EP2623451B1

EP2623451B1 - Bookbinding system

Info

Publication number: EP2623451B1
Application number: EP13153442.2A
Authority: EP
Inventors: Kouichiro c/o RISO KAGAKU CORPORATION R&D Center Iida; Atsushi c/o RISO KAGAKU CORPORATION / R&D Center Hiroshima
Original assignee: Riso Kagaku Corp
Current assignee: Riso Kagaku Corp
Priority date: 2012-01-31
Filing date: 2013-01-31
Publication date: 2018-10-31
Anticipated expiration: 2033-01-31
Also published as: JP5860708B2; EP2623451A2; JP2013155033A; EP2623451A3

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a bookbinding system configured to align sheets to perform bookbinding.

2. Description of the Related Art

There are bookbinding systems widely used having a so-called case binding device which applies paste to a spine side (back side) of a sheaf of sheets formed by bundling text sheets using a paste application roller, and wraps the sheaf of sheets with a cover sheet from the spine side (e.g., Japanese Patent Application Laid-Open Publication No. 2009-29562 ).
Such a bookbinding system usually allows a manual-feed sheet (e.g., pre-folded sheet) to be inserted through a manual insertion slot.
Such a bookbinding system has an aligner configured to align the text sheets conveyed by the bookbinding system and the manual-feed sheet inserted through the manual insertion slot. Typically, the sheets are placed on an alignment tray included in the aligner to be aligned. Then, edges of the bound book except for the spine side are cut off, which forms it into a finished book with a prescribe size.
Meanwhile, when placing a manual-feed sheet on the alignment tray, a user places it so that it butts against a predetermined position of the alignment tray. In addition, when placing on the alignment tray, a manual-feed sheet whose total length in the alignment direction is shorter than the text sheets, the user places the sheet so that a rotating paddle provided above the sheet causes the sheet to butt against the predetermined position.
Accordingly, misalignment caused by inaccurate alignment due to manual handling by the user or operation error may easily occur. When the edge of the manual-feed sheet protrudes from the predetermined position due to the misalignment, if the manual-feed sheet is a pre-folded sheet, the folded part will be cut off, which may result in a defective product.
As another example, US 2011/031677 A1 is disclosed. The application discloses a stapling apparatus which includes a processing tray; a paper discharge unit configured to discharge sheets on the processing tray; an aligning unit configured to align sheets manually inserted onto the processing tray from a paper discharge port of the paper discharge unit; and a stapler configured to staple the sheets manually inserted on the processing tray. US 2011/031677 A1 discloses a binding system according to the preamble of claim 1. US 2011/031677 A1 does not disclose a bookbinding system.

SUMMARY OF THE INVENTION

It is an object of the present invention, which has been made in view of the problem described above, to provide a bookbinding system such that, when the side edges of the bound book are cut off to finish the book, the folded part of the pre-folded sheet bound in the bound book will not be cut off.
In order to achieve the object described above, according to a first aspect of the present invention, there is provided a bookbinding system as defined in claim 1.
According to a second aspect of the present invention, there is provided a bookbinding system as defined in claim 2.
According to the first aspect of the present invention, the alignment procedure in the aligner is switched when the length of pre-folded sheet in the conveyance direction is shorter than the prescribed length from the spine side to the page opening side of the text sheets in the bound book after the side edges of the text sheets have been cut off. Therefore, a bookbinding system can be provided which prevents the folded part of pre-folded sheet bound in the book from being cut off, when cutting the edges of the bound book after binding.
According to the second aspect of the present invention, moving the front end member and the rear end member allows the front end positions in the conveyance direction of the text sheets and the pre-folded sheet to be aligned. Therefore, a bookbinding system which prevents the folded part of pre-folded sheet from being cut off can be provided by a simple mechanism without using a special device or performing a special operation procedure.
According to the first aspect of the present invention, a bookbinding system can be provided which reliably prevents the pre-folded sheet from being cut off.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic overall configuration diagram of a bookbinding system of an embodiment of the present invention.
FIG. 2 is a configuration diagram of a sheet conveyer, a cutting unit, and a conveyance switching mechanism of the bookbinding system of the embodiment of the present invention.
FIG. 3 (a) is an explanatory diagram showing the printing order of text sheets when inserting a manual-feed sheet between the front cover sheet and the top page with right-side binding, in the embodiment of the present invention. FIG. 3(b) is a perspective view explaining how the text sheets are stacked face up when inserting a manual-feed sheet between the front cover sheet and the top page with right-side binding, in the embodiment of the present invention.
FIG. 4 (a) is an explanatory diagram showing the printing order of text sheets when inserting a manual-feed sheet between the last page and the back cover sheet with right-side binding, in the embodiment of the present invention. FIG. 4(b) is a perspective view explaining how the text sheets are stacked face down when inserting a manual-feed sheet between the last page and the back cover sheet with right-side binding, in the embodiment of the present invention.
FIG. 5 is a perspective view explaining a clamper in the embodiment of the present invention.
FIG. 6 is a control block diagram of the bookbinding system of the embodiment of the present invention.
FIGS. 7 (a) to 7 (c) are respectively schematic side views for each process explaining the alignment operation of text sheets when no pre-folded sheet is inserted in the embodiment of the present invention.
FIGS. 8 (a) to 8 (c) are respectively schematic side views for each process explaining a preparatory operation of receiving a pre-folded sheet in the embodiment of the present invention.
FIGS. 9 (a) to 9 (d) are respectively schematic side views for each process explaining the alignment operation of the pre-folded sheet in the embodiment of the present invention.
FIGS. 10(a) to 10(c) are respectively schematic side views for each process explaining the alignment operation of text sheets after the pre-folded sheet is aligned in the embodiment of the present invention.
FIGS. 11(a) to 11(d) are respectively perspective views of each process of bookbinding in the embodiment of the present invention.
FIG. 12 is a control flow diagram of the bookbinding system in the embodiment of the present invention.
FIG. 13 is a perspective view showing how a bound book, which is manufactured in the embodiment of the present invention, is clamped by a clamping mechanism of a cutting machine.
FIG. 14 is a side view showing how a side edge of a bound book, which is manufactured in the embodiment of the present invention, is cut off by the cutting machine.
FIG. 15 is a plan view explaining how a finished book is obtained by cutting off, by a cutting machine, the side edges of the bound book which is manufactured in an embodiment of the present invention.

