JP2004305879A - Adhesive coating apparatus and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact low cost adhesive coating apparatus capable of preventing a coated adhesive from lacking at the time of movement of a sheet bundle after adhesive coating treatment to consequently certainly bond a cover to the sheet bundle, and an image forming apparatus. <P>SOLUTION: This adhesive coating apparatus is equipped with support means 55a and 55b for supporting the sheet bundle S1, a coating means 66 for applying an adhesive to the end edge of the sheet bundle S1 supported by the support means 55a and 55b and a feed means for feeding the sheet bundle S1 so that the leading edge coated with the adhesive by the coating means 66 becomes the head. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an adhesive applying apparatus for applying an adhesive to a sheet bundle and an image forming apparatus.
[0002]
[Prior art]
For example, a sheet processing apparatus such as a finisher attached to a bookbinding machine or an image forming apparatus generally processes a plurality of sheets into a bundle and binds the sheet bundle, or an adhesive such as glue on an edge of the sheet bundle. For example, to apply an adhesive.
[0003]
In the adhesive application processing, for example, after applying an adhesive to an edge of the sheet bundle, the sheet bundle is conveyed in a direction along the edge, and then the sheet bundle and the cover are separated in a direction orthogonal to the conveyance direction. The relative movement causes the cover to adhere to the edge of the sheet bundle to which the adhesive has been applied (for example, see Patent Document 1).
[0004]
[Patent Document 1]
JP 2000-168264 A
[Problems to be solved by the invention]
By the way, when the adhesive is applied to the edge of the sheet bundle and then the sheet bundle is conveyed in a direction along the edge, when the applied amount of the adhesive increases, or when the sheet bundle is inclined. When the sheet is conveyed, the edge of the sheet bundle being conveyed comes into contact with various members including the side wall of the conveyance path, whereby the adhesive applied to the edge of the sheet bundle is scraped off. There is a possibility that such a trouble as that may occur.
[0005]
As described above, if the adhesive is scraped off from the edge of the sheet bundle while the sheet bundle is being conveyed, the sheets constituting the sheet bundle may not be able to be completely adhered to each other by the adhesive, and furthermore, the adhesive may be further removed. The shortage of the agent causes a problem that the sheet bundle and the cover cannot be sufficiently bonded to each other. Further, there is also a problem that the adhesive adhered to the side wall of the transport path hinders the subsequent transport of the sheet bundle.
[0006]
Therefore, in order to avoid such a problem, conventionally, a sufficient space is secured between the edge of the sheet bundle to which the adhesive is applied and the conveyance path, and the amount of the adhesive applied is strictly controlled. Although some measures have been taken to provide special equipment, the size and cost of the apparatus have been increased, and improvements have been required.
[0007]
The present invention has been made in view of such a current situation, and an object of the present invention is to remove the applied adhesive when the sheet bundle is moved after the adhesive application processing, and as a result, the cover Is to provide a compact and low-cost adhesive application apparatus and an image forming apparatus which can be stuck to a sheet bundle reliably.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the adhesive applying device according to claim 1, wherein a supporting means for supporting a sheet bundle and an applying means for applying an adhesive to an edge of the sheet bundle supported by the supporting means. And conveying means for conveying the sheet bundle with the edge on which the adhesive is applied by the applying means leading.
[0009]
According to the first aspect of the present invention, since the sheet bundle is conveyed starting from the edge on which the adhesive is applied, it is not necessary to secure a particularly large space for the conveyance path. Even if a special device for strictly controlling the amount of the adhesive applied is not provided, the edge of the sheet bundle does not come into contact with the transport path when the sheet bundle is moved, so that the adhesive is not scraped off. Therefore, each sheet constituting the sheet bundle can be securely bonded to each other, and the sheet bundle and the cover can be sufficiently bonded without causing an increase in the size and cost of the apparatus. There is no problem that the adhesive adhered to the side wall of the path hinders conveyance of the subsequent sheet bundle.
[0010]
Further, the adhesive applying device according to the second aspect of the present invention includes a supporting means for supporting a sheet bundle, an applying means for applying an adhesive to an edge of the sheet bundle supported by the supporting means, and A cover sheet supply unit to be set at a position, and transporting the sheet bundle with the edge to which the adhesive is applied by the application unit leading, and the edge of the sheet bundle to the cover sheet set at the predetermined position. And conveying means for pressing the same.
[0011]
According to the second aspect of the invention, not only the same operation and effect as the first aspect of the invention can be obtained, but also when the sheet bundle is conveyed by a rotating body such as a roller (during conveyance). 2) can be corrected when pressing the edge of the sheet bundle toward the cover sheet.
[0012]
According to a third aspect of the present invention, in the second or third aspect, a first position at which an adhesive is applied to an edge of the sheet bundle and a sheet bundle formed by the conveying means are provided. Moving means for moving the applying means to a second position which does not hinder the conveyance of the coating means.
[0013]
According to the invention described in claim 3, the same operation and effect as the invention described in claim 1 or 2 can be obtained, and the sheet bundle is not moved so as to avoid the application unit. By moving the application unit, a conveyance path of the sheet bundle to which the adhesive has been applied can be secured, so that the coated sheet bundle is unlikely to shift during conveyance.
[0014]
Further, according to the invention described in claim 4 or claim 5, in the invention described in claim 2, the transporting means is configured to hold the sheet bundle or at a rear end in the transport direction of the sheet bundle. A grip member is provided which conveys and pushes the sheet bundle to the cover set at the predetermined position in the engaged state.
[0015]
According to the invention described in claim 4 or 5, the same operation and effect as the invention described in claim 2 can be obtained, and the sheet shifted in the transport direction when the sheet bundle is transported by the transport unit. Even when the sheet bundle is pressed, the sheet bundle is securely pressed against the cover in a state where the sheet bundle is sandwiched or engaged with the rear end of the sheet bundle in the transport direction, so that the sheet displaced in the transport direction at the time of pressing is corrected. Meanwhile, the sheet bundle can be adhered to the cover.
[0016]
According to a tenth aspect of the present invention, there is provided a support means for supporting a sheet bundle in a state of standing substantially vertically, and a lower end of the sheet bundle provided below the support means and supported by the support means. Applying means for applying an adhesive to an edge; a first position for applying an adhesive to a lower edge of the sheet bundle; and a second position for preventing the sheet bundle from being conveyed by the conveying means. It is characterized by comprising moving means for moving, and conveying means for conveying the sheet bundle downward with the edge on which the adhesive has been applied by the applying means leading.
[0017]
According to the tenth aspect, the same function and effect as those of the first aspect can be obtained, and in particular, as set forth in the eleventh aspect, provided below the coating means. If it is provided with a cover supply means for setting the cover in a predetermined position, the sheet bundle is conveyed toward the lower cover with the edge applied with the adhesive at the top, so that the adhesive is Even if it hangs down, it is caught on the cover and there is no danger that the adhesive will adhere to other parts of the device and cause problems.
[0018]
Further, according to the present invention, there is provided an image forming apparatus having the above features.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a sheet processing apparatus 20 in which an adhesive application apparatus according to an embodiment of the present invention is incorporated, and a copying machine 1 which is an example of an image forming apparatus including the sheet processing apparatus 20. I have.
[0020]
As shown in the figure, an image forming unit 3 is provided in the apparatus main body 2 of the copying machine 1, and an image is formed on a sheet such as plain paper or an OHP sheet by the image forming unit 3. More specifically, a document feeder 5 is mounted on the upper surface of the apparatus main body 2, and a document automatically fed from the document feeder 5 is optically read by an optical reading unit 7, and the read information is read. Is transmitted to the image forming unit 3 as a digital signal. In the image forming unit 3, a laser beam L is radiated from the light irradiating unit 13 to the surface of the photosensitive drum 15 based on the digital signal, whereby an electrostatic latent image corresponding to the document is formed on the surface of the photosensitive drum 15. Formed. Subsequently, by the rotation of the photosensitive drum 15, toner is supplied to the electrostatic latent image from the developing device 8 disposed around the photosensitive drum 15, and the electrostatic latent image is visualized. The visualized toner image is then transferred to the sheet S sent to the transfer unit at a predetermined timing. The sheet S to which the image is to be transferred is sent one by one from the sheet cassette 9 mounted on the lower portion of the apparatus main body 2 to the transfer unit by the transport roller 10. Of course, feeding from the multi tray 12 is also possible.
[0021]
The sheet S to which the toner image has been transferred by the transfer unit is then conveyed to the fixing device 6, where the toner image is permanently fixed by applying heat and pressure. When the one-sided mode is set in the apparatus main body 2, the sheet S that has passed through the fixing device 6 is sent to the sheet processing device 20. On the other hand, when the duplex recording mode is set in the apparatus main body 2, the sheet S on which an image is formed on one side is first conveyed to the re-conveying path 18 by switchback after passing through the fixing device 6, The sheet is again conveyed to the image forming unit 3 to form an image on the back surface, and then is sent to the sheet processing apparatus 20.
