The present invention relates to a bookmaking method in a bookmaking system that aligns sheets printed by an image forming apparatus in a bundle on a tray in the proper page order and binds the sheet bundle to create a booklet.
Bookmaking apparatus are widely used as a terminal device of an image forming apparatus such as a printer or printing machine, to stack sheets formed with images in proper order, align the sheets into a booklet, apply adhesive to one edge of the stacked booklet and bind the stacked booklet to a cover sheet. On-demand printing systems, such as electronic publishing systems, are known that print and finish a predetermined booklet by printing predetermined information, automatically binding and covering the booklet and then cutting the edges of sheets.
Such a system is proposed in Japanese Patent Application Publication No. 2004-209869 that discloses creating automatically a booklet of sheets output from an image forming apparatus. Outputted sheets are received from a discharge outlet and guided to a discharge path, then stacked and stored in a tray disposed at a lower side of the discharge outlet. The sheet bundle stacked on the tray in a horizontal posture is turned 90 degrees, then guided in a vertical posture to an adhesive application unit for gluing. The glued sheet bundle is then glued to a cover sheet supplied from an inserter and folded around to the sheet bundle. After adhesion of the sheet bundle to the cover, sheet bundle sides not glued are trimmed to finish the booklet. The finished booklet is then stored in a stacker.
The 2004-209869 document further discloses a roller impregnated with adhesive that travels along a sheet bundle edge while applying adhesive to a sheet bundle held in a vertical posture. A gap is then formed between the adhesive roller and the edge of the sheet bundle, creating a build-up layer of adhesive, on the roller that is applied to the edge of the sheet bundle. Adhesive applied in this manner to the back or binding portion of the edge of the sheet bundle may under some conditions fail to seep between the sheets, resulting in sheets falling out of the booklet.
For that reason, Japanese Patent Publication No. 11-21006 discloses a method for applying adhesive by deforming and opening the sheet edges by pressing the adhesive roller and sheet bundle edge together.
Accordingly, one method of applying adhesive to a sheet bundle edge using an adhesive roller includes the formation of a gap, as small as tolerable, between the sheet bundle edge and the adhesive roller to apply adhesive while separated. A second method includes forcefully pressing the sheet bundle edge and adhesive roller together causing the sheets to deform and separate the sheets in order to apply the adhesive between the sheets.
Using the former method, adhesive is applied to the back or binding portion of the sheet bundle. However, because adhesive does not get between sheets, a problem of sheets becoming detached from the final booklet may arise. If the latter method is applied, adhesive does get between pages, but the cover sheet which is not applied with adhesive on the back of the sheet bundle partially adheres causing unevenness, so the problem of wrinkles forming on the back of the cover sheet occurs.
This invention provides a bookmaking method that securely adheres the sheets together when creating a booklet by covering a sheet bundle with a cover sheet, and securely and uniformly adheres a cover sheet to a backside of a sheet bundle edge without loss of aesthetic appeals of the booklets.
The present invention employs the following configuration to solve the problems described above.
A first aspect of the present invention comprises sheet support means for holding a sheet bundle in a substantially vertical posture and adhesive application means arranged below the sheet support means, having an application member for applying adhesive to bottom side edge of a sheet bundle held by the sheet support means. Also, first conveyance means for moving the sheet support means and/or the adhesive application means relatively along the bottom side edge of the sheet bundle. Also, second conveyance means for moving the sheet support means and/or the adhesive application means in a substantially vertical direction to change the gap distance between the sheet bundle bottom side edge and the adhesive application member.
Furthermore, control means for controlling the first and second conveyance means and executing a first application action and a second application action are included with the following configuration. The control means execute a first application action on the sheet bundle bottom edge by operating the first conveyance means when a sheet bundle bottom edge and adhesive application member are pressed together with a first contact pressure by the second conveyance means. Then, after executing the first application action, the control means execute a second application action on the sheet bundle bottom edge by operating the first conveyance means when a sheet bundle bottom edge and adhesive application member are pressed together with a second contact pressure by the second conveyance means that is weaker than the first contact pressure. It is acceptable to configure the sheet support means in this case by a clamper member that grips a sheet bundle from the front and back. If the clamper member is configured to be able to move, it may also convey a sheet bundle while holding it.
This configuration makes it possible to cause the bottom edge of the sheet bundle to separate by a pressing force of the adhesive application member in the first application action, and to form a substantially uniform adhesive layer on the bottom edge of the sheet bundle with the second application action.
A second aspect of the present invention is to configure the adhesive application member as an adhesive-impregnated roller, as in the first aspect, and to configure the adhesive application means with the adhesive-impregnated roller and an adhesive tray that supplies adhesive to the adhesive-impregnated roller.
The third and fourth aspects of the present invention configure the first conveyance means with the adhesive application member, as in the configuration of the first and second aspects. A horizontal guide that guides the adhesive application member along a bottom edge of the sheet bundle in a substantially horizontal direction and a drive means for driving adhesive application member along the horizontal guide means horizontally are included. The third and fourth aspects include second conveyance means that comprise the sheet support means, a vertical guide means configured to allow the sheet support means to be able to move in a substantially vertical direction, and drive means for elevating the sheet support means along the vertical guide means.
The fifth and the sixth aspects of the present invention include a bookmaking apparatus comprising the first conveyance means that also includes the adhesive application member, a horizontal guide means that guides the adhesive application member in a substantially horizontal direction along a bottom edge of the sheet bundle, and drive means that drive the adhesive application member horizontally along the horizontal guide means. The fifth and sixth aspects include the second conveyance means with sheet support means, vertical guide means that guides the sheet support means to move in a substantially vertical direction, and drive means for elevating the sheet support means along the vertical guide means, wherein control means control drive means for driving the adhesive application member to move reciprocally from one edge to another edge along a bottom edge of the sheet bundle, as in the configuration of the third and fourth aspects of the invention. The control means execute the first application action in the outward movement of the drive means, and the second application action with the return movement of the drive means. This configuration can apply adhesive in a comparatively short amount of time.