DESCRIPTION OF THE EMBODIMENTS

In the following, an embodiment of the present invention will be described, referring to the drawings. In the following description, components identical or similar to those already described are provided with identical or similar reference numerals, and detailed description thereof is omitted as appropriate.
The drawings are schematic and the dimensional ratio or the like is not to scale. Therefore, specific dimensional ratio or the like must be determined taking into consideration the following description. In addition, same parts included in two or more drawings may be drawn with mutually different dimension or ratio.
An embodiment shown in the following is illustrative for the purpose of realizing the technical idea of the present invention, and the embodiment of the present invention is not intended to limit the material, shape, structure, arrangement or the like of components to those described below. The embodiment of the present invention may be implemented in various ways in a range not deviating from its scope.
In the following description, sheets of any size may be applied as text sheets . Although printing may be performed by stencil printing or ink-jet, for example, other printing technique will do, and the printing form is not particularly limited by the present invention. The type or number of sheets of the printed matter to be bound is not particularly limited. In addition, a "manual-feed sheet" in the following description refers to a pre-folded sheet which has been multi-folded except for the edge of the spine side, such as a so-called Z-folded or two-folded sheet.
FIG. 1 is a schematic overall configuration diagram of a bookbinding system 100 of the embodiment (referred to as the present embodiment in the following) of the present invention. FIG. 2 is a configuration diagram of a sheet conveyer 310, a cutting unit 330, and a conveyance switching mechanism 338 of the bookbinding system 100 of the present embodiment. FIG. 3(a) is an explanatory diagram showing the printing order of text sheets when inserting a manual-feed sheet between the front cover sheet and the top page with right-side binding. FIG. 3(b) is a perspective view explaining how the text sheets are stacked face up when inserting a manual-feed sheet between the front cover sheet and the top page with right-side binding. FIG. 4(a) is an explanatory diagram showing the printing order of text sheets when inserting a manual-feed sheet between the last page and the back cover sheet with right-side binding. FIG. 4(b) is a perspective view explaining how the text sheets are stacked face down when inserting a manual-feed sheet between the last page and the back cover sheet with right-side binding. The numbers provided at the corners of text sheets HP in FIGS. 3 and 4 indicate page numbers.
FIG. 5 is a perspective view explaining a clamper. FIG. 6 is a control block diagram of the bookbinding system of the present embodiment. FIGS. 7(a) to 7(c) are respectively schematic side views for each process explaining the alignment operation of text sheets when not inserting a pre-folded sheet in the present embodiment. FIGS. 8(a) to 8(c) are respectively schematic side views for each process explaining a preparatory operation of receiving the pre-folded sheet in the present embodiment. FIGS. 9(a) to 9(d) are respectively schematic side views for each process explaining the alignment operation of the pre-folded sheet in the present embodiment. FIGS. 10(a) to 10(c) are respectively schematic side views for each process explaining the alignment operation of text sheets after the pre-folded sheet is aligned in the present embodiment. In FIGS. 7 to 10(b), a side guide on the front side is omitted to facilitate explanation. FIGS. 11(a) to 11(d) are respectively perspective views of each process of bookbinding in the present embodiment. FIG. 12 is a control flow diagram of the bookbinding system 100 of the present embodiment.
As shown in FIG. 1, the bookbinding system 100 according to the present embodiment includes an image forming device 200 which performs printing on a front cover sheet FP and text sheets HP, a folding device 264 provided at a position on the downstream end side in the sheet conveyance direction adjacent to the image forming device 200 to fold sheets, and a bookbinding device (case binding device) 300 provided at a position on the downstream end side of the folding device 264 in the sheet conveyance direction to perform a binding process on the printed front cover sheet FP and the printed text sheets HP. In other words, the bookbinding system 100 is a system which manufactures a bound book (booklet) 440 by performing printing on the front cover sheet FP and the text sheets HP and binding process on the printed front cover sheet FP and the printed text sheets HP. Note that, subsequently, the bound book 440 has its three side edges except for the spine side cut off by a cutting machine.