[0022]
Note that the apparatus main body 2 sends a signal such as a sheet size to the sheet processing apparatus 20 so that the conveyance path in the sheet processing apparatus 20 can be switched in advance before the sheet S is sent to the sheet processing apparatus 20. Is to be sent.
[0023]
The sheet processing apparatus 20 includes at least a transport aligning unit 21 that transports and aligns the sheet S, an adhesive application unit 22, and a cutting unit 23. In addition to a normal discharge mode, an adhesive binding mode and a cutting mode Can be selected. The cutting in the cutting mode can be performed in three directions other than the bonding surface of the sheet bundle S1 described later.
[0024]
The transport aligning unit 21 includes a first transport path A that transports the sheet S carried in from the apparatus main body 2, second and third transport paths B and C that branch off from the first transport path A, and Fourth and fifth transport paths D and E branching from the third transport path C into two branches.
[0025]
As shown in detail in FIG. 2, a carry-in roller pair 25 is provided in the first carry path A, and a second carry path B and a third carry path are provided downstream of the carry-in roller pair 25. A first switching flapper 27 for switching the transport path is provided at a branch point with C. In addition, a second switching flapper 32 for switching the transport path is provided at a branch portion between the fourth transport path D and the fifth transport path E.
[0026]
In such a configuration of the transport path, when the normal discharge mode is selected on the apparatus main body 2 side, the sheet S carried into the sheet processing apparatus 20 from the apparatus main body 2 through the first transport path A is the first sheet S. Is guided to the second transport path B by the switching flapper 27, and is discharged to the stack tray 30 (see FIG. 1) via a plurality of pairs of transport rollers 29 provided in the second transport path B. On the other hand, when the bookbinding mode is selected on the apparatus main body 2 side, the sheet S is guided to the third conveyance path C by the first switching flapper 27, and then is guided to the fourth switching flapper 32 via the second switching flapper 32. After being guided to the transport path D or the fifth transport path E, and bound and bound (for example, bound by gluing) via the adhesive application section 22 and the cutting section 23, the stacking tray 35 (FIG. 1) See). Note that, in FIG. 2, the arrow X indicates the transport direction of the sheet S other than the cover S0 (see FIG. 8).
[0027]
In the third and fourth conveying paths C and D, pairs of conveying rollers 40a, 40b and 40c for conveying the sheet S are arranged in order. At a predetermined position between the pair of conveying rollers 40b and 40c, a first rear end detection sensor 50 for detecting the rear end of the sheet S and a second rear end detection sensor 51 are sequentially installed from the upstream side. ing.
[0028]
Further, downstream of the fourth transport path D, an accumulating unit 42 that forms an alignment area of the transport alignment unit 21 is provided. The stacking unit 42 includes a back plate 42a that receives the sheet S from the back surface thereof, and a reference plate (mounting plate) 45 that receives the edge (lower edge) of the sheet S from below. , 45, a predetermined number of sheets S are stacked in a substantially vertical state to form one sheet bundle S1. In this case, the back plate 42a can be slid in the stacking direction of the sheets S (substantially horizontal direction (thickness direction of the sheet bundle S1) indicated by an arrow Y1 in FIG. 2) by a slide mechanism (not shown), and a rack (not shown). Is fixed at an arbitrary slide position. Further, the reference plate 45 opens a stacking position (a position indicated by a solid line in FIG. 2) for supporting the sheets S (the sheet bundle S1) stacked on the stacking unit 42 from below, and opens a lower side of the stacking unit 42. The stacking direction of the sheets S (substantially the horizontal direction indicated by the arrow Y2 in FIG. 2 (thickness of the sheet bundle S1) between the retracted position (the position indicated by the broken line in FIG. 2) for releasing the support state of the sheets S )).
[0029]
The stacking unit 42 is provided with a pressing arm 52 for pressing the sheet S against the back plate 42a so as to be rotatable about a rotation shaft 52a. In addition, a stacking roller 43 that can be rotated forward and backward is disposed in the stacking unit 42 so as to face the back plate 42a. The stacking roller 43 is supported at one end of an arm 46 rotatably supported by a rotation shaft 46a. When the arm 46 rotates, the stacking roller 43 protrudes into the fourth conveyance path D and is attached to the back plate 42a. The sheet S is nipped and conveyed between the driven roller 43a provided.
[0030]
In addition, a caterpillar belt 48 for scraping is provided below the stacking roller 43 to convey the sheet S stacked on the stacking unit 42 toward the reference plate 45 in cooperation with the stacking roller 43. I have.
[0031]
In addition, a sheet bundle S1 stacked substantially vertically on the stacking unit 42 is held below the back plate 42a, and the sheet bundle S1 is kept substantially vertically (with the edge of the sheet bundle S1 being the leading edge). D) A pair of grippers (supporting means) 55a and 55b are provided as grip members for moving downward toward the adhesive application section 22 and the cutting section 23. These grippers 55a and 55b move in a substantially vertical direction between a holding position for holding the sheet bundle S1 between the back plate 42a and the reference plate 45 and a delivery position for transferring the sheet bundle S1 to the cutting device ( Lifting operation). The grippers 55a and 55b are substantially horizontally moved between the closed position (position shown in FIG. 2) for holding the sheet bundle S1 from both sides (the position shown in FIG. 2) and the open position for releasing the holding state of the sheet bundle S1 (the sheet bundle S1). Thickness direction). In the case of the present embodiment, the movement (opening / closing operation) between the open position and the closed position is performed by moving one slide gripper 55b with respect to the other fixed gripper 55a.
[0032]
The stacking section 42b is also provided with a sheet detection sensor 16 for detecting the presence or absence of the sheet S in the stacking section 42.
[0033]
Next, the case where the sheets S are stacked by the stacking unit 42 having the above-described configuration to form the sheet bundle S1 will be described.
[0034]
First, when the bookbinding mode is selected on the apparatus main body 2 side, the sheets S discharged from the apparatus main body 2 sequentially pass through the first conveying path A via the carry-in roller pair 25 and the first switching flapper 27. After being guided to the third transport path C, the sheet is guided from the fourth transport path D to the stacking unit 42 via the second switching flapper 32. When the rear end of the sheet S is detected by the first rear end detection sensor 50, the arm 46 is rotated, and the stacking roller 43 protrudes into the fourth conveyance path D and faces the driven roller 43a. At this time, the loading roller 43 rotates forward and feeds the sheet S to the back plate 42a while nipping the sheet S with the driven roller 43a. When the rear end of the sheet S is detected by the second rear end detection sensor 51, the stacking roller 43 starts to reversely rotate at a predetermined timing, whereby the sheet S whose back surface is supported by the back plate 42a is The stacking roller 43 and the caterpillar belt 48 rotate in the reverse direction, and are moved toward the reference plate 45. That is, the sheet S conveyed to the stacking unit 42 is once sent to and held by the back plate 42a, then pulled back toward the reference plate 45, the rear end thereof is applied to the reference plate 45, and the sheet S is conveyed in the conveyance direction. Matching (rear end matching) is performed. Hereinafter, the portion of the sheet bundle S1 formed by the trailing edge of the sheets S to be aligned is referred to as “the edge of the sheet bundle”.
[0035]
In this manner, each time the sheet S is stacked on the reference plate 45 (the rear end of the sheet S abuts on the reference plate 45), the pressing arm 52 rotates about the rotation shaft 52a. Then, the sheet S is pressed against the back plate 42a. The pressing force by the pressing arm 52 eliminates a gap between the sheets S, forms an appropriate sheet bundle S1, and slides the back plate 42a together with the sheet bundle S1. Then, the slide position of the back plate 42a is held by the rack mechanism, so that a stacking space for the next sheet S is secured. That is, as the number of sheets S stacked on the stacking unit 42 increases (in accordance with the thickness of the sheet bundle S1), the pressing arm 52 slides the back plate 42a to form the sheet bundle S1 with good alignment. To contribute.
[0036]
As described above, the sheets S are sequentially fed to the stacking unit 42 and a predetermined number of sheets S are stacked (a sheet bundle S1 having a predetermined thickness is formed), that is, the back plate 42. Is slid by a predetermined amount, the back plate 42a comes off the rack, is urged by an elastic member (not shown) and is moved toward the stacking roller 43, and pinches the sheet bundle S1 with the stacking roller 43. In the above-described configuration, the sheet S is conveyed to the stacking unit 42 to form the sheet bundle S1, but a predetermined number of sheet bundles are conveyed to the stacking unit 42 and stacked to form a sheet of a predetermined thickness. One sheet bundle S1 may be formed.
[0037]
The sheet bundle S1 thus formed is then held by the grippers 55a and 55b waiting at the open position and moved toward the adhesive application section 22. Although not shown in FIG. 2, the adhesive application section 22 is provided between a reference sheet 45 and a cover adhesive section 60 described below provided downstream of the fifth transport path E (FIG. 1). reference).
[0038]
Here, the grippers 55a and 55b and the driving mechanism thereof will be described in detail.
