDL) format and print setting data from an external client terminal through a network, and forms an image on a paper on the basis of the print job. The client terminal may be, for example, a personal computer, a tablet terminal, a smartphone, or the like.
As illustrated in
The image reader 210 includes an optical system including a mirror, a lens, and the like, and a reading sensor. The image reader 210 reads a document placed on a reading surface or a document conveyed by an auto document feeder (ADF) and outputs image signals.
The image processor 220 performs various types of image processing on an image signal received from the image reader 210 to generate print image data. The image processor 220 further generates print image data on the basis of print setting information and print data included in the print job received by the communicator 270. The generated print image data is transmitted to the image former 230.
The image former 230 forms an image on a paper on the basis of the print image data by using a known image forming process such as an electrophotographic method including charging, exposure, development, and transfer steps.
The image former 230 includes a photoreceptor drum as an image carrying member and a charger, an optical writer, a developing device, and a transferor arranged around the photoreceptor drum.
The photoreceptor drum is caused to rotate at a predetermined speed by a drum motor (not illustrated). The charger includes a corona discharger arranged around the photoreceptor drum and charges the surface of the photoreceptor drum by ions generated thereby. The optical writer incorporates a scanning optical device. The optical writer exposes the charged photoreceptor drum on the basis of input printing image data to reduce the charge in the exposed part and thereby forms a charge pattern (electrostatic latent image) corresponding to the printing image data. The developing device develops the formed electrostatic latent image, visualizes the image by toner, and forms a toner image. The transferor transfers the toner image on the photoreceptor drum onto a paper.
The paper feeder 240 supplies papers as a recording material to the image former 230. The paper feeder 240 includes an upper tray 241 and a lower tray 242. Papers of different sizes such as A4 size and A3 size can be accommodated in each of the trays.
The paper conveyor 250 conveys papers in the image forming apparatus 200. The paper conveyor 250 has a conveyance path and a plurality of pairs of conveyance rollers. The paper conveyor 250 also includes a paper reverser and a circulating conveyor and thus is capable of ejecting a paper after reversing the front and back sides of the paper after fixation or forming images on both sides of a paper.
The paper supplied from the paper feeder 240 is conveyed on the conveyance path toward the image former 230. At a pair of resist rollers 251, a timing at which the paper is conveyed to the transferor is controlled through synchronization with the toner image formed on the photoreceptor drum. The paper on which the toner image has been transferred by the transferor is conveyed to the fixer 260.
The fixer 260 fixes the toner image formed on the paper. The fixer 260 includes a hollow heating roller inside which a heater is arranged and a pressure roller facing the heating roller. The heating roller and the pressure roller are controlled at a predetermined temperature (for example, 100° C. or higher) by the heater to apply heating and pressing processing to the paper to fix the toner image.
The paper on which the image is fixed is supplied to the first post-processing apparatus 300 through a paper ejector (not illustrated).
The communicator 270 has a network I/F 271 and a post-processing apparatus I/F 272. The network I/F 271 is connected to a client terminal such as a personal computer via a network to transmit or receive data such as a print job.
The post-processing apparatus I/F 272 is communicably connected to the first post-processing apparatus 300 and the second post-processing apparatus 400 via a communication line 202 to transmit or receive data.
The operation display 280 has an input part and an output part. The input part includes, for example, a keyboard and a touch panel, and is used for a user to perform various instructions (input) such as inputting characters, various settings, and start instruction. The output part includes a display and is used for presentation, to a user, of a configuration of the apparatus, an execution status of a print job, conditions that allow post-processing, a picture of an output image, occurrence of abnormality (paper jam) in paper conveyance, etc.
The controller 290 controls the image reader 210, the image processor 220, the image former 230, the paper feeder 240, the paper conveyor 250, the fixer 260, the communicator 270, and the operation display 280. The controller 290 includes a CPU 291, an auxiliary storage device 292, a RAM 293, and a ROM 294.