(Image forming device)

The image forming device 200 in the bookbinding system 100 is provided with an ink-jet image forming unit 230. The image forming unit 230 is configured to perform printing on the front cover sheet FP and the text sheets HP based on cover image data and text image data. In addition, the image forming unit 230 has a plurality of line-type ink heads which respectively eject color inks of black K, cyan C, magenta M, and yellow Y.
A first paper feeder 210 having the front cover sheets FP accommodated and stacked thereon and a second paper feeder 220 having the text sheets HP accommodated and stacked thereon are provided upstream of the image forming unit 230 in the sheet conveyance direction. In addition, the second paper feeder 220, having provided therein a first paper feed tray 220a, a second paper feed tray 220b, and a third paper feed tray 220c, can accommodate text sheets HP of various types and sizes of sheets. It is possible to feed and convey sheets from the first paper feeder 210 and the second paper feeder 220 to the image forming unit 230 sequentially at a predetermined timing, while handling sheets one by one with a paper feed roller (not illustrated) . Here, it is not always necessary to accommodate the front cover sheets FP in the first paper feeder 210 and the text sheets HP in the second paper feeder 220, and it does not matter if the sheets are accommodated in any of the paper feeders.
A circular conveyance path 250 is provided downstream of the image forming unit 230 in the sheet conveyance direction. The printed sheets are discharged via the circular conveyance path 250 to a paper ejector 262 provided further downstream. The sheets discharged to the paper ejector 262 are used when the bookbinding process which will be described below is not performed. In addition, a path switching flapper (not illustrated) is provided in the circular conveyance path 250, which allows switching between a conveyance path to the paper ejector 262 and a conveyance path to a reversing unit 240. A sheet conveyed to the reversing unit 240 is reversed and switch-backed so as to be conveyed to the image forming unit 230 again. Accordingly, it becomes possible to perform duplex printing on the front cover sheet FP and the text sheets HP.
The front cover sheet FP and the text sheets HP, which have been subject to one-side printing or duplex printing, are conveyed via a communication conveyer 260 provided downstream of the image forming unit 230 in the sheet conveyance direction, folded by the folding device 264 as necessary, and conveyed to the bookbinding device 300. The communication conveyance path 260 and the circular conveyance path 250 are provided with the path switching flapper, and the path is selected as appropriate. In addition, the folding device 264 is controlled by a controller 282 which will be described below so that a sheet not supposed to be folded passes therethrough as it is.
An input panel 270 is provided at the top surface of the image forming device 200. The input panel 270 has provided thereon a start button for instructing execution of bookbinding, a touch panel for performing various settings such as selection of cleaning mode by which ON/OFF of cleaning operation can be selected and selection of sheet size. When forming a bound book using image data read from a scanner or the like, although it is possible to perform various settings via the input panel 270, the image forming device 200 usually receives job data from a personal computer connected via a communication interface, and accepts user settings by operation signals included in the job data (not shown) . Here, a PC (Personal Computer) may be connected to the bookbinding system 100 so that user settings are input from the PC screen instead of the input panel 270.
With the image forming device 200 configured as described above, the controller 282 which will be described below controls the order of printing text sheets HP and an insertion position of a manual-feed sheet MP so that they are determined according to the setting of the insertion position (front cover side or back cover side) of the pre-folded sheet or the manual-feed sheet which will be described below, which has been sent from the image forming device 200, and the setting of the side to be bounded (right-side binding or left-side binding). For example, as shown in FIG. 3, when inserting a manual-feed sheet MP between the front cover sheet and the top page with right-side binding, the controller 282 is controlled so that images are printed in descending order from the last page in a direction facing the front of the device (forward of the device), and the printed text sheets HP are stacked face up on the alignment tray 352. When inserting a manual-feed sheet MP between the last page and the back cover sheet with right-side binding, as shown in FIG. 4, the controller 282 is controlled so that images are printed in ascending order from the top page in a direction facing the back of the device (backward of the device), and the printed text sheets HP are stacked face down on the alignment tray 352.