[0039]
As shown in FIGS. 15 and 16, the grippers 55a and 55b extend in the width direction of the sheets S stacked on the stacking unit 42, and are attached to the pair of gripper units 87 and 88. As shown in detail in FIGS. 3 and 4, each gripper unit 87, 88 has a base plate 87a, 88a, one end of a fixed gripper 55a is connected to one first base plate 87a, and the other first base plate 87a is connected to the other first base plate 87a. The other end of the fixed gripper 55a is fixed to the second base plate 88a. The slide gripper 55b has racks 96a, 96b at both ends thereof, and the racks 96a, 96b are slidably attached to guide rails 87b, 88b of the base plates 87a, 88a, respectively.
[0040]
A gripper opening / closing motor 70 is fixed to the second base plate 88a, and a motor gear 89 is fixed to an output shaft of the motor 70. A worm gear 90 meshing with the motor gear 89, a first gear 91 meshing with the worm gear 90, a second gear 92 meshing with the first gear 91, and a second gear 92 are formed on the surface of the second base plate 88a. And a third key 93 meshing therewith are rotatably mounted. The gripper opening / closing motor 70 is connected to a CPU 159 as control means (see FIG. 15), and its driving is controlled by the CPU 159.
[0041]
The pair of base plates 87a and 88a support the rotating shaft 61 rotatably therebetween. A one-way gear 94 that meshes with the third gear 93 and a pinion gear 95b that meshes with one rack 96b of the slide gripper 55b are fixed to one end of the rotating shaft 61 supported by the second base plate 88a. On the other hand, a pinion gear 95a that meshes with the other rack 96a of the slide gripper 55b is fixed to the other end of the rotating shaft 61 supported by the first base plate 87a.
[0042]
As described above, the gripper units 87, 88 support the grippers 55a, 55b via the pinion rack mechanism, and operate the pinion rack mechanisms via the gear train by the gripper opening / closing motor 70, thereby causing the grippers 55a, 55b to operate. It constitutes a gripper opening / closing mechanism for opening and closing (a portion indicated by a dashed line (hatched line) in FIG. 3 rising to the right).
[0043]
In the present embodiment, a detecting unit that detects the thickness of the sheet bundle S1 stacked in the stacking unit 42 using such an opening and closing mechanism is provided. As clearly shown in FIG. 6, the detecting means includes an opening amount sensor flag 74b formed on the rack 96a and a gripper opening amount detection sensor 74a provided on the first base plate 87a. The thickness of the sheet bundle S1 sandwiched between the grippers 55a and 55b is detected by detecting the opening amount sensor flag 74b that moves together with the slide gripper 55b) with the gripper opening amount detection sensor 74a. Here, a detection signal detected by the gripper opening amount detection sensor 74a is sent to the CPU 159.
[0044]
In the present embodiment, a safety mechanism for preventing the slide gripper 55b from moving excessively is provided. As shown clearly in FIG. 7, the safety mechanism includes an opening limit detection sensor flag 75b formed on a rack 96b and a gripper opening limit fixed to a mounting plate 67 attached to a predetermined position of a second base plate 88a. And a detection sensor 75a. When detecting the sensor flag 75b that moves with the rack 96b (slide gripper 55b) at the open limit position, the detection sensor 75a sends the detection information to the CPU 159. Then, based on this detection information, the CPU 159 stops driving the gripper opening / closing motor 70, and regulates the further movement of the slide gripper 55b. If such a safety mechanism is provided, the amount of movement of the racks 96a and 96b can be limited to L (see FIG. 8), and it is possible to prevent the slide gripper 55b from being excessively moved and damaged by a malfunction of the motor 70 or the like. .
[0045]
The gripper units 87 and 88 are vertically movably attached to a pair of support plates 84a and 84b fixed to the main body of the sheet processing apparatus 20, for example. Specifically, each gripper unit 87, 88 is slidably engaged with guide rails 85a, 85b provided to extend vertically on the support plates 84a, 84b (see FIGS. 5 and 6). , Are fixed to lifting mechanisms 63a, 63b provided on the support plates 84a, 84b. In this case, the slidable engagement between the gripper units 87, 88 and the guide rails 85a, 85b is attached to the back surfaces of the base plates 87a, 88a of the gripper units 87, 88, as clearly shown in FIGS. It is constituted by a pair of rotatable guide rollers 86a and 86b. In the present embodiment, two pairs of guide rollers 86a, 86b are attached to the upper and lower surfaces of the back surfaces of the base plates 87a, 88a, and the guide rails 85a, 85b are sandwiched between the two rollers forming the pair of guide rollers 86a, 86b. It is.
[0046]
On the other hand, the lifting mechanisms 63a and 63b are composed of a gear pulley 80 and a tension pulley 83 rotatably mounted above and below the support plates 84a and 84b, and an endless drive belt 81 stretched between the pulleys 80 and 83. And a joint 82 fixed to the drive belt 81 and to which the base plates 87a, 88a of the gripper units 87, 88 are fixed. The gear pulleys 80 of the lifting mechanisms 63a and 63b are fixed to both ends of a rotating shaft 64 rotatably supported by support plates 84a and 84b, respectively.
[0047]
A driving force is transmitted to the lifting mechanisms 63a and 63b from the gripper vertical movement motor 69 via a gear train. Specifically, as shown in FIG. 9 and the like, a motor pulley 76 is fixed to an output shaft of the motor 69, and a drive belt 77 is provided between the motor pulley 76 and a gear pulley 78 attached at a predetermined position. Has been passed over. In this case, the tensioner 122 is applied to the drive belt 77, thereby applying a constant tension to the drive belt 77. The gear pulley 78 meshes with a gear 79 rotatably attached to one support plate 84b, and the gear 79 meshes with the gear pulley 80 of the one elevating mechanism 63b, so that the driving force of the motor 69 rises and falls. The driving force is transmitted to the mechanisms 63a and 63b (the driving force is transmitted to the lifting mechanism 63a via the rotating shaft 64). In FIG. 3, the lifting mechanism 63b and its driving mechanism are shown by solid lines (diagonal lines) which are lower right.
[0048]
The lifting operation of the gripper units 87, 88 (grippers 55a, 55b) by the lifting mechanisms 63a, 63b is controlled by the CPU 159 based on the position detection of the gripper units 87, 88. Specifically, as shown in FIG. 7, a vertical sensor flag 73b on the gripper opening / closing motor 70 is detected by a gripper vertical HP sensor 73a installed at a predetermined position on the support plate 84b, and the detection information is transmitted from the sensor 73a. By sending it to the CPU 159, the operation of the gripper vertical movement motor 69 is controlled (see FIG. 15). In the present embodiment, the vertical movement amount of the grippers 55a and 55b is limited to H by such control (see FIG. 8).
[0049]
According to the lifting / lowering / opening / closing mechanism (transporting means) configured as described above, the grippers 55a and 55b perform opening / closing and lifting / lowering operations as described below.
[0050]
First, as described above, when a predetermined sheet bundle S1 is formed in the stacking unit 42, the gripper opening / closing motor 70 is driven by the CPU 159. Thus, the pinion gears 95a, 95b are rotated via the various gears 89, 90, 91, 92, 93, 94 of the opening / closing mechanism, and the racks 96a, 96b meshing with the pinion gears 95a, 95b are indicated by broken lines in FIGS. It moves from the position shown to the position shown by the solid line (moves in the direction opposite to the arrow shown in FIGS. 7 and 8). As a result, the slide gripper 55b waiting at the open position (the position indicated by the broken line in FIG. 6) closes toward the sheet bundle S1, and the sheet bundle S1 is nipped by the grippers 55a and 55b. At this time, the thickness of the sheet bundle S1 sandwiched between the grippers 55a and 55b is detected by the opening amount sensor flag 74b and the gripper opening amount detection sensor 74a that move together with the rack 96a (slide gripper 55b).
[0051]
In this manner, when the sheet bundle S1 is nipped by the grippers 55a and 55b, the reference plate 45 moves from the stacking position (the position indicated by the solid line in FIG. 2) to the retracted position (the position indicated by the broken line in FIG. 2). After the slide, the transport path of the slide bundle S1 is formed. Then, in this state, the gripper vertical movement motor 69 is driven by the CPU 159, and the gripper unit 87, the pulleys and the belts 76, 77, 78, 79, 80, 81 of the driving mechanism and the elevating mechanisms 63a, 63b. The 88 (grippers 55a, 55b) is lowered toward the adhesive application section 22 (see arrows in FIGS. 9 and 10). The elevation control at this time is controlled by the CPU 159 based on the position detection of the gripper units 87 and 88 via the sensor 73a and the flag 73b, as described above.
Next, the adhesive application section 22 will be described in detail with reference to FIGS.
[0052]
The adhesive application unit 22 holds an adhesive b (for example, glue) and an adhesive unit 66 (see FIG. 11) as an application unit that applies the held adhesive b to the edge of the sheet bundle S1. A moving mechanism (moving means) for moving the bonding unit 66 along the edge of the sheet bundle S1 and a roller driving mechanism for rotating and driving an application roller 68b of the bonding unit 66 described later are provided.