The seventh aspect of the present invention is based upon the first aspect of the invention and comprises the control means including thickness recognition means for detecting a thickness of a sheet bundle. When performing the first application action, the first contact pressure changes according to the thickness of the sheet bundle. The first contact pressure is set higher as the sheet bundle becomes thicker.
The eighth aspect of the present invention is based upon the first aspect of the invention, and equips the control means with thickness recognition means for detecting a thickness of a sheet bundle. In addition, when performing the second application action, the control means controls the second conveyance means in order to increase the gap between the bottom edge of the sheet bundle and the adhesive application member as the thickness of the sheet bundle increases. This makes it possible to make a thicker layer of adhesive to be dispensed for a thicker sheet bundle, thereby making it possible to securely bind the sheets with adhesive.
The ninth aspect of the present invention is to equip the thickness recognition means to the sheet support means, as in the seventh aspect, and includes sheet support means with clamping members that grip a sheet bundle in addition to sensors that are configured to detect a gripping position of the clamping members. This configuration makes it possible to detect the thickness of the sheet bundle when sandwiching the sheet bundle.
The tenth aspect of the present invention is based upon the seventh aspect and configures the thickness recognition means with counting means for counting a number of sheets that comprises the sheet bundle and operation means for calculating the thickness of the sheet bundle based upon a sheet count value determined by the counting means. The operation means is operable to multiply an average thickness of an individual sheet by the sheet count value determined by the counting means.
The eleventh aspect of the present invention includes a cover sheet conveyance means for conveying a cover sheet below the adhesive application means and means for joining a cover sheet set at a predetermined position by this cover sheet conveyance means with a bottom side edge of a sheet bundle that has been applied with adhesive by the second application action, as in the configuration of the first aspect. A means for joining may include moving a cover sheet to press a sheet bundle gripped by a backup support, and the sheet support means may comprise gripping conveyance means. In some cases, a press member may be included along with the backup member, for clamping a shoulder of the sheet bundle simultaneously to the cover sheet.
The twelfth aspect of the present invention comprises sheet support means for holding a sheet bundle in a vertical posture, adhesive application means arranged below the sheet support means, and an application member for applying adhesive to a bottom side edge of a sheet bundle held by the sheet support means. This aspect may further include the first conveyance means for conveying the sheet support means and/or the adhesive application means relatively along a bottom edge of the sheet bundle, the second conveyance means for moving the sheet support means and/or the adhesive application means in a substantially vertical direction, an ability to change a gap distance between the bottom edge of the sheet bundle and the adhesive application member, and control means for executing a first and a second application action by controlling the first and the second conveyance means.
In support of the first conveyance means, the control means allows the sheet support means, and/or the adhesive application means, to perform a plurality of reciprocal movements along the bottom edge of the sheet bundle. For each reciprocal action, the second conveyance means may change the gap distance between the bottom edge of the sheet bundle and the adhesive application member.
A 13th aspect of the present invention comprises image forming means for forming images on sheets, tray means for stacking sheets from the image forming means, and a bookmaking apparatus having sheet support means for conveying a sheet bundle on the tray means to a predetermined adhesive application position at a substantially vertical posture, for applying adhesive to a sheet bundle held by the sheet support means, wherein the bookmaking apparatus is composed of the bookmaking apparatus of the configuration of the first aspect.
The present invention performs the first application action while the adhesive application member is in pressing contact with the sheet bundle. After the first application action, a second application action, weaker in contact pressure than that of the first application action, or separated from and not in contact with the sheet bundle, is executed in order that adhesive penetrates between the sheets at the first application action and a uniform adhesive layer is formed on the back of the sheet bundle edge at the second application action.
Accordingly, sheets do not fall out after the book has been created, and a uniform layer of adhesive is formed between the cover sheet and the back of the sheet bundle edge to prevent unevenness or wrinkles, in order that the aesthetic appeal of the book is not lost. Furthermore, because the adhesive application member is configured to reciprocally move from one edge of a stationary sheet bundle to another edge, the overall apparatus may be more compact compared to a system configured for the sheet bundle to move its edge direction. Accordingly, the first application action may be executed at the outward pass of the adhesive application member, and by executing the second application action in the return pass, the time for applying adhesive may be shortened.
Preferred embodiments of the present invention based on a bookmaking apparatus that employs the invention will be described below with reference to the accompanying drawings.
The bookmaking system shown in
Image Printing Unit
The image printing unit A is embedded in a system such as a computer or word processor. It prints to a series of sheets, and then conveys them out from a discharge outlet. Any type of printing means, such as a laser printer or ink jet printer can be employed. There is nothing particularly special about the one disclosed in the drawings. Any known printing means or other configuration of an image forming apparatus may be employed.
Inserter Unit
Sheets discharged from the image printing unit A described above are conveyed toward the stacking tray unit, described below, to undergo the bookmaking process. The inserter unit B supplies a cover sheet to this discharge path. For that reason, a hopper for supplying cover sheets, a separator mechanism for kicking out one sheet at a time from the hopper, and a conveyance mechanism for conveying a sheet to a discharge path are configured. Note that the embodiment disclosed in the drawings does not employ a configuration having any particular feature. Any known inserter configuration may be used.