(Bookbinding device)

The bookbinding device 300 in the bookbinding system 100 is provided with the sheet conveyer 310 which conveys the printed cover sheet FP and the printed text sheets HP which have been sent from the communication conveyance path 260 on the side of the image forming device 200. The cutting unit 330 which cuts the front cover sheet FP into a suitable size is provided at a position adjacent to the sheet conveyer 310. The conveyance switching mechanism 338 which will described below conveys the front cover sheet FP to the cutting unit 330, where cutting operation is performed. The cover sheet FP and the text sheets HP are respectively conveyed to a formation unit 380 and an aligner 350, via the sheet conveyer 310. The sheet conveyer 310 is provided with a mechanism (not shown) which switches between the conveyance paths to the formation unit 380 and the aligner 350.
The aligner 350 is provided with the alignment tray 352 which sequentially stacks the text sheets HP conveyed thereto. The alignment tray 352 is provided with a front end guide (abutting fence) 354 configured to align the position of the text sheets HP in the sheet conveyance direction, a rear end guide (rear end fence) 355 provided upstream of the front end guide 354 in the conveyance direction and movable in the conveyance direction, and a side guide (side fence) 356 configured to align the position of the text sheets HP in the width direction. Both the front end guide 354 and the rear end guide 355 are assumed to be movable in parallel to the sheet conveyance direction, i.e., in a direction along which the distance therebetween increases or decreases.
As shown in FIG. 6, the aligner 350 is provided with a rear end guide home position sensor 350b, a rear end guide movement pulse motor 350c, a feed-in roller drive pulse motor 350d, a front end guide home position sensor 350e, and a front end guide movement pulse motor 350f. The rear end guide home position sensor 350b detects the home position of the rear end guide 355. The rear end guide movement pulse motor 350c provides the rear end guide 355 with a movement force. The feed-in roller drive pulse motor 350dprovides a feed-in roller 348 with a rotational force. The front end guide home position sensor 350e detects the home position of the front end guide 354. The front end guide movement pulse motor 350f provides the front end guide 354 with a movement force.
The feed-in roller 348, configured to feed the text sheets HP and the manual-feed sheet MP to the alignment tray 352, is provided upstream of the alignment tray 352 in the conveyance direction. The peripheral velocity of the feed-in roller 348 may be set by the controller 282 which will be described below so that the velocity is different for feeding the text sheets HP and for feeding the manual-feed sheet MP.
The bookbinding device 300 is provided with, at the upper part thereof, a manual-feed sheet insertion unit 302 for inserting the manual-feed sheet MP into the alignment tray 352. The manual-feed sheet insertion unit 302 has an insertion unit 304 for inserting the manual-feed sheet MP from the upper part of the device, and a guide unit 306 which guides the manual-feed sheet MP inserted into the insertion unit 304 to the upstream of the feed-in roller 348 in the conveyance direction. A sheet length measurement sensor 346 (see FIG. 1) which measures the lengths of the text sheets HP and the manual-feed sheet MP in the conveyance direction is provided downstream of the manual-feed sheet insertion unit 302 in the conveyance direction. In the present embodiment, a configuration is allowed such that the manual-feed sheet MP inserted from the manual-feed sheet insertion unit 302 and being in a stand-by state may be automatically fed to the alignment tray 352 at an appropriate feed timing, or a manual operation is allowed in which the manual-feed sheet MP is inserted and immediately fed to the alignment tray 352 by the user who has been waiting for an appropriate timing.
Note that, if the manual-feed sheet MP is thick, there may be provided a manual-feed sheet insertion unit 309 having an opening/closing door 307 included in the upper part of the device housing, and an insertion guide 308 which guides the manual-feed sheet MP inserted from the opening/closing door 307 to the alignment tray 352 so that the manual-feed sheet MP is placed on the text sheets HP without passing through the feed-in roller 348.
The bookbinding device 300 has a clamping unit 370 which clamps a sheet sheaf TP fed from the aligner 350 with clampers 372 (see FIGS. 1 and 5). The clamping unit 370 is movably provided between a receiving position where the sheet sheaf TP is received from the aligner 350 by a moving mechanism (not shown) and a binding position where the sheet sheaf TP is passed to the formation unit 380. The manual-feed sheet MP inserted into the alignment tray 352 forms the sheet sheaf TP together with the text sheets HP and the sheet sheaf TP is clamped by the clamping unit 370.
As shown in FIG. 6, the clamping unit 370 is provided with a sheet sheaf thickness detection sensor 370a, a clamp open/close home position sensor 370b, a clamp movement home position sensor 370c, a clamp traverse home position sensor 370d, a clamp open/close pulse motor 370e, a clamp movement pulse motor 370f, and a clamp traverse pulse motor 370g. The sheet sheaf thickness detection sensor 370a detects the thickness of the sheet sheaf TP based on a distance "d" (see FIG. 5) between clampers 372 when the sheet sheaf TP is clamped with the clampers 372. The clamp open/close home position sensor 370b detects the home position with regard to open/close of the clampers (clamp plates) 372. The clamp movement home position sensor 370c detects the home position when clamping the sheet sheaf TP with the clamping unit 370. The clamp traverse home position sensor 370d detects the home position with regard to the traverse (movement between the paste application position and the formation position) of the clamping unit 370. The clamp open/close pulse motor 370e provides the clampers 372 with an opening/closing force. The clamp movement pulse motor 370f provides the clamping unit 370 with a movement force between the position where the sheet sheaf TP on the alignment tray 352 is clamped and the home position. The clamp traverse pulse motor 370g provides the clamping unit 370 with a movement force between the paste application position and the formation position.