[0053]
As shown in FIG. 11, the bonding unit 66 is rotatably supported by, for example, an aluminum container (adhesive container) 66a for storing the adhesive b and the container 66a via an aluminum rotary shaft 68c. A coating unit 68b serving as a rotating body, a heater unit 180 serving as a melting unit that is detachably installed at the bottom of the container 66a, for example, and heats and melts the adhesive b in the container 66a at room temperature, for example. A heat-insulating cover 181 made of a heat-resistant resin that receives the heater unit 66a and the heater unit 180 and insulates them from below and from the side. In this case, the application roller 68b is made of, for example, heat-resistant rubber, contacts the adhesive b in the container 66a and holds the adhesive on the surface, and rotates the adhesive b held on the surface while rotating itself. Apply to the edge of S1. The heater unit 180 is connected to a power supply (not shown).
[0054]
The container 66a is provided with a temperature sensor 71 for detecting the temperature of the adhesive b in the container 66a. The temperature sensor 71 is electrically connected to the CPU 159 as shown in FIG. 15, and sends a detection signal relating to the temperature of the adhesive b to the CPU 159. Further, the CPU 159 controls the supply of current from the power supply to the heater unit 180 based on the detection information from the temperature sensor 71. The power supply line from the power supply to the heater unit 180 is provided with a fuse 200 for preventing overcurrent.
[0055]
12 to 14 show a moving mechanism for moving (sliding) the bonding unit 66 along the edge of the sheet bundle S1, and a roller driving mechanism for rotating and driving the application roller 68b.
[0056]
As shown in FIGS. 12 and 13, the moving mechanism includes a container moving motor 67, a motor pulley 97 fixed to an output shaft of the container moving motor 67, and a first support frame 204 fixed at a predetermined position. A pulley 99 rotatably supported with respect to the pulley, a drive belt 98 stretched between the pulleys 97 and 99, a first gear 100 rotating integrally with the pulley 99, and a second gear fixed at a predetermined position. A second gear 101 rotatably supported by the support frame 206 and meshing with the first gear 100; and a pulley 102 supported by the second support frame 206 and rotated integrally with the second gear 101 And a tension pulley 104 separated from the pulley 102 by a predetermined distance along the moving direction of the bonding unit 66, and a container moving bell bridged between the tension pulley 104 and the pulley 102. And a 103. The container moving motor 67 is electrically connected to the CPU 159, and its driving is controlled by the CPU 159 (see FIG. 15).
[0057]
A joint member 107 is fixed to the container moving belt 103. One end of the joint member 107 supports the bonding unit 66 and is movably supported by a support rod 105 extending along the moving direction of the bonding unit 66. The other end of the joint member 107 is movably supported by a support rail 106 having a U-shaped cross section extending parallel to the support rod 105. In this case, the other end of the joint member 107 is provided with a pair of guide rollers 108 that roll while contacting the upper and lower rail surfaces 106 a and 106 b of the support rail 106. Therefore, the rails 106a and 106b are constantly urged.
[0058]
Therefore, in such a configuration, when the container moving motor 67 is driven by the control of the CPU 159, the container moving belt 103 is rotationally driven via the motor pulley 97, the driving belt 98, the pulley 99, the gears 100 and 101, and the pulley 102. Then, the joint member 107 fixed to the container moving belt 103 slides along the support rod 105 and the support rail 106. In this case, since the joint member 107 moves stably with both ends supported by the support rod 105 and the support rail 106, the bonding unit 66 supported by the joint member 107 can be stably moved straight without rattling. Moving. Therefore, the coating process of the adhesive b described later can be performed accurately.
[0059]
On the other hand, as shown in FIGS. 12 and 14, the roller driving mechanism rotates the coating roller rotation motor 68, the motor pulley 110 fixed to the output shaft of the motor 68, and the first support frame 204. A pulley 112 that is supported so as to be supported, a drive belt 111 that is stretched between the pulleys 110 and 112, a drive gear 113 that rotates integrally with the pulley 112, and that is rotatably supported by a second support frame 206. A driven gear 114 that meshes with the drive gear 113, a pulley 115 that is supported by the second support frame 206 and rotates integrally with the driven gear 114, and is rotatable by the second support frame 206 and the third support frame 208. A pulley 117 fixed to one end of the supported shaft 210, a drive belt 116 stretched between the pulleys 115 and 117, and a drive belt 116 fixed to the other end of the shaft 210. , A tension pulley 121 separated from the pulley 118 by a predetermined distance along the moving direction of the bonding motor 66, an application roller rotating pulley 120 fixed to a rotation shaft 68c of the application roller 68b, and pulleys 118 and 120. , 121, and a constant tension is applied to the coating roller rotating belt 119 by being pressed against the coating roller rotating belt 119 on both sides of the coating roller rotating pulley 120 and near the pulley 118. And a tensioner 122 to be applied. Note that the tensioner 122 is also applied to the drive belt 116. The roller rotation motor 68 is electrically connected to the CPU 159, and its driving is controlled by the CPU 159 (see FIG. 15).
[0060]
Therefore, in such a configuration, when the application roller rotation motor 68 is driven under the control of the CPU 159, the motor pulley 110, the drive belt 111, the pulley 112, the gears 113 and 114, the pulley 115, the drive belt 116, the pulleys 117 and 118, The application roller rotating belt 119 is driven via the pulley 118. Therefore, the applying roller rotating pulley 120 rotates together with the applying roller rotating belt 119, and the applying roller 68b connected to the applying roller rotating pulley 120 via the rotating shaft 68c is rotated.
[0061]
By the way, as described above, such an adhesive application section 22 is provided between a reference sheet 45 and a cover adhesive section 60 described later provided downstream of the fifth transport path E (FIG. 1). reference). Then, the bonding unit 66 of the adhesive coating unit 22 uses the moving mechanism to apply a coating area 155 (in FIG. 15, an arbitrary position within the coating area 155 (first position) in the coating area 155) for applying the adhesive b to the sheet bundle S1. The adhesive unit 66 is located at (position)), and a standby position 156 (retreat position (second position) indicated by a broken line in FIG. 16) for retreating from the conveyance path of the sheet bundle S1 and preparing for the coating process. And a replenishing position 157 (a second position shown by a solid line in FIG. 16) for receiving a replenishment of the adhesive b.
[0062]
In this case, the standby position 156 is detected by the container HP sensor 72 (see FIG. 16) installed at a predetermined position (a position other than the application area 155) on the movement path of the bonding unit 66. Specifically, during the movement of the bonding unit 66, the container HP sensor flag 162 (see FIG. 13) provided on the joint member 107 that slides with the bonding unit 66 is detected by the container HP sensor 72 (the sensor 72 is turned on). ), The detection signal is sent to the CPU 159, the driving of the container moving motor 67 is stopped, and the bonding unit 66 is positioned at the standby position 156.
[0063]
The replenishment position 157 is recognized by the CPU 159 as a position away from the standby position 156 (in a state where the sensor 72 is turned on) by a predetermined distance (for example, 14 mm) in a direction away from the sheet bundle S1. Further, the application region 155 is, for example, a position of the starting position P separated from the standby position 157 by a predetermined distance in the direction approaching the sheet bundle S1 and a position of the bonding unit 66 separated from the starting position P by a predetermined distance in the direction away from the standby position 156. It is recognized by the CPU 159 as an area between the turning position Q. In the present embodiment, the standby position 156 and the replenishment position 157 are provided separately, but the replenishment position 157 may also serve as the standby position 156.
[0064]
Next, a case where the adhesive b is applied to the edge of the sheet bundle S1 sent from the accumulation unit 42 by the grippers 55a and 55b by the adhesive application unit 22 having the above configuration will be described.
[0065]
First, as described above, the sheet bundle S1 that is sandwiched and lowered by the grippers 55a and 55b from the stacking unit 42 side has a predetermined position on the application area 155 in the movement path of the bonding unit 66 (see FIG. 15). Position). In this case, the distance between the edge of the sheet bundle S1 and the application roller 68b is adjusted according to the thickness of the sheet bundle S1. That is, as described above, the thickness of the sheet bundle S1 sandwiched between the grippers 55a and 55b is detected by detecting the opening amount sensor flag 74b that moves together with the slide gripper 55b by the gripper opening amount detection sensor 74a. Therefore, the CPU 159 determines the distance between the edge of the sheet bundle S1 and the application roller 68b by performing position control on the vertical movement of the grippers 55a and 55b based on the detection result.
[0066]
When the sheet bundle S1 is positioned at a predetermined position on the application area 155 in this manner, the adhesive unit 66 that has been waiting at the standby position 156 controls the start position P of the application area 155 by the control of the CPU 159. (The state shown in FIG. 15). Thereafter, the bonding unit 66 is moved from the starting position P toward the folding position Q with respect to the sheet bundle S1 in a state where the application roller 68b is rotated forward and is in contact with the edge of the sheet bundle S1. Thus, the adhesive b is evenly applied to the edge of the sheet bundle S1 by the application roller 68b having the surface of the adhesive b in the container 66a.