Stacking Tray Unit
The stacking tray unit C collects sets of sheets sequentially discharged from a discharge outlet of the image printing unit in page order to form a stacked sheet bundle. For that reason, the stacking tray unit is arranged below the discharge outlet and is composed of tray means for sequentially stacking sheets. The tray means is equipped with a trailing edge control member for engaging a sheet edge to control the sheet; auxiliary conveyance means, such as forward and reverse drive rollers, for feeding a sheet to the trailing edge control member; and aligning means for aligning right and left sides of a sheet in the width direction using the sides of the sheet as references, or aligning a sheet using a center as a reference.
A first feature of the apparatus of the embodiment disclosed in the drawings is that a portion of the tray is movable. The tray is configured to allow a portion thereof to be able to extend or retract in the direction of sheet conveyance. A sheet conveyance direction length signal is employed to change the position that supports a leading end of a sheet in the forward or reverse direction (in the direction of sheet conveyance). This configuration makes it possible to support sheets in a stable manner and without misalignment, regardless of the length of the sheets. Simultaneously, this configuration makes it possible to adjust the position of the curling portion of the sheet which results into accurate position alignment of stacked sheets.
A second feature is that the tray performs multiple rolls that include stacking sheets, as described above, and conveying a sheet bundle toward, for example, a stacking position and a processing position of a next process. Specifically, the stacking tray unit is capable of rising and lowering between a stacking position for stacking sheets, and a conveyance position for conveying sheets to a next process. This configuration simplifies the sheet bundle conveyance mechanism and enables a more compact apparatus.
Bundle Conveyance Mechanism Unit
The bundle conveyance mechanism unit conveys sheets stacked and aligned in a bundle at the stacking tray unit, disclosed above, to a processing position of a next process with their edges and positions neatly aligned by aligning means. In order to feed the bundle to the finishing process position, e.g., the application of adhesive, the bundle conveyance turns from the tray in a substantially horizontal position to a substantially vertically position. An additional feature of the apparatus shown in the drawings includes a sheet bundle being conveyed from the stacking tray unit to a finishing position of a next process by first gripping conveyance means and second gripping conveyance means.
Simultaneous to this, tray means cooperate with the first gripping conveyance means to move a sheet bundle from a stacking position downward to a sheet conveyance position below over a predetermined distance, and to then move the sheet bundle to the second gripping conveyance means. At that point the second gripping conveyance means moves to a finishing position in a substantially vertical posture by turning the sheet bundle a predetermined angle, but at that time the tray means are lowered a predetermined amount to the lower side, and after handing the sheet bundle over to the second gripping conveyance means, there is no need to arrange a discharge path beyond what is necessary above the apparatus to ensure clearance for the gripping conveyance means to turn over sheets (a locus or revolution of the sheets).
Furthermore, the apparatus in the drawings is equipped with a stopper member for engaging a processing edge of a sheet bundle at a finishing position when the sheet bundle is conveyed by the second gripping conveyance means to the finishing position. The processing edge of the sheet bundle engages the stopper member so that the posture of the sheet bundle is positioned properly at a reference position for finishing. This makes the correct finishing possible by correcting the posture of the sheet bundle at the finishing unit, even if the position of the sheet bundle becomes misaligned during its conveyance.
Adhesive Unit
The adhesive unit E applies adhesive, such as glue, to the backside edge of the stacked sheet bundle. When doing so, the sheet bundle must be positioned in an inverted posture in a substantially vertical direction. The apparatus of the present invention is capable of retracting the adhesive tray of the adhesive unit E toward the backside of the sheet bundle, away from the conveyance path of the sheet bundle. The apparatus is configured to continue conveying the sheet bundle in a direct line path after applying adhesive. The reference member that touches and controls a processing edge of the sheet bundle is arranged with the adhesive application unit retracted, a complex sheet bundle conveyance path unnecessary. The adhesive application unit E comprises a roller for applying adhesive to the processing edge (the back) of the sheet bundle, and a compact tray for supplying adhesive to the roller. Because the adhesive tray travels along with the adhesive applying roller, the adhesive application unit E may be made compact.
Binding Unit
The binding unit joins the glued sheet bundle to a center position of a cover sheet supplied by the inserter unit B, described above. The binding unit folds the cover sheet to form a booklet for the sheet bundle. When the adhesive application unit retracts from the sheet bundle conveyance path, the cover sheet is supplied from a path that is substantially orthogonal to the sheet bundle conveyance path. The cover sheet is joined with the adhesive applied edge surface of the substantially vertically positioned sheet bundle along a center line of the cover sheet. Folding rollers then fold the cover sheet around the sheet bundle to cover it. The apparatus in the drawings is equipped with backup members and a folding block to neatly press the back cover and shoulders of the cover sheet and inner sheet bundle.
Trimming Unit
The trimming unit is operable to cut the outer sheet edges of the glued back portion of the sheet bundle, to complete the bookbinding process. For that reason, the sheet bundle is gripped by gripping means so the side edges may be sequentially cut by the cutter member. Non-limiting, any known cutting mechanism may be utilized.
Storing/Stacking Unit
The storing/stacking unit stacks sheet bundles that have been made into booklets. Storing/stacking units are known in the field of bookmaking and any known storing/stacking unit may be used.
The following will explain the configuration of each of the units described above.
Image Printing Unit A
As can be seen in
As can be seen in
Inserter Unit B
Sheets sequentially formed with images are conveyed to a discharge outlet 107 of an image printing unit A. Normally, a discharge stack is prepared at the discharge outlet 107. With this invention, a sheet conveyance, i.e., a bookmaking apparatus connected to the discharge path 107, is inserted into path 501. An inserter unit B is mounted to the sheet conveyance in path 501. The inserter unit B comprises one or more trays for stacking sheets (shown in the drawing as a two-tiered stacking tray 201); pickup means 202 for separating sheets on the stacking tray 201 into single sheets; and a sheet supply path 203 for guiding sheets from the pickup means 202 to the sheet conveyance in path 501.