The CPU 291 executes a control program for the image forming apparatus. The control program is stored in the auxiliary storage device 292 and is loaded to the RAM 293 when executed by the CPU 291. The auxiliary storage device 292 includes a large-capacity storage device such as a hard disk drive and a flash memory. In the RAM 293, calculation results accompanying execution of the CPU 291, the position and type of functional units loaded in the first post-processing apparatus 300, prohibition condition information which will be described later, etc. are stored. In the ROM 294, various parameters, various programs, and the like are stored. The CPU 291 executes the control program to implement various functions.
<First Post-Processing Apparatus 300>
The first post-processing apparatus 300 conveys or post-processes the paper supplied from the image forming apparatus 200 in accordance with an instruction from the image forming apparatus 200 and supplies the paper to the second post-processing apparatus 400 or ejects to a purge tray 340.
The first post-processing apparatus 300 is arranged between the image forming apparatus 200 and the second post-processing apparatus 400 in the image forming system 100 and includes a paper conveyor 310, a post-processor 320, a trash box 330, the purge tray 340, a communication I/F 350, and a controller 360. These components are connected by an internal bus 301 so as to allow communication thereamong.
As illustrated in
The paper conveyor 310 further has a long paper conveyor 315 and a purge conveyor 316. The long paper conveyor 315 conveys a long paper supplied from the image forming apparatus 200 while aligning the paper. More specifically, the long paper conveyor 315 temporarily holds the long paper supplied from the image forming apparatus 200 in the conveyance path 312 and aligns the paper in terms of inclination with respect to the conveyance direction (adjust to correct orientation) before conveyance to the post-processor 320. The purge conveyor 316 conveys the paper from the post-processor 320 to the purge tray 340. Note that although illustration is simplified, the purge conveyor 316 may include a number of pairs of conveyance rollers 314 along the conveyance path 313 such that papers cut into a card size or a business card size in the post-processor 320 can be reliably conveyed.
The post-processor 320 performs post-processing on a paper by one or more functional units. The post-processor 320 has a plurality of slots 321 to 324 for loading functional units. The slots 321 to 324 each have a slot number (#1 to #4). Functional units are loaded at respective loading positions along the conveyance path. A loading position is defined by the position on the conveyance path (position in the X direction). In
Furthermore, detection sensors 325 to 328 are installed in the slots 321 to 324, respectively. In cooperation with the controller 360, the detection sensors 325 to 328 determine whether each of the functional units 501 to 504 is installed and in the case where a functional unit is loaded in any of the slots 321 to 324, the type of the functional unit and whether loaded, that is, information of the loading position are acquired. The detection sensors 325 to 328 and the controller 360 function as loading detectors and type detectors.
The detection sensors 325 to 328 may be of any form as long as the detection sensor can detect whether a functional unit is loaded and the type of the functional unit. For example, a light sensor, an actuator, or the like may be used. Alternatively, a connector in the main body of the first post-processing apparatus 300 and a connector of a functional unit may be fitted and electrically connected to allow the controller 290 to detect whether loaded and to read an identification number stored in a control board of the functional unit after the connection, thereby allowing the type of the functional unit to be detected (determined).
The functional units 501 to 504 may be any one of, for example, a CD cutting unit, a top/bottom slit (FD cutting) unit, a margin cutting slit unit, a crease unit, a CD sewing machine unit, an FD sewing machine unit, and a business card slit unit.
The CD cutting unit is a unit that cuts a paper in the CD direction. The top/bottom slit is a unit that cuts a paper in the paper conveyance direction and is also called a feed direction (FD) cutting unit. Hereinafter, the paper conveyance direction is also referred to as the “FD direction”.
The margin cutting slit unit is a unit that forms a slit in the FD direction. For example, in the margin cutting slit processing, cutting is performed with two parallel cutting lines with a slit (groove) formed between the two cutting lines. The crease unit is a unit that forms a streak in a predetermined direction, for example, the CD direction.
The CD sewing machine unit is a unit that forms a perforation in the CD direction, and the FD sewing machine unit is a unit that forms a perforation in the FD direction. The business card slit unit is a unit that forms a plurality of slits in the FD direction in order to cut a paper into the size of a business card.
Note that the post-processor 320 may also use a functional unit other than the above. The cutting waste cut by functional units involved in cutting of papers falls to the trash box 330 by its own weight and accumulates. A user periodically discards the cutting waste in the trash box.