The clamping unit 370 is controlled to clamp, with the clampers 372, the front end TPT which is the edge of the sheet sheaf TP on the front end side in the conveyance direction (downstream end side in the conveyance direction), when detecting the thickness of the sheet sheaf TP. In addition, the clamping unit 370 is controlled to clamp, with the clampers 372, the central part of the sheet sheaf TP in the conveyance direction, when moving the sheet sheaf TP to a subsequent process. Here, the central part of the sheet sheaf TP in the conveyance direction refers to, without being limited to the intermediate position between the front end and the rear end of the sheets in the conveyance direction, a part of the sheets where the sheet sheaf TP can be moved in a clamped manner with no problem.
In addition, a book pasting device 360 is provided near the clamping unit 370 when located at the receiving position. The book pasting device 360 is provided with a paste accommodating unit (paste tank) 364 which accommodates paste, and a paste application roller 362 configured to apply paste to the sheet sheaf TP. The paste application roller 362 is elongated and held around a horizontal rotation axis inside the paste accommodating unit 364. Here, the paste (adhesive agent) collectively pastes the sheet sheaf TP to fix the cover sheet to the sheet sheaf TP.
As shown in FIGS. 1 and 11(a) to 11(d), the formation unit 380 is provided with a back folding plate 386 on which the front cover sheet FP conveyed from the sheet conveyer 310 is placed, and an abutment plate 388 provided below the back folding plate 386, to which the back side of the sheet sheaf TP conveyed to the binding position by the clamping unit 370 abuts through the front cover sheet FP.
In addition, as shown in FIG. 6, the formation unit 380 is provided with a cover position detection sensor 380a, a back folding plate home position sensor 380b, an abutment plate home position sensor 380c, a cover sheet conveying motor 380d, a back folding plate movement pulse motor 380e, and an abutment plate movement pulse motor 380f. The cover position detection sensor 380a detects the position of the front cover sheet FP. The back folding plate home position sensor 380b detects the position of the back folding plate 386. The abutment plate home position sensor 380c detects the home position of the abutment plate 388. The cover sheet conveying motor 380d provides the front cover sheet FP with a conveyance power. The back folding plate movement pulse motor 380e provides the back folding plate 386 with a movement force. The abutment plate movement pulse motor 380f provides the abutment plate 388 with a movement force.
A bound book ejection unit 390 is configured to be able to accommodate a plurality of bound books 440 which have been bound and formed in the formation unit 380 (see FIGS. 1 and 11(d)) and conveyed from the formation unit 380. Note that, in the present embodiment, conveyance from the formation unit 380 uses free-fall of the bound books 440.
As shown in FIG. 2, the sheet conveyer 310 is provided with four pieces of roller pairs in the order of a first conveyance roller 312, a second conveyance roller 314, a conveyance reference roller 316, and a conveyance reference auxiliary roller 322, from upstream of the sheet conveyance direction. The conveyance reference roller 316 is provided with a conveyance reference encoder 318 configured to control the amount of conveyance of the front cover sheet FP. A cover sheet size sensor 320 configured to detect the length of the front cover sheet FP in the conveyance direction is provided between the conveyance reference roller 316 and the conveyance reference auxiliary roller 322.
The conveyance switching mechanism 338 is provided between the first conveyance roller 312 and the second conveyance roller 314. The conveyance switching mechanism 338 is capable of switching between two paths, i.e., a normal conveyance path 338a which allows conveyance between the first conveyance roller 312 and the second conveyance roller 314, and a cutting conveyance path 338b which allows conveyance between the second conveyance roller 314 and the cutting unit 330, by pivoting around a switching fulcrum 338c using a drive mechanism (not shown).
The cutting unit 330 is provided with a cut auxiliary roller 336, a cutter 334, and a scrap container 332, in this order from the position near the conveyance path switching mechanism 338. The cutter 334 is a shuttle cutter, which can perform cutting with its blade moving back and forth in the width direction of the front cover sheet FP. The cut auxiliary roller 336 holds the front cover sheet FP when the cutter 334 cuts the front cover sheet FP. The scrap container 332 is configured to be able to accommodate useless parts of the cover sheet which becomes useless when cut. In addition, the scrap container 332 is removably provided so that the user can dispose of useless parts of the cover sheet accommodated therein to outside the container.
As shown in FIG. 6, the cutting unit 330 is provided with a cutter home position sensor 330a, and a cutter motor 330b connected to the cutter home position sensor 330a. Using the cutter home position sensor 330a, the controller 282 adjusts the home position of the cutter motor 330b having the cutter 334 (see FIG. 2) attached thereto, so that the length of the front cover sheet FP in the conveyance direction becomes appropriate.