Sheets stacked on the stacking tray 201 are sequentially conveyed to the sheet conveyance mechanism in path 501 between sheets conveyed out from the discharge outlet 107 of the image printing unit A. Specifically, after the final sheet of a series of sheets has been discharged from image printing unit A, a sheet is supplied from the stacking tray 201. Special sheets, such as thicker sheets or coated sheets, may be prepared as cover sheets and loaded in the stacking tray 201. Upon receipt of a control signal from the bookmaking apparatus, a sheet on the stacking tray 201 is conveyed to the sheet conveyance mechanism in path 501. Although a two-tiered stacking tray 201 may be supplied, making it possible to prepare in advance different types of cover sheets, cover sheets from only the selected stacker are conveyed to the sheet conveyance mechanism.
Stacking Tray Unit C
As shown in
A stacking tray unit C for stacking in a bundle a series of sheets formed with images is arranged above the sheet conveyance mechanism in path 501. A bundle conveyance mechanism unit D is also arranged above the sheet conveyance in path 501 for conveying a sheet bundle from the stacking tray unit C to an adhesive application unit E position. A branching discharge path 301 is established on the sheet conveyance mechanism in path 501. This discharge path 301 is configured to discharge a sheet substantially horizontally above the sheet conveyance mechanism in path 501. Arranged on the discharge path 301 are a feed roller 302 and sheet sensor 303.
Tray means 305 are disposed below a discharge outlet 304 of the discharge path 301 forming a predetermined level therewith. Sheets are stacked and supported on the tray means 305 from the discharge outlet 304. Although tray means 305 may be fixedly disposed to the apparatus frame F1, F2, the tray means 305 may be disposed according to the embodiments illustrated the accompanying figures and as described below.
After a predetermined number of sheets has been stacked, the tray means 305 is configured to move toward a finishing position direction of a next process along with the sheet bundle. The tray means 305 is configured to rise and lower between a stacking position for stacking sheets (hereinafter referred to as a raised position) and a lowered position (hereinafter referred to as a lowered position) that is a predetermined distance below the raised position. The tray means 305 is configured to rise and lower so that stacked sheet bundles may be conveyed without disturbing their aligned state and to provide a compact conveyance mechanism. It is preferable that the tray means 305 be as compact and as light-weight as possible. The tray means shown in the drawings is configured so that the length of the tray member is shorter than the length of a sheet conveyance direction in order that the leading ends of sheets hang outside of the tray member.
Aligning means 314 (
As shown in
Still referring now to
Specifically, the movable support unit 305b is slidably supported in the sheet discharge direction on the fixed support unit 305a. The movable support unit 305b slides in the sheet discharge direction by drive means composed of the rack 309, the pinion 310 and the drive motor M1.
As shown in drawings, at least the fixed support unit 305a of the tray means 305 is obliquely arranged. A first aligning means 311 (
A guide member 312 is established above the tray means 305 for guiding a sheet from the discharge outlet 304. The guide member 312 is composed of a plate-shaped member positioned above the discharge outlet 304 to guide sheets from the discharge outlet so that they are conveyed along the tray without being thrown about, and to guide sheets when they are conveyed to the first aligning means 311 by a forward and reverse drive roller, described below.
The guide member 312, composed of a plate-shaped member is supported at its base end by a rotating shaft 313. This rotating shaft 313 is connected to a stepping motor, not shown. Stepping control of this motor controls the movement of the guide member 312 between a position retracted above the tray, a position for guiding a sheet from the discharge outlet, positioned above the discharge outlet, and a position for guiding a sheet on the tray to the first aligning means 311.
Forward and reverse drive rollers 113 configured to rise and lower are arranged downstream of the guide member 312. The forward and reverse roller 113 functions as an auxiliary conveyance means and rotates in the sheet discharge direction (forward rotation direction) at a position where the roller 113 contacts a sheet advancing into the tray means (the fixed support unit 305a) from the discharge outlet 304, and rotates in a reverse direction (reverse rotation direction) after an estimated or predetermined amount of time to allow the trailing end of the sheet to separate from the discharge outlet 304 to move the leading end of the sheet toward the first aligning means 311. For that reason, the forward and reverse roller 113 is supported by an arm member (bracket) that allows the roller shaft to freely rotate and is connected to a forward and reverse drive motor. This arm member is configured to retract from the sheet to a position above the tray by the operation of a one-way clutch and the rotating direction of the motor.
Aligning means 314 and pressing means 320 are arranged on the tray means 305, described above, for aligning the sheet sides. The aligning means 314 are composed of aligning members 315a and 315b that are paired left and right for positioning the side edges of a sheet at a reference position that is at a right angle to the direction of sheet discharge. For that purpose, the left and right aligning members 315a and 315b can move toward a center of the sheet in the width direction the same amounts to perform alignment on center point reference, or one aligning member can be stationary while the other aligning member can move in the sheet width direction a predetermined amount to perform alignment with reference to one side. Either method is known in the art. These structures are well known, and thus are summarized.
As can be seen in
Furthermore, tray means 305 is arranged with a sheet pressing member 320 (
The embodiments disclosed herein disclose the pressing member 320 configured to move according to the size of the sheet due to the relationship of the movable support unit 305b being configured to move its position according to the size of the sheet. In other embodiments, the pressing means 320 may be configured by a weighted piece that hangs downward in a ramp shape above the tray.
Still referring to
Note that wing-shaped auxiliary trays 305c are established on the left and right sides of the fixed support unit 305a that support sheet sides (both sides) that project outside of the fixed support unit 305a on the tray means 305. This is to make the fixed support unit 305a that configures the tray means narrower than the width of sheets. Furthermore, auxiliary trays 305c cause the sides of the sheets to protrude outside of the tray so that the gripping means, described below, can grip the corners of the sheet.
