This invention relates to a paper-sheet handling device that is preferably applied to an apparatus which performs a punching process, a binding process or the like on recording paper-sheets released from a copy machine, a print machine or the like for black-and-white use or color use. Particularly, it relates to one in which a clamp-opening-and-closing driving section that drives a movable clamp member is provided with a cam, a part of the cam having a given shape defines a normal operation range thereof, and a hollowed part thereof, which is continuous with this part having the given shape, defines a lock position for opening the clamp so that a roller member of the movable clamp member or the like can drop into the hollowed part thereof, and it is possible to carry out any jam-removing operation with the movable clamp being opened when an error occurs.
In recent years, a case in which a copy machine, a print machine or the like for black-and-white use and for color use is used by combining a paper-sheet handling device that performs a punching process, a binding process or the like has been increased. According to this kind of paper-sheet handling device, as referred to page 2 and FIG. 4 of Japanese Patent Application Publication No. 2003-320780, the paper-sheets after the image is formed are received and are perforated by utilizing a punching function provided on a downstream side of the paper-sheets. The paper-sheets after the perforation are aligned. A binding component is automatically inserted into the punch holes thus perforated of the aligned paper-sheets.
By the way, it is configured that the paper-sheet handling device is provided with a paper-sheet-reserving unit in which, when aligning a plurality of paper-sheets after the perforation, the paper-sheets are temporarily reserved. The paper-sheet-reserving unit is provided with an alignment pin driving mechanism and in the paper-sheet-reserving unit unit, a plurality of paper-sheets entered from a paper-sheet transport path is stacked up with them being aligned. The stacked paper-sheets are aligned with an end surface and a forward end of the each paper-sheet being adjusted with their reference positions. When paper-sheets are stacked by one volume, alignment pins are inserted into two predetermined punch holes in a bundle of paper-sheets so that rearrangement (pre-alignment) is performed thereon based on the positions of punch holes. It is configured that the bundle of rearranged paper-sheets is moved to the binding processing unit while it is sandwiched by a clamp movement mechanism. In the binding processing unit, any ring binding process is performed by a binding component under the condition where the bundle of paper-sheets is aligned. According to the conventional paper-sheet handling device, however, there are problems as follows.
i. A paper-sheet handling device disclosed in Page 2 and FIG. 4 of Japanese Patent Application Publication No. 2003-320780 is provided with a clamp movement mechanism and the clamp movement mechanism holding the bundle of paper-sheets is often moved toward a binding processing unit parallel to it. If during this movement, a center position of the bundle of paper-sheets alters based on a thickness thereof, it is impossible to guide the center position of the bundle of paper-sheets to a ring center position of the binding processing unit with a good reproducibility, thereby resulting in a problem such that a poor binding by the binding member occurs.
ii. Accordingly, when the bundle of paper-sheets is moved from the paper-sheet-reserving unit to the binding processing unit while the center position alters on the basis of the thickness of the bundle of paper-sheets, the bundle of paper-sheets bends between a running guide and a clamper, thereby causing the bundle of paper-sheets to be scratched or the paper-sheets to be deviated from each other.
iii. If the poor binding by the binding member as described above occurs, any jam-removing operation must be performed in the paper-sheet-reserving unit under a condition where an excitation in a motor of the clamp-opening-and-closing driving section is turned off and a booklet is sandwiched in the clamp mechanism section. This causes the removing operation to be performed with a manipulation lever for opening the clamp being turned, thereby resulting in a problem of a poor operability on a jam processing.
iv. The above-mentioned paper-sheet handling device is provided with a clamp movement mechanism, which is often moved to the binding processing unit while it holds the bundle of paper-sheets. In this case, since the clamp movement mechanism is configured so that the clamp mechanism section and the clamp-opening-and-closing driving section are mounted on a main board, the clamp movement mechanism must be driven to the binding processing unit by the main board on which the clamp mechanism section and the clamp-opening-and-closing driving section are mounted if the clamp mechanism section holds the bundle of aligned paper-sheets.
v. Incidentally, if a structure such that the whole of clamp movement mechanism is moved to the binding processing unit is taken, a structure of the clamp movement mechanism (hereinafter referred to as “paper-sheet fixation and movement mechanism”) is not only made complex but harness (wiring) processing for supplying a power source to the clamp-opening-and-closing driving section is also made complex, thereby resulting in a problem such that it causes the paper-sheet handling device to be hindered from being made inexpensive.
A first paper-sheet handling device according to the present invention is a paper-sheet handling device that transports a bundle of paper-sheets obtained by binding a plurality of paper-sheets, characterized in that the device is provided with a paper-sheet fixation and movement mechanism that contains a fixed clamp member and a movable clamp member and transports the bundle of paper-sheets with it being fixed, wherein the paper-sheet fixation and movement mechanism contains a clamp-opening-and-closing driving section that drives the movable clamp member, wherein the clamp-opening-and-closing driving section is provided with a cam, and wherein the cam contains a part having a given shape, the part defining a normal operation range in which the movable clamp member is moved up to a predetermined position with respect to the fixed clamp member to release the bundle of paper-sheets, and a hollowed part that keeps a lock position for opening the clamp, the hollowed part being continuous with the part having the given shape.