[0067]
When the bonding unit 66 reaches the turning position Q, the forward rotation of the application roller 68b is stopped, and the movement of the bonding unit 66 is also stopped. Then, from this point, the bonding unit 66 starts to move from the turnback position Q toward the starting position P with the application roller 68b rotated in the reverse direction. Then, when the bonding unit 66 reaches the starting position P again, the reverse rotation of the application roller 68b is stopped, and the movement of the bonding unit 66 is also stopped. Then, after the reciprocation as described above is performed twice, for example, the operation of applying the adhesive b is completed.
[0068]
When the application of the adhesive b to the edge of the sheet bundle S1 is completed, the bonding unit 66 is moved to the standby position 157 or the replenishment position 156, and the conveyance path of the sheet bundle S1 is secured. The movement control of the bonding unit 66 at this time is performed by the CPU 159 via the container moving motor 67 based on the detection result of the container HP sensor 72 as described above. After that, the sheet bundle S1 nipped by the grippers 55a and 55b is lowered to the cover bonding unit 60 through the transport path secured by the retreat of the bonding unit 66 (in a direction intersecting the moving direction of the bonding unit 66) ( See FIG. 16).
[0069]
The cover S0 (see FIG. 8) has already been conveyed to the cover bonding section 60 and is on standby until the adhesive b is applied to the edge of the sheet bundle S1 in this manner. In this case, as shown in FIG. 2, the cover S0 is sent from the apparatus main body 2 to the cover bonding unit 60 via the cover supply unit. That is, the cover S0 is transported into the fifth transport path E via the first and second switching flappers 27 and 32, and the sheet bundle S1 is transported via the cover transport drive roller 57 in the transport path E. Is positioned at a predetermined position of the cover bonding section 60 that crosses the transport path of. Then, the edges of the sheet bundle S1 to which the adhesive b is applied are pressed against the positioned cover sheet S0 by the grips 55a and 55b (see FIG. 8). Further, in this state, the sheet bundle S1 is further moved downward by the grippers 55a and 55b while the cover S0 is adhered to the edge thereof by the adhesive b, and the slide located below the cover adhering section 60. It is pressed against a free butting plate 59 (see FIG. 2). Thereafter, the cover S0 and the sheet bundle S1 are pressed from both sides by a slidable back-folding plate 58 (see FIG. 2) in a state of being abutted against the abutting plate 59. Thereby, a fold corresponding to the thickness of the sheet bundle S1 is formed on the cover S0.
[0070]
Next, after the abutment plate 59 slides outward to form a conveyance path for the sheet bundle S1, the grippers 55a and 55b hold the sheet bundle S1 to which the cover S0 is adhered while holding the sheet bundle S1. 23 (see FIG. 1). At this time, if the grippers 55a and 55b do not have a sufficient stroke to deliver the sheet bundle S1 to the lower cutting unit 23, the sheet bundle S1 to which the cover S0 is adhered is moved downward by the grippers 55a and 55b. After the sheet bundle S1 has been moved by the predetermined distance, the gripping state of the sheet bundle S1 by the grippers 55a and 55b is released once the sheet bundle S1 is sandwiched by the back folding plate 58. Then, if the grippers 55a and 55b are moved upward, and the sheet bundle S1 is again clamped by the grippers 55a and 55b and moved downward at the position above the grippers 55a and 55b, even if the strokes of the grippers 55a and 55b are small, the grippers 55a are moved. , 55b alone enables the sheet bundle S1 to be reliably delivered to the lower cutting section 23.
[0071]
By the way, when the application processing of the adhesive b as described above is repeated, the amount of the adhesive b in the container 66a decreases, and it becomes necessary to replenish the adhesive b in the container 66a. Therefore, in the present embodiment, the remaining amount of the adhesive b in the container 66a is detected, and the bonding unit 66 can be moved to the replenishing position 157 automatically or as required.
[0072]
That is, the reference surface 161 is set to the same height as the liquid level of the adhesive b when the inside of the container 66a is filled with the adhesive b in the adhesive application section 22, and the inside of the container 66a An adhesive amount detection sensor 160 (see FIG. 15) for detecting the current liquid level (uppermost surface) of the adhesive b is provided. Then, the CPU 159 calculates the amount of the adhesive b in the container 66a from the difference between the current liquid level detected by the adhesive amount detection sensor 160 and the reference surface 161, and replenishes the adhesive based on the calculation result. The amount of the adhesive b to be determined is determined, and the adhesive unit 66 is moved from the application area 155 or the standby position 156 to the replenishment position 157 at a predetermined timing or according to a user's request.
[0073]
Next, an adhesive replenishing mechanism (replenishing means) K for replenishing the adhesive in the container 66a of the adhesive unit 66 at the replenishing position 156 will be described with reference to FIGS.
[0074]
The adhesive replenishing mechanism K is provided above the replenishing position 157 as shown also in FIG. 16, and as shown in FIG. 17 and FIG. 163), a rotation mechanism (rotation driving means) 230 for rotating the adhesive bar storage 153, and a discharge position (discharge unit) for the adhesive rod 163 in the adhesive bar storage 153. A push mechanism 240 that pushes down at 158 and a feed mechanism 250 that feeds the adhesive rod 163 pushed by the push mechanism 240 into the container 66a of the adhesive unit 66 through the outlet 164 (see FIGS. 16 and 21) are provided. I have. The bonding rod 163 is loaded into the bonding rod storage body 153 by the user, for example, from the loading section G.
[0075]
The power of the rotation mechanism 230, the pushing mechanism 240, and the feed mechanism 250 (adhesive moving means) is obtained by forward / reverse rotation of the common adhesive supply motor 123. In this case, as will be described later, when the adhesive replenishment motor 123 rotates forward, power is transmitted to the rotation mechanism 230, and the adhesive rod housing 153 is rotated. On the other hand, when the adhesive replenishment motor 123 rotates reversely, the pushing mechanism 240 is rotated. The power is transmitted to the feed mechanism 250 and an adhesive rod pushing arm 140 and an adhesive rod feed drive roller 149 described later are driven.
[0076]
As clearly shown in FIG. 17, the adhesive rod storage body 153 is configured as a substantially cylindrical rotating body rotatably supported by the rotation support member 290, and a plurality of partitions separated by the partition member 131. Is provided along the circumferential direction thereof. That is, the adhesive rod storage section 153a is formed by dividing the adhesive rod storage body 153 into a plurality of cylindrical parts by the partition member 131.
[0077]
Further, by rotating the bonding rod storage unit 153 by the rotation mechanism 230, any one of the bonding rod storage units 153a is positioned at the discharge position 158. That is, the adhesive rod storage body 153 can rotate (move) between the carry-in portion G for receiving the adhesive rod 163 to be refilled and the discharge position 158 for refilling the adhesive rod 163 to the container 66a of the adhesive unit 66. I can do it.
[0078]
At the discharge position 158, an adhesive rod empty sensor 143 for detecting the presence or absence of the adhesive rod 163 in the adhesive rod storage portion 153a located at the discharge position 158 is provided (see FIG. 19). Further, the adhesive rod storage body 153 has, for example, a circular clock plate (encoder) 132 that rotates integrally with the adhesive rod storage body 153 at the bottom thereof. A plurality of slits 132a for detection are formed at predetermined intervals. Further, in the present embodiment, it is desirable to provide a shielding member for preventing the adhesive bar 163 from being carried into the adhesive bar storage portion 153a at the carry-out position 158 in the carry-in portion G.
[0079]
As clearly shown in FIG. 18, the rotation mechanism 230 that rotates the adhesive rod housing 153 includes a motor gear 124 attached to an output shaft of the adhesive refill motor 123, a first gear pulley 125 that meshes with the motor gear 124, A first pulley 127 separated from the first gear pulley 125 at a predetermined interval, a first drive belt 126 stretched between the pulleys 125 and 127, and separated from the first pulley 127 at a predetermined interval. A second gear pulley 129, a second drive belt 128 stretched between the pulleys 127 and 129, and a one-way gear 130 that rotates integrally with the adhesive rod storage body 153 and meshes with the second gear pulley 129. I have. In this case, the one-way gear 130 does not transmit the reverse rotation driving force of the adhesive replenishment motor 123 to the adhesive rod storage body 153 so that the adhesive rod storage body 153 does not rotate when the adhesive replenishment motor 123 rotates reversely.
[0080]
Therefore, in such a configuration, when the adhesive replenishment motor 123 rotates forward, the motor gear 124, the first gear pulley 125, the first drive belt 126, the first pulley 127, the second drive belt 128, and the second The one-way gear 130 rotates in the direction indicated by the arrow in FIG. 18 via the gear pulley 129, and the adhesive rod housing 153 rotates.