Specifically, as shown in
Bundle Conveyance Mechanism Unit
Sheets formed with images are sequentially picked up from the discharge outlet 301 (
In one embodiment of the present invention, tray means 305 move to a conveyance position that lowers a predetermined amount from a raised position where sheets are stacked. The following will explain the elevator structure of the tray means 305.
As shown in
The fixed support unit 332 (hereinafter referred to as the “tray assembly 332”) having the structure described above, is matingly supported to slide on the apparatus frame F1, F2 by operation of the left and right pair of guide shafts 333 (
Therefore, when the elevator motor M3 rotates, the drive gear 335 rotates thereby moving the rack 336 upward or downward, and the tray assembly 332 rises or lowers. The tray assembly 332 lowers in the downward direction with the clockwise direction rotation of the drive gear 335 at the position shown in the drawing. The tray assembly 332 rises with the counterclockwise direction rotation of the drive gear 335. Racks 337 are provided in a pair on the left and right on the apparatus frame F1, F2. The racks 337 mesh with the fan-shaped gears 338 so the rotation of the shaft 331, interlocked with the up and down action of the tray assembly 332, rotates the auxiliary tray 305c.
When the tray assembly 332 is lowered from the position shown in
The raised position of the tray assembly 332 is set to a position for stacking sheets from the discharge outlet 301, as shown in
A first gripping conveyance means is provided at the position of the auxiliary tray 305c to grip both edges of sheets after the auxiliary tray 305c moves to a retracted position. As shown in
The guide rails 408 are arranged in positions that are paired on the left and right sides. A frame 409 is matingly supported to move along these guide rails 408. The entire side frame 409 is supported to move in the left and right directions of
Still referring to
Still referring to
Upper and lower clampers are mounted to each clamp support frame 402. An elastic pad, such as one made of rubber, is integrally mounted to the clamp support frame 402 on the upper clamper 403. The upper clamper 403 is configured to move in up and down directions to engage and separate from the sheet bundle on the tray assembly 332 by operation of the drive motor M8 of the movable frame 410 (
On the other hand, the lower clamper 404 may be mounted to a plunger 405 that is slidably mounted to the clamp support frame 402. The lower clamper 404 is composed of an elastic pad, such as one made by rubber. This plunger 405 may internally house an elastic spring, and is mounted to move in up and down directions on the clamp support frame 402. The plunger 405 is integrally equipped with the rack 406. The pinion 407 meshes with the rack 406, and a drive motor M4 is connected to this pinion 407 interposed by a transmission shaft 415. Note that the pinion 407 is movably mated in the shaft direction on the transmission shaft 415. When the clamp support frame 402 (
Still referring to
In this manner, the tray assembly 332 may move downward from a stacking position (a raised position) to a conveyance position (a lowered position), and at the same time, the first gripping conveyance means lowers with the tray assembly 332 while the sheet bundle on the tray is gripped by the upper clamper 403 and the lower clamper 404 (
The second gripping conveyance means 420 turns the sheet bundle received at a substantially horizontal posture from the first gripping conveyance means 401 approximately 90 degrees so that the sheet bundle is vertical, then moves to the processing position of a next process. For that reason, the second gripping conveyance means 420 is disposed on the right and left side frames F1 and F2 at a position adjacent to the tray assembly 332, as shown in
Main clamper 421 and the sub-clamper 422 are turnably mounted to the apparatus frames F1 and F2 to turn after gripping the sheet bundle to change the sheet bundle to a vertical posture.
Guide rails 428 are disposed in a pair, in up and down directions on the right and left side frames 423a and 423b. Movable side frames 429 are mated to these guide rails 428. The main clamper 421 and the sub-clamper 422 are mounted to the movable side frames 429. A fixed clamper 421a that composes the main clamper 421 is fastened to the left and right movable side frames 429, and the main clamper 421a is mounted to a rod 431 that fits in the bearing 430. A rack 432 is provided on the rod 431, and the pinion 433 connected to the drive motor M6 (
The movable side frame 429 is provided in greater detail in
The following will describe the structure of the sub-clamper 422. In the state where the sheet bundle is handed over from the first gripping conveyance means 401, shown in
As shown in
A stock spring 453 is interposed between the mounting shaft 451 and the mounting seat 452. As shown in
This lock claw 456 is equipped on the sub-clamper 422b side, and is configured to engage and separate from the engaging groove 457 formed on the bracket 450 on the main clamper 421b side. When engaged, the sub-clamper 422 checks rotation around the shaft 451 using detection sensor 451 for detecting the clamped state.
The drive motor M6 (
Specifically,
Individual drive means are not used for the clamping action of the main clamper 421 and the sub-clampers 422a and 422b. Rather, the clamping action of the main clamper 421 executes the clamping action of the sub-clampers 422a and 422b. For the structure to enable that, the sub-clampers 422a and 422b are mounted to each of the main clampers 421 that are capable of approaching and separating from each other, interposed by the spring 453. With the approaching action of the main clampers 421, the sub-clampers 422a and 422b nip the sheet bundle, then the main clampers 421 grip the sheet bundle while the action of the spring 453 urges.
Conversely, to release, the main clampers 421 withdraw from the sheet bundle, and the sub-clampers 422a and 422b also withdraw from the sheet bundle. Then, the main clampers 421 release the sheet bundle and while the sub-clampers 422a and 422b are gripping the sheet bundle, they rotate around the shaft 451 when the main clampers 421 release the sheet bundle. The sub-clampers 422a and 422b simultaneously maintain the sheet bundle posture without rotating when the main clampers 421 are gripping. A positioning member 436 (
The sheet bundle SB is gripped by both the main clampers 421 and sub-clampers 422 in the state 15A1, and the sheet bundle SB received at a substantially horizontal posture from the first gripping conveyance means 401 is rotated approximately 90 degrees to be substantially vertically oriented.