The communication I/F 350 is communicably connected to the post-processing apparatus I/F 272 of the image forming apparatus 200 via the communication line 202 to transmit or receive data.
The controller 360 controls the paper conveyor 310, the post-processor 320, and the communication I/F 350. The controller 360 includes a CPU 361, a RAM 362, and a ROM 363.
The CPU 361 executes a control program for the first post-processing apparatus and implements various functions. The RAM 362 stores calculation results or processing results of the CPU 361, the position and type of functional units loaded in the post-processor 320, prohibition condition information which will be described later, etc. The ROM 363 stores the control program, various parameters including loading positions (positions in the conveyance path) corresponding the slots (or slot numbers), and other data.
The controller 360 acquires the type of functional units and the loading position on the basis of detection results of the detection sensors 325 to 328. For example, a unit number unique to each type of all functional units that can be loaded in the slots 321 to 324 may be allocated in advance. The unit number can be acquired as information of the type of the loaded functional unit. The correspondence between unit numbers and the type of functional units can be stored in the RAM 362 as a table.
When the correspondence is denoted as “name of functional unit (unit number),” unit numbers are allocated in a manner such as CD cutting (1), FD slit (2), margin cutting slit (3), crease (4), CD sewing machine (5), FD sewing machine (6), business card slit (7), and dummy (8).
Alternatively, an identification number unique to every functional unit that can be loaded in the slots 321 to 324 may be allocated in advance, and the identification number can be acquired as information of the type of the loaded functional unit. The correspondence between identification numbers and the type of functional units can be stored in the RAM 362 as a table.
Furthermore, as information of loading positions, for example slots #1 to #4 may be used. The slots #1 to #4 correspond to the slots 321 to 324, respectively. The slots 321 to 324 are arranged in the order of the slots 321, 322, 323, and 324 from the side close to the image forming apparatus 200, and distances from a predetermined reference position in the conveyance path to each of the slots 321 to 324 are defined in advance, which are stored in the ROM 363. Therefore, by specifying one of the slots #1 to #4, a loading position is uniquely determined.
The controller 360 functions as a condition output part and derives conditions that allow post-processing by the post-processor 320 depending on loading positions of functional units detected by the detection sensors 325 to 328. Details of conditions that allow post-processing will be described later.
<Second Post-Processing Apparatus 400>
The second post-processing apparatus 400 conveys or post-processes a paper supplied from the first post-processing apparatus 300 in accordance with an instruction from the image forming apparatus 200 and ejects the paper to the outside of the image forming system 100. The second post-processing apparatus 400 is arranged most downstream in the image forming system 100 and includes an insertion paper feeder 410, a paper conveyor 420, a stitch binder 430, a main tray 440, a purge tray 450, a communication I/F 460, and a controller 470. These components are connected by an internal bus 401 so as to allow communication thereamong.
The insertion paper feeder 410 includes one or more paper feed trays. In the paper feed trays of the insertion paper feeder 410, for example, pre-printed papers, colored papers, etc. are loaded and used as, for example, a front cover of a printed bundle or an insertion paper for dividing chapters. Papers placed in the paper feed trays are fed at a predetermined timing on the basis of the print setting information.
The paper conveyor 420 includes a conveyance path 421 and a plurality of pairs of conveyance rollers 422 and conveys the paper supplied from the first post-processing apparatus 300 along the conveyance path 421. The paper conveyor 420 also conveys a paper supplied from the first post-processing apparatus 300 or the insertion paper feeder 410 along the conveyance path 421. The paper conveyor 420 also conveys a booklet side-stitched by the stitch binder 430 to the main tray 440.
The stitch binder 430 includes a stacker that accumulates papers and a stapler that staples a bundle of papers. The stitch binder 430 staples an end of a bundle of papers to side-stitch the bundle of papers to produce a booklet.
The main tray 440 ejects valid papers out of the papers conveyed by the paper conveyor 420. The purge tray 450 ejects invalid paper out of the papers conveyed by the paper conveyor 420.
The communication I/F 460 is communicably connected to the post-processing apparatus I/F 272 of the image forming apparatus 200 via the communication line 202 to transmit or receive data.