[0081]
On the other hand, the pushing mechanism 240 shares the motor gear 124, the first gear pulley 125, the first drive belt 126, and the first pulley 127 with the rotating mechanism 230, as clearly shown in FIG. ing. Further, the pushing mechanism 240 has, as its own components, a worm gear (one-way gear) 133 that rotates integrally with the first pulley 127, a first gear 134 that meshes with the worm gear 133, and meshes with the first gear 134. A second gear 135, a second pulley 137 connected to the second gear 135 via a torque clutch 136, and a tension pulley 139 spaced upward from the second pulley 137 at a predetermined interval. , A belt member 138 bridged between the pulleys 137 and 139, an adhesive rod pushing arm 140 connected and fixed to the belt member 138 via a joint member 154, and between the belt member 138 and the adhesive rod container 153. And an extended arm guide rail 141.
[0082]
In this case, the worm gear 133 does not transmit the forward rotation driving force of the adhesive refill motor 123 to the first gear 134 so that the adhesive pushing arm 140 is not driven when the adhesive refill motor 123 rotates forward. Further, the torque clutch 136 prevents the bonding rod 163 from being damaged by idling when the bonding rod pushing arm 140 excessively presses the bonding rod 163 against the application roller 68b of the bonding unit 66 as described later. It is supposed to.
The adhesive rod pushing arm 140 is normally held in a posture parallel to the belt member 138 (the posture indicated by A in FIG. 19) by being urged by a spring (not shown). When the mating portion 140a engages with an engaging portion 141a of the guide rail 141, which will be described later, a posture orthogonal to the belt body 138 (the guide rail 141) against the urging force of the spring (a posture indicated by B in FIG. 19). , And can be applied to the upper end of the bonding rod 163 in the bonding rod storage portion 153a located at the discharge position 158.
[0083]
The guide rail 141 extends along the belt body 138 from the reversing position on the tension pulley 139 side in the traveling of the belt body of the adhesive rod pushing arm 140 to just before the reversing position on the second pulley 137 side. Further, the guide rail 141 is positioned near the reversing position on the tension pulley 139 side to engage the engaging portion 140a of the bonding rod pressing arm 140, thereby causing the bonding rod pressing arm 140 to be in a parallel posture against the urging force of the spring. A has an engaging portion 141a for converting from A to the orthogonal posture B. On the downstream side from the engaging portion 141, the rail surface contacts the bonding rod pressing arm 140, and the bonding rod pressing arm 140 has The posture B is maintained. The guide rail 141 is provided with an arm HP sensor 142 for detecting the home position of the adhesive rod pushing arm 140 at an inverted position on the tension pulley 139 side, specifically, at an upstream side of the engaging portion 141. Have been.
[0084]
Therefore, in such a configuration, when the adhesive replenishment motor 123 rotates in the reverse direction, the motor gear 124, the first gear pulley 125, the first drive belt 126, the first pulley 127, the worm gear 133, the first gear 134, the second gear The belt body 138 is rotationally driven via the gear 135, the torque clutch 136, and the second pulley 137, and the adhesive rod pushing arm 140 moves together with the belt body 138. Also, during this movement, as shown in detail in FIG. 21, when the engaging portion 140a of the adhesive rod pushing arm 140 engages with the engaging portion 141a of the guide rail 141, the adhesive rod pushing arm 140 applies the urging force of the spring. Is changed from the posture A parallel to the belt body 138 to a posture B orthogonal to the belt body 138 (guide rail 141), and guided while the perpendicular surface B is held by the rail surface of the guide rail 141. At the same time, it comes into contact with the upper end of the adhesive rod 163 in the adhesive rod storage portion 153a located at the discharge position 158, and thereafter, the adhesive rod 163 is sent downward. Then, when the bonding rod pushing arm 140 is released from the guide rail 141 just before the reversing position on the second pulley 137 side, it is returned to the parallel posture A again by the urging force of the spring (see C in FIG. 21). After that, the parallel posture A is maintained until the engagement with the engagement portion 141a of the guide rail 141 again.
[0085]
As clearly shown in FIG. 20, the feed mechanism 250 connects the motor gear 124, the first gear pulley 125, the first drive belt 126, and the first pulley 127 to the rotation mechanism 230 and the pushing mechanism. The worm gear 133 is shared with the pushing mechanism 240. The feed mechanism 250 includes, as its own components, a third gear 144 that meshes with the worm gear 133, a third pulley 146 connected to the third gear 144 via a torque clutch 145, and a third gear 144. A first rotating shaft 300 spaced apart from the pulley 146 at a predetermined interval, a fourth pulley 148 fixed to one end of the first rotating shaft 300, and a third rotating shaft between the pulleys 146 and 148. Drive belt 147, a feed drive roller 149 fixed to the first rotation shaft 130 and in contact with the bonding rod 163 to feed the bonding rod 163 downward, and a second rotation extending in parallel with the first rotation shaft 300. A shaft 310 and a feed driven roller 150 fixed to the second rotating shaft 310 and in contact with the adhesive bar 163 to feed the adhesive bar 163 downward in cooperation with the feed drive roller 149; That. In this case, when the feed drive roller 149 excessively presses the bonding rod 163 against the application roller 68b of the bonding unit 66 as described later, the torque clutch 145 prevents the bonding rod 163 from being damaged by idling. It is supposed to.
[0086]
Further, the feed mechanism 250 is provided with a detection unit for detecting the supply amount of the bonding rod 163, that is, the pressing amount of the bonding rod 163. More specifically, this detecting means determines the amount of feed of the adhesive rod 163 from the amount of rotation of the clock plate (encoder) 151 fixed to the second rotating shaft 310 and the amount of rotation of the clock plate 151 accompanying rotation of the feed rollers 149 and 150. And a feed amount detection sensor 152 for detecting The detection signal from the feed amount detection sensor 152 is sent to the CPU 159.
[0087]
Therefore, in such a configuration, when the adhesive replenishment motor 123 rotates in the reverse direction, the motor gear 124, the first gear pulley 125, the first drive belt 126, the first pulley 127, the worm gear 133, the third gear 144, and the torque The first rotating shaft 300 is rotated via the clutch 145, the third pulley 146, the third driving belt 147, and the fourth pulley 148, and the feed driving roller 149 fixed to the first rotating shaft 300 is rotated. Rotated. Therefore, the adhesive rod 163 that comes into contact with the feed drive roller 149 and the feed driven roller 150 is sent downward from the outlet 164 toward the container 66 a of the adhesive unit 66.
[0088]
Next, a case where the adhesive is replenished into the container 66a of the bonding unit 66 using the adhesive replenishing mechanism K having the above configuration will be described.
[0089]
As described above, when the adhesive unit 66 is moved from the application area 155 or the standby position 156 to the replenishment position 157 at a predetermined timing (automatically) or at the request of the user, the adhesive amount detection sensor 160 The adhesive (adhesive bar 163) is replenished from the adhesive replenishing mechanism K into the container 66a of the adhesive unit 66 by the amount calculated by the CPU 159 based on the detection signal from (see FIG. 15).
[0090]
Specifically, when the adhesive rod 163 is detected at the discharge position 158 by the adhesive rod empty sensor 143 (see FIG. 19), the adhesive rod 163 is operated by the pushing mechanism 240 and the feed mechanism 250 according to the replenishment request. The pushing arm 140 and the pair of feed rollers 149 and 150 are driven, and the adhesive rod 163 in the adhesive rod storage part 153a located at the discharge position 158 is sent downward from the outlet part 164 toward the container 66a of the adhesive unit 66. At this time, since the adhesive replenishing motor 123 is rotating in the reverse direction, the rotating mechanism 230 is not driven, and the adhesive rod 163 is smoothly sent downward without any trouble while being held at the discharge position 158. .
[0091]
On the other hand, when the bonding rod 163 is not detected at the discharging position 158 by the bonding rod empty sensor 143, the bonding operation is performed by the rotating mechanism 230 until the bonding rod storage portion 153a where the bonding rod 163 exists is positioned at the discharging position 158. The rod housing 153 is rotated. Of course, at this time, since the adhesive replenishment motor 123 is rotating forward, the pushing mechanism 240 and the feed mechanism 250 are not driven, and the adhesive rod pushing arm 140 enters the rotating adhesive rod storage body 153. Never. Then, when the bonding rod storage section 153a in which the bonding rod 163 exists is located at the discharge position 158 and this is detected by the bonding rod empty sensor 143, the pushing mechanism 240 and the feed mechanism 250 are subsequently driven to push the bonding rod. The operation of replenishing the adhesive rod 163 is performed by the arm 140 and the adhesive rod feed roller pairs 149 and 150.
[0092]
In the replenishment operation of the bonding rod 163 by the pressing mechanism 240 and the feeding mechanism 250, the bonding rod 163 is pressed against the application roller 68b of the bonding unit 66 by the bonding rod pressing arm 140 and the bonding rod feed roller pair 149, 150, for example. Is done. When the bonding rod pushing arm 140 pushes the bonding rod 163 downward while melting the bonding rod 163, the engagement state between the bonding rod pressing arm 140 and the guide rail 141 is released. As a result of this disengagement, the adhesive rod pushing arm 140 is changed in posture from the posture B orthogonal to the belt body 138 to the posture A parallel to the belt body 138 by the biasing force of the spring, as described above. Move with the belt body 138 while maintaining the parallel posture A. As described above, if the adhesive rod pushing arm 140 is always kept in the parallel posture A except for the operation of pushing down the adhesive rod 163, the space of the pushing mechanism 240 can be saved.