(Controller)

As shown in FIG. 6, the bookbinding system 100 is provided with the controller 282. The controller 282 controls each part of the image forming device 200 and the bookbinding device 300, based on input information from the input panel 270, the conveyance reference encoder 318 (see FIG. 2), the cover sheet size sensor 320, or the like.
The controller 282 has a memory unit 284 configured to store the sheet size or the like, a page printing order determination unit 285 configured to determine the order of pages to be printed, and an image direction determination unit 286 configured to determine the direction of images when printing. Furthermore, the controller 282 has a cover sheet appropriate dimension calculator 287 configured to calculate an appropriate length of the front cover sheet FP in the conveyance direction, and a manual-feed sheet insertion unit controller 288 configured to insert the manual-feed sheet MP at a predetermined timing. In the present embodiment, a cutting position determination unit 287k is configured to cut the front cover sheet FP into a predetermined length based on the length calculated by the cover sheet appropriate dimension calculator 287. The controller 282 also has an aligner controller 289 configured to control the drive operation of the front end guide movement pulse motor 350f and the rear end guide movement pulse motor 350c.
In addition, the controller 282 has a clamp unit controller 296 configured to control the clamping unit 370, and a sheet sheaf thickness detector 299 configured to detect the thickness of the front end TPT by clamping (pre-clamping) the front end TPT of the sheet sheaf TP with the clamping unit 370. The front end TPT is an edge forming the spine side when the book is bound. The clamp unit controller 296 has a pre-clamp position calculator 297 configured to calculate the pre-clamp position to detect the thickness, and a clamp position calculator 298 configured to calculate the clamping position when conveying the sheet sheaf TP.
Furthermore, the controller 282 has a pasting device controller 290 configured to control the drive of the book pasting device 360. Along with the operation of clamping the text sheets HP by the clamping unit 370, the pasting device controller 290 controls the book pasting device 360 so as to rotate the paste application roller 362 and stop it at an application position and, after the application of paste to the spine side of the text sheets HP is completed, rotate the paste application roller 362 and stop it at a wait position.
In addition, the controller 282 has a timer 291. The timer 291 receives a signal from the cover position detection sensor 380a described above, and controls the formation unit 380 so that the text sheets HP and the front cover sheets FP are appropriately formed in the formation unit 380.