The controller 470 controls the insertion paper feeder 410, the paper conveyor 420, the stitch binder 430, the main tray 440, the purge tray 450, and the communication I/F 460. The controller 470 includes a CPU 471, a RAM 472, and a ROM 473.
The CPU 471 executes a control program for the second post-processing apparatus and implements various functions. The RAM 472 stores calculation results, processing results, and other data of the CPU 471. The ROM 473 stores the control program, various parameters, and other data.
<Control Method of Image Forming System 100>
With reference to
As illustrated in
If it is determined that no functional unit is loaded in any of the slots 321 to 324 (step S101: NO), the flow stands by until it is determined that a functional unit is loaded in any one of the slots 321 to 324 (step S101: NO).
On the other hand, when it is determined that a functional unit is loaded in any one of the slots 321 to 324 (step S101: YES), information of the loading position of the functional unit is acquired (step S102). In the example illustrated in
Subsequently, information of the type of the functional units is acquired (step S103). The controller 360 acquires information of the type of the functional units 501 to 504 on the basis of the detection results of the detection sensors 325 to 328. For example, the controller 360 acquires unit numbers 1, 2, 8, and 8 as the information of the type of the functional units 501 to 504, respectively. That is, the functional units 501 to 504 correspond to CD cutting (1), FD slit (2), dummy (8), and dummy (8), respectively.
Subsequently, conditions that allow post-processing are output (step S104). The controller 360 outputs conditions that allow post-processing by the post-processor 320 depending on the type and the loading position of the functional units 501 to 504. More specifically, it is as follows.
<Output of Conditions that Allow Post-Processing (Step S104)>
As illustrated in
As illustrated in
In the case where the functional unit 501 of the slot 321 performs post-processing, if the position where the post-processing is performed is within the distance D1 from the top of the paper, the paper is not pulled by the second post-processing apparatus 400 while the functional unit 501 is performing the post-processing. Moreover, in the case where the functional unit 504 of the slot 324 performs post-processing, if the position where the post-processing is performed is within the distance D4 from the top of the paper, the paper is not pulled by the second post-processing apparatus 400 while the functional unit 504 is performing the post-processing.
In the following description, the case where the distances D1 to D4 are set to 500, 370, 240, and 110 mm, respectively, will be illustrated for the sake of convenience. Furthermore, the example where the functional unit of the slot 321 is capable of post-processing a paper having a length of up to 490 mm is illustrated. However, the values of the distances D1 to D4 and paper sizes that can be post-processed are not limited to above cases.
The controller 360 determines whether a constraint is posed by the loading positions of the functional units. More specifically, the controller 360 determines whether constraints are posed on the basis of the types and loading positions of the functional units 501 to 504 loaded in the slots 321 to 324.
In the example illustrated in
If no constraint is posed by loading positions of functional units (step S201: NO), the controller 360 outputs conditions that allow post-processing (step S202). As illustrated in
Moreover, the controller 360 outputs, as a picture of an output image, a representative example of post-processing that can be performed with the above arrangement of the functional units as illustrated in
The paper 601 after the cutting processing is either conveyed to the second post-processing apparatus 400 or conveyed to the purge tray 340 and ejected. Then, the controller 360 terminates the processing of outputting conditions that allow post-processing (return).
Next, cases where a constraint is posed by loading positions of functional units which will be explained.
Referring back to
For example, a case is assumed where the CD cutting unit, the crease unit, the FD slit unit, and the dummy unit are loaded in the slots 321 to 324, respectively, as functional units.
Since the crease unit performs processing for forming a streak in the CD direction on the paper, there is a possibility that a constraint is posed depending on a position at which the processing is performed. In the above arrangement of the functional units, since the crease unit is loaded in the slot 322, the crease processing can be performed within a range of positions up to 360 mm from the top of the paper in the present embodiment, for example. That is, when the crease unit is loaded in the slot 322, this results in a constraint that a range that can be post-processed is limited to positions up to 360 mm from the top of the paper.
Next, conditions that allow post-processing and prohibition information are output (step S204). As illustrated in
The controller 360 further sets 360 mm as a prohibition condition due to constraints on the crease unit. Then, as illustrated in
Moreover, the controller 360 outputs, as a picture of an output image, a representative example of post-processing that can be performed with the above arrangement of the functional units as illustrated in
<Another Example where Constraint is Posed Due to Loading Positions of Functional Units>
For example, a case is assumed where the FD slit unit, the dummy unit, the margin cutting slit unit, and the CD cutting unit are loaded in the slots 321 to 324, respectively, as functional units.