[0093]
Further, after the bonding rod pushing arm 140 is converted into the parallel posture A and held in this manner, the bonding rod 163 is pushed down only by the feed roller pairs 149 and 150. During this time, the adhesive rod pushing arm 140 receives the driving force from the adhesive replenishment motor 123 which is a common driving source for the feed roller pairs 149 and 150, and thus continues to move together with the belt body 138. After the adhesive bar 163 is pushed down only by the feed roller pair 149 and 150 to replenish all the adhesive bars 163 at the discharge position 158, the next adhesive bar 163 is positioned at the discharge position 158. For this purpose, the adhesive rod housing 153 is rotated. At this time, if the adhesive rod pushing arm 140, which has been moving up to that point, has entered the adhesive rod storage section 153a at the discharge position 158, the rotation of the adhesive rod storage body 153 will be hindered, and the adhesive rod pushing will be inhibited. Either the arm 140 or the adhesive rod storage body 153 will be damaged. Therefore, in this embodiment, when the adhesive rod pushing arm 140 is detected by the arm HP sensor 142, the reverse rotation drive of the adhesive replenishing motor 123 is stopped (the driving of the pushing mechanism 240 and the feed mechanism 250 is stopped), Thereafter, the adhesive replenishing motor 123 is driven to rotate forward to rotate the adhesive rod housing 153. Note that such control is performed by the CPU 159 as described above.
[0094]
As described above, the adhesive (adhesive) is supplied from the adhesive replenishing mechanism K into the container 66a of the adhesive unit 66 by the amount calculated by the CPU 159 based on the detection signal from the adhesive amount detection sensor 160 (see FIG. 15). When the bar 163) is replenished, the replenishment operation is completed. In this case, the replenishment amount of the adhesive rod 163 is recognized by the CPU 159 via a feed amount detection sensor 152 that detects the rotation amount of the clock plate 151 accompanying the rotation of the feed rollers 149 and 150.
[0095]
As described above, the adhesive application device according to the present embodiment applies the grippers 55a and 55b as supporting means for supporting the sheet bundle S1 and the adhesive to the edges of the sheet bundle S1 supported by the grippers 55a and 55b. The bonding unit 66 is also provided as a coating unit for coating, and the sheet bundle S1 is conveyed with the edge on which the adhesive is coated by the bonding unit 66 leading.
[0096]
As described above, if the sheet bundle S1 is transported with the edge on which the adhesive is applied at the top, the application amount of the adhesive is strictly controlled without securing a particularly large space for the transport path. Even if no special equipment is provided, the edge of the sheet bundle S1 does not come into contact with the conveyance path when the sheet bundle S1 is moved, so that the adhesive is not scraped off. Therefore, the sheets S constituting the sheet bundle S1 can be securely bonded to each other, and the sheet bundle S1 and the cover S0 can be sufficiently bonded without increasing the size and cost of the apparatus. Further, there is no problem that the adhesive adhered to the side wall of the transport path hinders the subsequent transport of the sheet bundle S1.
[0097]
Further, the adhesive applying apparatus of the present embodiment conveys the sheet bundle S1 with the edge on which the adhesive is applied by the adhesive unit 66 leading, and sets the edge of the sheet bundle S1 at the predetermined position. Pressed against the cover S0. According to such a configuration, in particular, the shift between the sheets S in the transport direction that occurs when the sheet bundle S1 is transported (during transport) by a rotating body such as a roller is determined by setting the edge of the sheet bundle S1 to the cover S0. It can be corrected when pressing toward.
[0098]
Further, the adhesive application device of the present embodiment includes an application area 155 (first position) where the adhesive is applied to the edge of the sheet bundle S1 and a retreat position where the conveyance of the sheet bundle S1 by the grippers 55a and 55b is not hindered. The bonding unit 66 can be moved to 156 and a replenishment position 157 (second position).
[0099]
In such a configuration, by moving the bonding unit 66 instead of moving the sheet bundle S1 so as to avoid the bonding unit 66, the transport path of the sheet bundle S1 to which the adhesive has been applied can be secured. The processed sheet bundle S1 is unlikely to shift during conveyance.
[0100]
Further, the adhesive application device of the present embodiment includes grippers 55a and 55b which convey the sheet bundle S1 to the cover S0 set at the predetermined position and press the sheet bundle S1 while holding the sheet bundle S1. Therefore, even if a sheet S shifted in the transport direction occurs when the sheet bundle S1 is transported, since the sheet bundle S1 is reliably pressed toward the cover S0 while being sandwiched, the sheet S shifted in the transport direction when pressed. Is corrected, the sheet bundle S1 can be adhered to the cover.
[0101]
Further, in the adhesive application device of the present embodiment, the adhesive is applied to the lower edge of the sheet bundle S1, and the sheet bundle S1 is conveyed downward, and the sheet bundle S1 is placed on the lower cover S0. Since the lower edge is pressed, even if the adhesive hangs down, it is received on the cover S0, and there is no possibility that the adhesive will adhere to other parts of the apparatus and cause a problem.
[0102]
FIG. 22 and FIG. 23 show a modification of the bonding unit. As shown in the figure, the bonding unit 66A according to this modification includes a container 310 containing an adhesive, and a nozzle 325 serving as an adhesive discharging member that discharges the adhesive in the container 310 to the edge of the sheet bundle S1. And a supply tube 326 attached to the nozzle 325 to supply the adhesive. The bonding unit 66A is supported by a support member 328 slidably mounted by a guide rail 327, and can move the discharge port of the nozzle 325 along the lower edge of the sheet bundle S1. That is, as shown in FIG. 23, the nozzle 325 moves from one end to the other end of the sheet bundle S1 while discharging and applying the adhesive to the edge of the sheet bundle S1.
[0103]
As described above, by adopting a configuration in which the adhesive is discharged, even if the sheet S of the sheet bundle S1 is displaced, the adhesive is uniformly applied to the edge of the sheet bundle S1 by the discharge pressure from the nozzle 325. Can be.
[0104]
FIGS. 24 and 25 show a first modification of the transport mode of the sheet bundle S.
[0105]
As shown in FIG. 24, the sheet bundle conveying mechanism (conveying means) according to this modification engages with a guide 331 that sandwiches the sheet bundle S1 from both sides and the upper end (the rear edge in the conveying direction) of the sheet bundle S1. A pusher 330 is provided as an engagement member that pushes down the upper end of the pusher 330 in a state where the pusher 330 is pressed. In this configuration, the sheet bundle S <b> 1 is pushed down to the application position by the pusher 330 while being held by the guide 331. The bonding unit 66 moves to the application area 155 and applies the adhesive to the edge of the sheet bundle S1. When the adhesive is applied to the edge of the sheet bundle S1, the bonding unit 66 moves to the standby position 156 or the replenishment position 157, and forms the transport path of the sheet bundle S1.
FIG. 25 shows a state in which the edge of the sheet bundle S1 is pressed against the cover S0 by the pusher 330. As described above, when the adhesive is applied to the edge of the sheet bundle S1 and the bonding unit 66 is moved to the standby position 156 or the replenishment position 157, and the conveyance path of the sheet bundle S1 is formed, the pusher 330 becomes Then, the upper end of the sheet bundle S1 sandwiched between the guides 331 is pressed down, and the edge of the sheet bundle S1 on which the adhesive is applied is pressed against the cover S0.
[0106]
According to such a configuration, even when the sheet S shifted in the transport direction occurs when the sheet bundle S1 is transported, the pusher 330 is engaged with the rear end of the sheet bundle S1 in the transport direction. The edge is securely pressed against the cover S0. Therefore, the sheet bundle S1 can be adhered to the cover S0 while correcting the sheet S that is displaced in the transport direction at the time of pressing.
[0107]
FIGS. 26 to 29 show a second modification of the transport mode of the sheet bundle S. As shown in FIG. 26, a sheet bundle transport mechanism (transporting unit) according to this modification transports a plurality of bundles as an engagement member that transports the sheet bundle S1 while rotating while pressing both surfaces of the sheet bundle S1. A roller pair 333 is provided. The sheet bundle S <b> 1 is conveyed to the lower application area 155 by the rotation of the bundle conveying roller pair 333 in a state where both sides are pressed and nipped by the bundle conveying roller pair 333. The bonding unit 66 moves to the application area 155 and applies the adhesive to the edge of the sheet bundle S1. When the adhesive is applied to the edge of the sheet bundle S1, the adhesive unit 66 moves to the standby position 156 or the replenishment position 157, and forms a transport path for the sheet bundle S1.
[0108]
FIG. 27 illustrates a state in which the edge of the sheet bundle S1 is pressed against the cover S0 by the bundle conveying roller pair 333. When the adhesive is applied to the edge of the sheet bundle S1 and the adhesive unit 66 is moved to the standby position 156 or the replenishment position 157 to form a transport path for the sheet bundle S1, the bundle transport roller pair 333 moves The bundle S1 is pressed down, and the edge of the sheet bundle S1 on which the adhesive is applied is pressed against the cover S0. Note that the sheet bundle S1 can be freely conveyed up and down by the forward and reverse rotation of the bundle conveying roller pair 333.