Next, 15A2 and 15B2 refer to an operation state wherein the drive motor M6 operates to shift each clamper from a first gripping position to a slightly loosened second gripping position. At this time, the main clamper 421 is positioned at a non-engaged releasing position from the sheet bundle SB, and the sub-clampers 422 are positioned at an operating position where they grip the sheet bundle SB. Therefore, the sheet bundle SB separates from the main clampers 421 and is supported by the springs 454 and 455. The sheet bundle SB is then in a state near a processing position under its own weight.
Next, 15A3 and 15B3 refer to an operation state wherein the drive motor 7 (see
Next, 15A4 and 15B4 illustrate a state wherein the sheet bundle SB and main clampers 421a and 412b touching the reference member. At that time, the drive motor M6 rotates in the gripping position and the movable gripper grips the sheet bundle. Therefore, in the state of 15A4 and 15B4, the sheet bundle SB is securely gripped by the main clampers 421a and 421b and the sub-clampers 422a and 422b (
The following will explain the operations of each unit according to the states shown from S1 to S11 in
The movable support unit 305b and pressing piece 323 are preset at positions where sheets can be securely aligned in the width direction by the aligning means 314 with the leading edge of the sheet hanging downward to form a bend in the sheet S, and the rotating shaft 313 can securely execute the operation to convey the leading edge of the sheet S to a first aligning member 311.
Sheet S is conveyed from the sheet supply path 203, and at that time, the sheet is guided by the guide member 312 to the fixed support unit 305a positioned above the discharge outlet 304. The rotating shaft 313 idles above the tray, and the aligning members 315a and 315b idle at the outer side in the direction of sheet width. Then, at S2, as the sheet advances into the tray, the rotating shaft 313 lowers to a position to touch the sheet on the tray, and helps the sheet advance into the tray by rotating in the clockwise direction. At S3, the rotating shaft 313 rises as the leading edge of the sheet advances into the tray. The guide member 312 moves to a position to guide the sheet along the top of the tray, shown in the drawing.
Next, the rotating shaft 313 lowers to a position to touch the sheet on the tray, and rotates in reverse in a counterclockwise direction to move the trailing edge of the sheet (the right side of the drawing) toward the first aligning means 311. The guide member 312 guides the sheet. At the state of S5 in the drawing, after an estimated amount of time for the leading edge of the sheet to arrive at the first aligning means 311, the rotating shaft stops. At S6, the guide member 312 retracts above the tray, and at S7, the rotating shaft 313 retracts in an upward direction.
In this state, the sheet is supported by the fixed support unit 305a and movable support unit 305b of the tray. The sheet is placed in a free state, other than by being pressed by the pressing piece 323. At state S7 (
Repeating the steps of the operations from S1 to S11 for each sheet S stacks sheets from the discharge outlet 304 onto the tray means. At this time, the trailing edge of the stacked sheets are at the first aligning means 311 and the left and right sides of the sheets are positioned and aligned at the left and right aligning members 315a and 315b so the sheets are neatly stacked. In this way the pages of a series of sheets are stacked in page order, and upon receiving an end signal from the image printing unit A, the stacking process is completed.
Next, the inserter unit B uses a stack conveyance mechanism unit to convey the sheet bundle to the next process.
Next, T5 to T8 of
The second gripping conveyance means 420, composed of the main clampers 421 and the sub-clampers 422a and 422b, idles at the T6 position. The first gripping conveyance means 401 moves in the direction of the arrows in the drawings from the T6 position, and conveys the sheet bundle on the tray assembly 332 toward the second gripping conveyance means 420. The channel-shaped guide rail 402 is guided along a guide rail 408 for the first gripping conveyance means 401 and moves by the drive motor M1 that meshes with the rack 434.
Next, the sheet bundle is conveyed from the tray assembly 332, and the first gripping conveyance means 401 stops at the T7 state. The reverse rotation of the drive motor M3 starts raising the tray assembly 332 toward the raised position. Simultaneous to this, the drive motor M6 (see
Then, as shown at T8, the tray assembly 332 recovers to its raised position, and the sheet bundle is gripped by the second gripping conveyance means 420. The first gripping conveyance means 401 starts recovery movement in the direction of the arrow in the drawing. The lower clamper 404 lowers from the state of T9, where it was gripping the sheet bundle simultaneously with the second gripping conveyance means 420 to separate from the sheet surface (the state of T10) for this recovery movement. Next, at T11, the upper clamper 403 rises to separate from the sheet surface, and moves to its initial state of T12.
At the same time as the releasing action of the clampers, the first gripping conveyance means 401 recovers in the horizontal direction from the state of T8 to the state of T13, and then recovers to a vertical direction at T14.