Out of the above, a functional unit that performs post-processing in the CD direction is only the CD cutting unit. The CD cutting unit is loaded in the slot 324 and can perform CD cutting at any position in the FD direction as long as the position is within a range of 100 mm from the top of the paper. However, in a case where the position exceeds 100 mm from the top of the paper, there is a possibility that the paper is pulled by the second post-processing apparatus 400 while the CD cutting unit is performing cutting processing. Therefore, in the case where the CD cutting unit is loaded in the slot 324, a constraint is posed that the range in which post-processing can be performed is limited to positions up to 100 mm from the top of the paper.
As illustrated in
The controller 360 further sets 100 mm as a prohibition condition due to constraints on the CD cutting unit. Then, as illustrated in
Moreover, the controller 360 outputs, as a picture of an output image, a representative example of post-processing that can be performed with the above arrangement of the functional units as illustrated in
<Relaxation of Prohibition Conditions by Switching of Functional Units>
Again referring back to
If the constraint is not relaxed by switching of the functional units (step S205: NO), the controller 360 terminates the processing (return).
On the other hand, if the prohibition condition is relaxed by switching of the functional units (step S205: YES), the controller 360 outputs conditions that allow post-processing in the case where the prohibition condition is relaxed (step S206). More specifically, if switching of the positions of the FD slit unit, the dummy unit, the other dummy unit, and the CD cutting unit loaded in the slots #1 to #4 relaxes the prohibition condition, the controller 360 recommends a user the order of arrangement in which the prohibition condition is relaxed. For example, the controller 360 presents orders of arrangement of the functional units as illustrated in
As illustrated in
Moreover, as illustrated in
Moreover, as illustrated in
As described above, in the present embodiment, the controller 360 can present a better condition to the user with a less restrictive prohibition condition even with a combination of the same functional units (for example, the FD slit unit, the dummy unit, the other dummy unit, the CD cutting unit).
<List of Combinations of Functional Units>
Combinations of functional units will be described with reference to
In
Post-processes may include an FS main tray (eject to the main tray after processing by the post-processing apparatus), an LS main tray (eject to the main tray after processing by a large stacker), an SD book body (saddle stitch binding), and a PB book body (case binding). Output matters may include a sheet, a flyer, an advertisement, and a banner.
As indicated in “No. 2,” it is possible to perform processing for cutting a paper in the CD direction a plurality of times by the CD cutting unit with the same combination of functional units as the above “No. 1.” In the table an example is illustrated where an A3-sized paper is divided into two sheets of A4 paper.
Post-processes may include trimer unit (TU) purge (eject to the purge tray 340), the FS main tray, the LS main tray, and the PB book body. Like in “No. 1,” output matters may include a sheet, a flyer, an advertisement, and a banner.
The combination of functional units indicated in “No. 3” is the same as the combination of the functional units illustrated in
Post-processes may include a PB cover (produce a cover by case binding), an SD cover (produce a cover by saddle stitch binding), SD folding (folding by saddle stitch binding), and long length creasing (for folding). Output matters may include a banner, a book cover, a leaflet, a catalog, a pamphlet, a photo album, and a booklet.
As illustrated in “No. 4,” in the case where functional units of FD slit, crease, margin cutting slit, and CD cutting are loaded in the slots #1 to #4, typical examples of post-processing may be four-side cutting processing and crease processing.
A post-process may be TU purge (eject to the purge tray 340). Output matters may include folded cards (shopping card, greeting card, stamp card, invitation card, etc.).
Note that although the ejection destination may be the purge tray 340, conveyance to the downstream second post-processing apparatus 400 is not possible since the paper is divided into a plurality of sheets in the FD direction by the margin cutting slit processing.
Subsequently, in
The combination of functional units indicated in “No. 6” is obtained by replacing the margin cutting slit unit in “No. 5” with a business card slit unit. Post-processes may include the TU purge or a dedicated stacker, and output matters may include business cards and cards.