(Operation and effect)

Next, the operation of the bookbinding system 100 of the present embodiment will be described, referring to FIGS. 7 to 12. In the following description, the pre-folded sheet ZP will be described as it printed by the image forming device 200 and folded by the folding device 264. The bookbinding system 100 determines, as will be described below, that a manual-feed sheet MP inserted from the manual-feed sheet insertion unit 302 is a pre-folded sheet ZP and processes it accordingly. Therefore, the term "pre-folded sheet" refers to a pre-folded sheet before being folded or after having been folded by the folding device 264 and, when the phrase "printing of a pre-folded sheet" is described, it means that the image forming device 200 preliminarily performs printing on a sheet to be folded.
In the control flow of FIG. 12, when the print-and-bind operation is started, the controller 282 determines whether or not the next sheet to be conveyed from the image forming device 200 to the alignment tray 352 is a text sheet HP other than a pre-folded sheet ZP (step S1).
If the sheet to be conveyed is a text sheet HP other than a pre-folded sheet ZP (YES), printing of the text sheet HP is started (step S2). Subsequently, the length of the text sheet HP in the conveyance direction is measured by the sheet length measurement sensor 346 (step S3), and an alignment operation of the text sheets HP placed in the alignment tray 352 is performed (step S4). At step S4, as shown in FIGS. 7 (a) to 7(c) and FIGS. 10(a) to 10(c), alignment is performed by moving the rear end guide 355 downstream of the conveyance direction (toward the front end guide 354) back to its original position each time a text sheet HP is discharged to the alignment tray 352 by the feed-in roller 348, and causing the front end of the text sheets HP in the conveyance direction to abut against the front end guide 354. The distance of movement of the rear end guide 355 is determined by calculating an appropriate value by the controller 282, based on the length measured at step S3.
If, at step S1, the sheet to be conveyed is not a text sheet HP other than a pre-folded sheet ZP (NO), the preparatory operation of receiving the pre-folded sheet ZP is performed (step S5). At step S5, as shown in FIGS. 8(a) to 8(c), the front end guide 354 is moved from the home position to the upstream of the conveyance direction (toward the rear end guide 355), and the sheaf of the text sheets HP accommodated in the alignment tray 352 is moved toward the rear end guide 355. Subsequently, the front end guide 354 is returned to the home position which is its original position. Here, the home position of the front end guide 354 is a position when receiving the text sheets HP other than the pre-folded sheet ZP in the alignment tray 352, as shown in FIGS. 8(a) and 8(c).
Subsequently, either the image forming device 200 performs printing on a pre-folded sheet ZP and the pre-folded sheet ZP is conveyed from the folding device 264 to the bookbinding device 300, or a pre-folded sheet ZP is inserted from the manual-feed sheet insertion unit 302 (step S6), and the length of the pre-folded sheet ZP in the conveyance direction is measured by the sheet length measurement sensor 346 (step S7) . It is then determined (step S8) whether or not the length of pre-folded sheet ZP in the conveyance direction is shorter than a prescribed length B (see FIG. 14) from the spine side to the page opening side of the text sheets HP of a bound book 444 (see FIG. 15) which has been discharged from the bookbinding system 100 and has its side edges cut off.
If the length of the pre-folded sheet ZP in the conveyance direction is shorter than the prescribed length B (YES), the alignment operation of the pre-folded sheet ZP is performed (step S9). At step S9, as shown in FIGS. 9(a) to 9(d), discharging the pre-folded sheet ZP to the alignment tray 352 by the feed-in roller 348 positions the front end of pre-folded sheet ZP in the conveyance direction further downstream of the conveyance direction than the front end of the text sheets HP in the conveyance direction (see FIG. 9 (b)). Moving the rear end guide 355 downstream of the conveyance direction causes the front end position of the text sheets HP and the pre-folded sheet ZP in the conveyance direction to abut against the front end guide 354, thereby aligning the sheets (see FIG. 9 (c)). Subsequently, the rear end guide 355 is returned to its original position (see FIG. 9(d)). As a result, the front ends of the sheets are precisely aligned.
The bookbinding system 100 determines that a sheet inserted from the manual-feed sheet insertion unit 302 is a pre-folded sheet ZP, and thus steps S5 to S9 are performed without performing steps S1 to S4.
After step S9, it is determined whether or not printing of the text sheets HP and the pre-folded sheet ZP has been completed (step S10). If printing has not been completed (NO), the process flow returns to step S1.
If printing has been completed at step S10 (YES), the sheet sheaf TP in the alignment tray 352 is clamped by the clamping unit 370 (step S11), and paste is applied to the spine side of the clamped sheet sheaf TP by the book pasting device 360 (step S12) . A cover formation operation is then performed (see FIG. 11, step S13), and a book conveyance operation is performed to discharge the bound book 440 manufactured by the bookbinding system 100 to the bound book ejection unit 390 (step S14).
Subsequently, it is determined whether or not all the scheduled bookbinding operations have been completed (step S15) . If not all the bookbinding operations have been completed (NO), the process flow returns to step S1. If all the bookbinding operations have been completed (YES), the print-and-bind operation is terminated.
In addition, if, at step S8, the length of the pre-folded sheet ZP in the conveyance direction is not shorter than the prescribed length B (NO), the print-and-bind operation is interrupted and a message "pre-folded sheet size over" is displayed on the input panel 270 (step S16) . Here, the message may be communicated to the user via a sound such as an alarm instead of displaying it.
FIG. 13 is a perspective view showing how the bound book 440 is clamped by a clamping mechanism 470 of the cutting machine. FIG. 14 is a side view showing how the side edge of the bound book 440 is cut off by the cutting machine. FIG. 15 is a plan view explaining how a finished book is obtained by cutting off the side edges of the bound book 440 by the cutting machine.
The bound book 440 discharged at step S14 (before subject to cutting into a finished book) subsequently has its three side edges 440p, 440q and 440r except for the spine side cut off by the cutting machine into a finished book 444, as shown in FIGS. 13 to 15. In other words, the bound book 440 is clamped by the clamping mechanism 470 of the cutting machine, and each side edge except for the spine side is cut off by a cutter 472 of the cutting machine. The cutting is performed so that the text sheets HP and the front cover sheet FP conform with the standard size at the time of bookbinding.
In the present embodiment, the bookbinding operation is interrupted by the controller 282 if the length of the pre-folded sheet ZP in the conveyance direction is not equal to or less than the prescribed length B from the spine side to the page opening side of the text sheets HP in the bound book 444 having its side edges 440p, 440q and 440r cut off. Therefore, as shown in FIG. 14, the pre-folded sheet ZP will never protrude beyond the text sheets HP at the page opening side US of the bound book 440 opposite to the spine side BS. Therefore, the folded part ZPB of pre-folded sheet ZP will never be cut off even if the page opening side US of the bound book 440 is cut off by the cutting machine.
In addition, the front end position of the text sheets HP and the pre-folded sheet ZP in the conveyance direction can be aligned by controlling the movement of the rear end guide 355 and the front end guide 354 as discussed above. Therefore, the mechanism can be simplified without using a rotating paddle, and also prevention of the folded part ZPB of the pre-folded sheet ZP from being cut off can be easily realized without requiring a special device or a special operation procedure.
Moreover, insertion of the pre-folded sheet ZP is not particularly limited to the last page or the like, and it can be inserted midway through stacking of the text sheets HP.