Along with the recovery operation of the first gripping conveyance means 401, the second gripping conveyance means 420 rotates in the clockwise direction with the drive motor M5 in the state shown in
Then, the drive motor M6 (
Next, the drive motor M7 rotates to lower the movable side frame 429 a predetermined amount, as shown in
Adhesive Application Unit
As shown in
As shown in
The movable side frame 429 mounted with the main clampers 421a and 421b and sub-clampers 422a and 422b (hereinafter referred to as the clamper members 420) is configured to move in a vertical direction guided by the guide rail, as described above. The movable side frame 429 is connected to a drive motor M7 interposed by a rack 434 and pinion 435. (See
The following will explain the adhesive dispensing method by the adhesive application unit E to the sheet bundle SB in this configuration, with references to
To explain the adhesive method based on
Next, U3 illustrates the drive motor M7 operating to lower the clamper members 421 a predetermined amount from an idling position (U1). The drive motor M7 is composed of a stepping motor for the movement amount of the clamper members. The movement amount is controlled by controlling the motor pulse from the initial position (home position) of the clamper members 420. Of particular note, in the outward path of the adhesive application unit E, the bottom side edge S1 of the sheet bundle and the surface (the outer circumference) of the adhesive roll 62 are touching each other. Specifically, the clampers 420 lower to a position where the bottom edge S1 of the sheet bundle overlaps the adhesive roll 62 fastened on the adhesive tray slidably supported on the guide rail 66.
This overlap amount is set according to the pressing force of the sheet edge and adhesive roll. The pressing force between the two is set to deform and open the sheet edges and allow adhesive to be applied between the sheets. The overlap amount in the outward path of the adhesive application unit E is preset, but it is acceptable to vary the overlap amount according to the thickness of the sheet bundle. In such a case, the overlap amount should be made greater as the thickness of the sheet bundle increases, to increase the pressing force. Note that sheet thickness detection will be described below.
With the positional relationship between the sheet bundle and the adhesive roll, the adhesive roll 62 moves from one end of the sheet bundle (the right end) to the other end thereof. The adhesive roll 62 rotates in the direction of the arrow in the drawings. The adhesive roll 62 and the adhesive application unit E stop when the adhesive roll 62 reaches the other end (left end) of the sheet bundle in the state of U4. Then, the clamp member 420 of the second gripping conveyance means rises to return to its home position (see the state of U5 in
The adhesive application operation forms an adhesive layer having a uniform thickness on the sheet bundle edge at the same time as applying adhesive between the sheets by forming a gap between the sheet bundle edge and the adhesive roll after the adhesive application operation. Because an excessive amount of adhesive adheres to the left and right edges of the sheet bundle edge, it is necessary to process the edges.
U7 shows the processing of the sheet bundle edges. After applying adhesive in the outward and return passes, the adhesive application unit E returns to the sheet bundle edges to remove the excess adhesive layer. A knife edge roll reduces the layer of adhesive at the edges. Next, the adhesive application unit E moves to the other end to remove excessive adhesive at that other end. The adhesive application unit E completes the application of adhesive with the above operations and returns to its home position (the states of U11 and U12), and grips the sheet bundle accordingly. The clamper members 420 also return to their home position.
Note that this explanation has focused on forming a minimum gap (without any contact between the sheet bundle bottom edge and adhesive roll) between the sheet bundle bottom edge S1 and adhesive roll surface for the adhesive dispensing operation in the return path of the adhesive application unit E. However, it is also acceptable for both the sheet bundle bottom edge S1 and adhesive roll surface to be in contact with less contact pressure than that of the outward path. In that case, the adhesive application unit E can apply adhesive between the pages of sheets at the outward path, and form a substantially uniform adhesive layer on the edge surface (the back portion) of the sheet bundle at the return path.
Cover Sheet Conveyance Mechanism
Referring to the system shown in
This second path 200 is configured by an upper conveyance guide 63 and lower conveyance guide 64 that oppose each other at a predetermined gap in up and down directions. The upper conveyance guide 63 is separated into a first upper conveyance guide 63a at the right side and a second upper conveyance guide 63b at the left side. These left and right side conveyance guides are configured to open separately. A joining stage 150 (
A first aligning means 130 for positioning a cover sheet supply direction; a second aligning means 135 for positioning a cover sheet supply right angle direction; and an offset conveyance means 140 for feeding a cover sheet aligned by the first and second aligning means 130 and 135 to the joining stage 150 (
An aligning unit 75, (
Specifically, a guide rail, not shown, is equipped on the fixed frame 76, and the aligning unit 75 matingly moves on this rail. A stepping motor M12 (
As shown in
A reverse rotating roller 68 (
Also, as shown in
Then, the reverse rotation rollers 68 lower to a position to engage the sheet (U4) and at the same time, all conveyance rollers engaged with the sheet retract to a position upward from the sheet (U5). The reverse rotation rollers 68 are driven to move the sheet in a direction opposite to the supply direction. At this time, the stoppers 72 assume a standing position by the operation solenoid SOL. Then, the trailing edge of the sheet engages the stoppers 72. Immediately thereafter, simultaneously with the stopping of the reverse rotation rollers 68, the rollers are separated from the sheet. Note that the timing for stopping the reverse rotating rollers 68 is calculated using a signal generated where the sensor S71 detected a trailing edge of the sheet.
Then, the power to operate solenoid SOL is cut to allow the stoppers to return to their initial posture (U7). Then, the trailing edge of the sheet is nipped by the step portion (plate) 75a of the aligning unit 75 and the stoppers 72. In this state, when the drive motor M12 is started, the aligning unit 75 moves in a direction that is orthogonal to the sheet supply direction, and moves to the sheet nipped by the stoppers 72 at the same time.
As shown in
Referring now to
Referring to
The swing arm 83 is connected to a transmission gear 85a connected to a drive motor M14 that drives a gear 85 of the pivot unit. The rotation of the motor is operable to control the elevating position of the conveyance guides and conveyance rollers. Note that the drive motor M14 controls the angle of the swing arm 83 at two stages to position the conveyance rollers at a non-operating position slightly retracted from the sheet and the upper conveyance guide at a position greatly separated from the lower conveyance guide. The number 84 represents the recovery spring of the swing arm in the drawings. The conveyance rollers 69b, having the same structure as the conveyance rollers 69, are mounted to the second conveyance guide 63b by the support stays 82b, and this support stay is rockingly supported by the swing arm 83. However, the swing arm 83, positioned at a left side (a downstream side) of the joining stage is configured to rotate in a direction opposite to that of the swing arm 83 positioned on the right side, and the arm rotates with the drive motor M15.