In “No. 7” and “No. 8,” functional units of FD slit, CD sewing machine, FD sewing machine, and CD cutting are loaded in the slots #1 to #4, respectively. In the case of “No. 7,” typical examples of post-processing may be four-side cutting processing and sewing processing. Furthermore, in the case of “No. 8,” typical examples of post-processing may be multiple cutting processing and sewing processing. Note that, in “No. 7” and “No. 8,” a broken line indicates sewing processing by the CD sewing machine or the FD sewing machine. A post-process may be the TU purge, and output matters may include tickets, coupons, etc.
Note that samples such as photographs of output matters may be displayed in the lists of
<Exemplary Output of Post-Processed Paper>
Next, exemplary output of a paper post-processed by the first post-processing apparatus 300 will be described.
<First Variation>
As illustrated in
As illustrated in
Alternatively, instead of adding the texts 604 to the cutting positions of the paper 600, color frames 605 may be provided at the cutting positions as illustrated in
In this manner, since a picture of an output image including an identifier (text 604 or color frame 605) indicating a position at which a functional unit performs post-processing is printed in the first variation, a user can easily confirm that post-processing is appropriately performed on the paper that is actually output.
<Second Variation>
As illustrated in
In this manner, since in the second variation an image is printed on adjacent regions surrounding the picture of the output image of the paper having been performed with cutting processing by the post-processor 320, the user can easily confirm that cutting processing is appropriately performed on the paper that is actually output.
The first post-processing apparatus 300 and the image forming system 100 of the present embodiment described above have the following effects.
Since the first post-processing apparatus 300 outputs conditions that allow post-processing depending on loading positions of functional units in the first post-processing apparatus 300, a user can easily determine whether desired post-processing can be performed.
<Third Variation>
The first post-processing apparatus 300 further includes the display 329. The display 329 functions as a condition output part together with a controller 360 and displays conditions that allow post-processing by the post-processor 320 depending on loading positions of functional units of the post-processor 320.
The embodiments have been described as the above. However, it is understood without mentioning that those skilled in the art can add, modify, and omit an embodiment of the present invention as appropriate within the scope of the technical idea of the present invention.
For example in the embodiment described above, the case has been described where the controller 360 of the first post-processing apparatus 300 derives conditions that allow post-processing by the post-processor 320 depending on loading positions of functional units detected by the detection sensors 325 to 328. However, the present invention is not limited to such a case, and the controller 290 of the image forming apparatus 200 may derive conditions that allow post-processing by the post-processor 320 depending on loading positions of functional units detected by the detection sensors 325 to 328.
Moreover, in the embodiment described above, the case where a paper being post-processed in the first post-processing apparatus 300 is pulled by the second post-processing apparatus 400 connected in a later stage has been described as the constraint for example; however, the present invention can also be applied to other constraints. Furthermore, the present invention can be applied not only to constraints related to the CD direction but also to constraints related to the FD direction.
Meanwhile, the control programs of the image forming apparatus, the first and second post-processing apparatuses may be provided by a computer readable recording medium such as a USB memory, a flexible disk, and a CD-ROM or may be provided online via a network such as the Internet. In this case, the program recorded in the computer-readable recording medium is usually transferred to and stored in a storage, a storage device, or the like. This control program may be provided as independent application software, for example, or may be incorporated into software of each device as one function of the image forming apparatus.
Although embodiments of the present invention have been described and illustrated in detail, the disclosed embodiments are made for purposes of illustration and example only and not limitation. The scope of the present invention should be interpreted by terms of the appended claims.
Number | Date | Country | Kind |
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2017-245083 | Dec 2017 | JP | national |
Number | Name | Date | Kind |
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7419149 | Oota | Sep 2008 | B2 |
7832318 | Oota | Nov 2010 | B2 |
10273109 | Oguri | Apr 2019 | B2 |
20030035143 | Glemser | Feb 2003 | A1 |
20030036468 | Blank | Feb 2003 | A1 |
Number | Date | Country |
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2005239308 | Sep 2005 | JP |
2005239312 | Sep 2005 | JP |
Number | Date | Country | |
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20190193980 A1 | Jun 2019 | US |