[0109]
Here, a description will be given of the correction of the deviation occurring in the sheet bundle S1 when the sheet bundle S1 is conveyed with the edge on which the adhesive is applied being the leading edge.
[0110]
FIG. 28 shows a state in which the sheet bundle S1 is shifted when the sheet bundle S1 is conveyed with the edge 334 to which the adhesive is applied being the leading edge. As shown in the figure, when the sheet bundle S1 is conveyed onto the cover S0 surface with the edge 334 being the leading edge by rotating the bundle conveying roller pair 333, the sheet S directly in contact with the bundle conveying roller pair 333 and the bundle The sheet S that is not directly in contact with the pair of conveying rollers 333 is shifted during conveyance. If the cover S0 is stuck in this misaligned state, the bonding of the sheet bundle S1 will be incomplete and the sheet bundle S1 will fall apart.
[0111]
FIG. 29 shows a state in which the sheet bundle S1 is pressed against the cover S0. As shown in FIG. 29, the deviation caused during the conveyance in which both sides of the sheet bundle S1 are pressed by the bundle conveyance roller pair 333 is corrected when the sheet bundle S1 is pressed against the cover S0, as shown in FIG. Note that the above deviation correction can be achieved by pressing the sheet bundle S1 against the cover S0 not only by the bundle transport roller pair 333 but also by the gripper.
[0112]
According to the above-described transport mechanism, when the sheet bundle S1 is transported with the edge on which the adhesive is applied being the leading edge, the shift caused by the transport can be corrected, and the adhesive can be reliably applied. You can perform beautiful bookbinding.
[0113]
As described above, the preferred embodiments of the present invention have been described. However, it is needless to say that the present invention is not limited to the above-described embodiments, and can be variously modified without departing from the gist thereof. For example, in the above-described embodiment, the sheet bundle S1 is formed in an upright state in a substantially vertical direction, and is conveyed in the substantially vertical state. It is not necessary that the sheet bundle S1 be substantially vertical. In other words, any form may be used as long as the sheet bundle S1 can be conveyed with the edge on which the adhesive is applied at the top.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an image forming apparatus including a sheet processing apparatus having an adhesive application apparatus according to the present invention.
FIG. 2 is a cross-sectional view of a conveyance alignment unit that conveys a sheet discharged from an apparatus main body of the image forming apparatus to a stacking unit.
FIG. 3 is an assembled perspective view of a gripper opening / closing mechanism and a lifting / lowering mechanism.
FIG. 4 is an exploded perspective view of a gripper opening / closing mechanism and a lifting / lowering mechanism.
FIG. 5 is a perspective view showing a slidable engagement form between a gripper unit and a support plate.
FIG. 6 is a perspective view showing one side of a gripper opening / closing mechanism.
FIG. 7 is a perspective view showing the other side of the gripper opening / closing mechanism.
FIG. 8 is a side view of the other side of the gripper opening / closing mechanism.
FIG. 9 is a perspective view showing one side of a gripper lifting mechanism.
FIG. 10 is a side view of one side of the gripper elevating mechanism.
11A is a plan view of the bonding unit, FIG. 11B is a cross-sectional view taken along line ZZ of FIG. 11A, and FIG. 11C is an exploded perspective view of the bonding unit.
FIG. 12 is a perspective view of a moving mechanism for moving the bonding unit and a driving mechanism for rotating the application roller.
FIG. 13 is a perspective view mainly showing a moving mechanism for moving the bonding unit.
FIG. 14 is a perspective view mainly showing a driving mechanism for rotating an application roller.
FIG. 15 is an electrical circuit diagram and a diagram showing a positional relationship between a sheet bundle and an adhesion unit in an adhesive application section (a state where the adhesion unit is located in an application area).
FIG. 16 is a diagram illustrating a positional relationship between a sheet bundle and an adhesion unit in an adhesive application section (a state where the adhesion unit is located at a replenishment position).
FIG. 17 is a perspective view of an adhesive replenishment mechanism.
FIG. 18 is a perspective view mainly showing a rotation mechanism for rotating the adhesive rod housing.
FIG. 19 is a perspective view mainly showing a pushing mechanism for pushing an adhesive rod into an adhesive unit.
FIG. 20 is a perspective view mainly showing a feeding mechanism for feeding the bonding rod into the bonding unit.
FIG. 21 is a schematic side view of the feed mechanism of FIG. 20;
FIG. 22 is a side view according to a modification of the bonding unit.
FIG. 23 is a front view according to a modified example of the bonding unit.
24A is a side view according to a first modified example (before cover bonding) of a sheet bundle conveyance mode, and FIG. 24B is a front view.
FIG. 25A is a side view according to a first modified example (after the cover is adhered) of the sheet bundle conveyance mode, and FIG. 25B is a front view.
26A is a side view according to a second modified example (before cover bonding) of a sheet bundle conveyance mode, and FIG. 26B is a front view.
FIG. 27A is a side view according to a second modified example (after the cover is adhered) of the sheet bundle conveyance mode, and FIG. 27B is a front view.
FIG. 28 is a diagram for explaining displacement correction according to a second modification of the sheet bundle conveyance mode.
FIG. 29 is a diagram for explaining deviation correction according to a second modification of the sheet bundle conveyance mode.
[Explanation of symbols]
42 accumulation unit
55a Fixed gripper (supporting means)
55b slide gripper (supporting means)
66 Adhesion unit (application means)
66a container (adhesive container)
68b Coating roller (rotating body)
155 coating area (first position)
156 Standby position (second position)
157 Refill position (second position)
159 CPU (control means)
180 heater unit (melting means)
K adhesive replenishment mechanism (replenishment means)
S1 sheet bundle

Claims (12)

Support means for supporting the sheet bundle;
Coating means for applying an adhesive to an edge of the sheet bundle supported by the supporting means,
Conveying means for conveying the sheet bundle with the edge on which the adhesive is applied by the applying means at the head,
An adhesive application device, comprising: Support means for supporting the sheet bundle;
Coating means for applying an adhesive to an edge of the sheet bundle supported by the supporting means,
Cover supply means for setting the cover at a predetermined position;
Transport means for transporting the sheet bundle with the edge on which the adhesive is applied by the application means at the head, and pressing the edge of the sheet bundle against a cover set at the predetermined position;
An adhesive application device, comprising: A moving unit that moves the applying unit to a first position where the adhesive is applied to the edge of the sheet bundle and a second position that does not prevent the conveying unit from conveying the sheet bundle. The adhesive application device according to claim 1 or 2, wherein 3. The adhesive application according to claim 2, wherein the conveying unit includes a grip member that conveys and pushes the sheet bundle to the cover set at the predetermined position while holding the sheet bundle. 3. apparatus. 2. The image forming apparatus according to claim 1, wherein the conveying unit includes an engaging member that conveys the sheet bundle to the cover set at the predetermined position and presses the sheet bundle in a state of being engaged with a trailing edge of the sheet bundle in the conveying direction. 3. The adhesive application device according to 2. 4. The bonding according to claim 3, wherein the application unit includes a replenishing unit that replenishes the adhesive, and the second position is a position where the adhesive is replenished to the application unit by the replenishing unit. Agent application device. The coating means,
Melting means for heating and melting the solid adhesive,
An adhesive container that stores the adhesive melted by the melting unit,
A rotating body that applies the molten adhesive contained in the adhesive container to an edge of the sheet bundle;
The adhesive application device according to any one of claims 1 to 6, further comprising: The adhesive application device according to any one of claims 1 to 6, wherein the application unit includes an adhesive discharge member that discharges the adhesive to an edge of the sheet bundle. Support means for supporting the sheet bundle;
Coating means for applying an adhesive to an edge of the sheet bundle supported by the supporting means,
Moving means for moving the applying means to a first position at which an adhesive is applied to an edge of the sheet bundle and a second position which does not hinder the conveying of the sheet bundle by the conveying means;
Conveying means for conveying the sheet bundle in a direction intersecting the moving direction of the applying means by the moving means, with the edge on which the adhesive is applied by the applying means at the head,
An adhesive application device, comprising: Support means for supporting the sheet bundle in an upright state in a substantially vertical direction,
An application unit provided below the support unit and applying an adhesive to a lower edge of the sheet bundle supported by the support unit;
Moving means for moving the applying means to a first position for applying an adhesive to a lower edge of the sheet bundle and a second position which does not hinder the conveying of the sheet bundle by the conveying means;
Conveying means for conveying the sheet bundle downward, with the edge on which the adhesive is applied by the applying means at the head,
An adhesive application device, comprising: The adhesive application device according to claim 10, further comprising a cover supply unit provided below the application unit and configured to set a cover at a predetermined position. An image forming apparatus comprising the adhesive application device according to any one of claims 1 to 11.

Images