The conveyance rollers 69 of this configuration are connected to the drive motor M13 and controlled by a control CPU, not shown. The control CPU executes the second aligning action that aligns a width direction that is orthogonal to a sheet supply direction of the cover sheet positioned by the stoppers 72. After that is completed, the CPU starts the drive motor M14 to lower the conveyance rollers 69 to a position where they touch the sheet, and then starts the drive motor M13 to convey the cover sheet a predetermined amount toward the joining stage 150 (
To control the conveyance rollers 69, the control CPU calculates the cover sheet size (the length in the conveyance direction) and the conveyance amount to match the center of the sheet from the thickness of the sheet bundle conveyed from the first path 100 and the center of the joining stage. The CPU then calculates the number of steps required to drive motor M13. Motor M13 comprises a stepping motor, and based on those calculations supplies power pulses thereto. In this case, either a calculation of the conveyance amount is selected using only the length of the sheet, or a calculation of the conveyance amount is selected using the sheet length and the thickness of a sheet bundle from the first path.
The former calculation does not require detection of the sheet bundle thickness, and it is easier to calculate the conveyance amount, but if the thickness of the sheet bundle differs, the edges of both the cover sheet and sheet bundle will be different when folding them together. Accordingly, the former calculation is best suited to apparatus specifications that require uniform thickness. Although the latter method allows for the possibility of misalignment based upon the detection accuracy of the sheet bundle, this method is suited to apparatus specifications that require bookbinding of a variety of thicknesses. It is also possible to apply a sheet bundle thickness detection method for adjusting the contact pressure such as when gluing as described above for detecting the thickness of a sheet bundle. The conveyance rollers 69 and their controlling means (such as a control CPU as described above) compose the offset moving means.
Joining Mechanism of the Sheet Bundle and Cover Sheet
A joining stage 150 (
The following will simultaneously explain the structure and operation for joining the sheet bundle and cover sheet, according to
A drive motor M15 rotates to retract the reference member 437 from the first path that is integrally formed with the guide, when the second upper conveyance guide 64 is freed when in the state of W2 in the drawing. By driving a drive motor M16 to drive the second gripping conveyance means (hereinafter referred to as the main clamper 421), the sheet bundle is conveyed to a downstream side. When the cover sheet CS and sheet bundle SB are joined in the state of W3 in the drawing, the backup member 151 is supporting the cover sheet back surface. There is a gap formed between the backup member 151 and the bottom conveyance guide. The back folding block 155 advances into this gap.
Next, the first upper conveyance guide 63a separates from the bottom conveyance guide 64a in the same way as the second conveyance guide earlier. The upper side of the cover sheet CS is freed at W4. With the cover sheet free, the cover sheet is folded by the back folding block 155 at W5. This back folding block 155 is configured to open freely to press the sheet bundle shoulders from the position of W4 where the right and left sides of the pair of blocks are separated, and press to form the back of the booklet along with the backup member 151.
Next, the back folding block 155 recovers to its original position from the shoulders of the sheet bundle (W6), and then the main clamper 421 releases from the sheet bundle S. (W7) After releasing, the main clamper 421 retracts to an upstream side of the first path (W8), and the main clamper 421 grips the sheet (W9). Therefore, the main clamper 421 grips the bottom edge of the sheet bundle when joining with the sheet bundle (the operations from W1 to W5), and then grips the central portion of the sheet bundle. In this way, gripping the bottom edge when joining the sheet bundle and cover sheet prevents the sheet bundle from coming apart by the pressure to acts to join the sheets.
After changing the position that the main clamper 421 grips the sheet bundle, and backing up the main clamper 421, the cover sheet is pulled from the backup member 151 (W10). The retracting action of the clamper is pulse controlled by the drive motor M7. After pulling the cover sheet CS, the backup member 151 retracts from the first path to the state of W11.
Folding conveyance means are equipped on the first path at a downstream side of the joining stage 150. The drawings show this configured by a pair of folding rollers 160 (
At W17, after the trailing edge of the sheet bundle passes the joining stage 150 at the recover operation of the main clamper 421, a sensor transmits a signal of the detection of the trailing edge of the sheet bundle, and the second gripping conveyance means 420 including the main clamper 421 convert its posture 90 degrees to recover to the posture to receive the next sheet bundle. Simultaneously to this, the first and the second upper conveyance guides also recover to their original position to convey the next cover sheet.
At W18 and W19, the folding rollers 160 recover from a pressed state to a separated state. At W20, the backup member 151 and the back folding block 155 both recover to their original positions. In this way, the sheet bundle formed into a booklet is conveyed from the folding conveyance means to a trimming unit where edges in three directions, excluding the glued and bound edge are cut, and the finished sheet bundle is stored in a storing stacking tray.
While the invention has been explained with reference to the specific embodiments of the invention, the explanation is illustrative and the invention is limited only by the appended claims.
Number | Date | Country | Kind |
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2005-175646 | Jun 2005 | JP | national |
This is a continuation application of Ser. No. 11/452,908 filed on Jun. 15, 2006. The present application claims priority to Japanese Patent Application No. 2005-175646 and hereby incorporated by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
5678813 | Osako et al. | Oct 1997 | A |
20050238462 | Oota | Oct 2005 | A1 |
Number | Date | Country | |
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20110002755 A1 | Jan 2011 | US |
Number | Date | Country | |
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Parent | 11452908 | Jun 2006 | US |
Child | 12805075 | US |