Claims

A bookbinding system comprising:
an aligner (350) configured to align text sheets (HP) to be bound into a bound book (440); and

a controller (282) configured to control the aligner (350); and

a sheet length measurement sensor (346),

wherein the controller (282):
is suitable for determining whether or not a text sheet (HP) to be conveyed to the aligner (350) is a pre-folded sheet (ZP);

is suitable for determining, when the text sheet (HP) to be conveyed to the aligner (350) is the pre-folded sheet (ZP), whether or not the length of the pre-folded sheet (ZP) in a conveyance direction measured by the sheet length measurement sensor (346) is shorter than a prescribed length from a spine side to a page opening side of text sheets (HP) in the bound book (440) after side edges of the text sheets (HP) have been cut off, and

is suitable for switching, when the length of the pre-folded sheet (ZP) in the conveyance direction is shorter than the prescribed length, alignment procedures in the aligner (350),and

characterized in that

the controller (282) is suitable for interrupting a bookbinding operation and is suitable for warning a user, when the length of the pre-folded sheet (ZP) in the conveyance direction is not shorter than the prescribed length.
The bookbinding system according to claim 1, wherein
the aligner (350) includes a rear end member (355) located on an upstream side in the conveyance direction of the text sheet (HP) that has been accommodated in the aligner (350), a front end member (354) located on a downstream side in the conveyance direction of the accommodated text sheet (HP), a first motor (350c) configured to move the rear end member (355), and a second motor (350f) configured to move the front end member (354), and
when the length of the pre-folded sheet (ZP) in the conveyance direction is shorter than the prescribed length, the controller (282):
is suitable for moving the accommodated text sheet (HP) toward the rear end member (355) side by moving the front end member (354) from a home position toward the rear end member (355) side using the second motor (350f);

is suitable for returning the front end member (354) to the home position using the second motor (350f);

is suitable for conveying the pre-folded sheet (ZP) to the aligner (350); and

is suitable for moving the accommodated text sheet (HP) toward the front end member (354) side by moving the rear end member (355) toward the front end member (354) side using the first motor (350c).