According to the first paper-sheet handling device relating to the present invention, when transporting the bundle of paper-sheets obtained by binding the plurality of paper-sheets, the paper-sheet fixation and movement mechanism transports the bundle of paper-sheets with it being fixed together with the fixed clamp member and the movable clamp member. On the assumption of this, the clamp-opening-and-closing driving section drives the movable clamp member. The clamp-opening-and-closing driving section is provided with a cam and, when releasing the bundle of paper-sheets, the cam moves the movable clamp member up to a predetermined position with respect to the fixed clamp member by a part thereof having a given shape, which defines a normal operation range, to release the bundle of paper-sheets. Further, when an error or the like occurs, by rotating the cam to a hollowed part that is continuous with the part having the given shape, the roller member or the like of the movable clamp member can drop into the hollowed part. Accordingly, it becomes possible to lock the opened situation of the movable clamp member. This enables the operability to be improved because any jam-removing operation is carried out with the movable clamp being opened. Furthermore, since the lock position for opening the clamp is set to a position that is different from the normal operation range, it is possible to prevent release of the lock of the manipulation lever from being forgotten.
A second paper-sheet handling device according to the present invention is a paper-sheet handling device that transports a bundle of paper-sheets obtained by binding a plurality of paper-sheets, characterized in that the device is provided with a paper-sheet fixation and movement mechanism that contains a fixed clamp member and a movable clamp member, respectively, at a right end side and a left end side and transports the bundle of paper-sheets with it being fixed, wherein the paper-sheet fixation and movement mechanism contains a main body member, a clamp-opening-and-closing driving section that drives the movable clamp members at the right and left end sides, the clamp-opening-and-closing driving section being attached to the main body member, and a paper-sheet fixation and movement section that is movably attached to the main body member and transports the bundle of paper-sheets with it being fixed separately from the clamp-opening-and-closing driving section.
According to the second paper-sheet handling device relating to the present invention, when transporting the bundle of paper-sheets obtained by binding the plurality of paper-sheets, the paper-sheet fixation and movement mechanism contains the fixed clamp member and the movable clamp member at a right end side and a left end side, respectively and transports the bundle of paper-sheets with it being fixed therewith. For example, in the paper-sheet fixation and movement mechanism, the paper-sheet fixation and movement section is movably attached to the main body member. It is configured that the paper-sheet fixation and movement section contains an urging member and urges the respective movable clamp members to a side of the fixed clamp members to keep a clamp-closed situation.
The clamp-opening-and-closing driving section is attached to the main body member to drive the movable clamp members at the right and left end sides. For example, the clamp-opening-and-closing driving section exceeds urging force of the paper-sheet fixation and movement section against the respective movable clamp members to keep the clamp-opened situation. On this situation, a plurality of paper-sheets is bound to obtain the bundle of paper-sheets. It is configured that the paper-sheet fixation and movement section transports the bundle of paper-sheets with it being fixed separately from the clamp-opening-and-closing driving section.
Consequently, holding transporting the bundle of paper-sheets, it is possible to separate the clamp-opening-and-closing driving section and the paper-sheet fixation and movement section from each other structurally and to move the bundle of paper-sheets to a binding step or the like easily with it being fixed by means of the paper-sheet fixation and movement section which mounts a necessary minimal level of structural parts. Furthermore, it is possible to make a movement area (a dead space) of the paper-sheet fixation and movement section less and to make the unit structure smaller and simpler. No driving means such as a motor or no electric part such as home position sensor is mounted on the paper-sheet fixation and movement section so that any wiring (harness) processing is unnecessary because movement of such an electric part is not accompanied, thereby allowing the paper-sheet fixation and movement mechanism to be simplified.
The present invention has an object to provide a first paper-sheet handling device by which it becomes possible to improve workability and operability when a jam removes and to prevent release of the lock of the manipulation lever from being forgotten. It also has an object to provide a second paper-sheet handling device by which it becomes possible to simplify the structure of the paper-sheet fixation and movement section that moves the bundle of paper-sheets to the binding step with it being fixed.
Hereinafter, the paper-sheet handling devices relating to exemplified embodiments of this invention will be explained with respect to with reference to the drawings. The paper-sheet-handling device 100 shown in
The paper-sheet-handling device 100 has a device main body portion (housing) 101. It is preferable for the paper-sheet-handling device 100 to be used in conjunction with a copy machine, a printing machine (picture forming device) or the like, and the device main body portion 101 has a comparable height as that of the copy machine, the printing machine or the like. A paper-sheet transport unit 10 which constitutes one example of paper-sheet transport means is provided in a device main body portion 101. The paper-sheet transport unit 10 has a first transport path 11 and a second transport path 12. The transport path 11 has a paper-feed inlet 13 and an outlet 14, and has a through-pass function for transporting the paper-sheet 3 drawn from the paper-feed inlet 13 toward the outlet 14 that becomes the predetermined position.
Here, the through-pass function means a function such that the transport path 11 positioned between a copy machine, a printing machine or the like on the upstream side and other paper-sheet handling device on the downstream side directly delivers the paper-sheet 3 from the copy machine, the printing machine or the like to the other paper-sheet handling device. In a case in which the through-pass function is selected, it is configured that the acceleration process of the transport rollers, the binding process or the like is omitted. The paper-sheet 3, usually, in case of one-side copy, is delivered in a state of the face down. A paper feed sensor 111 is mounted on the paper-feed inlet 13 so as to output a paper feeding detection signal S11 to a control unit 50 by detecting a front edge of the paper-sheet 3.
The transport path 12 has a switchback function by which the transport path is switchable from the transport path 11. Here, the switchback function means a function that decelerates and stops the transport of the paper-sheet 3 at a predetermined position of the transport path 11, thereafter, switches the transport path of the paper-sheet 3 from the transport path 11 to the transport path 12, and also, delivers the paper-sheet 3 in the reverse direction. A flap 15 is provided in the transport path 11 so as to switch the transport path from the transport path 11 to the transport path 12.
Also, three cooperative transport rollers 17c, 19a′, 19a are provided at a switch point between the transport path 11 and the transport path 12. The transport rollers 17c and 19a rotate clockwise, and the transport roller 19a′ rotates counterclockwise. For example, it is constituted such that the transport roller 19a′ is a drive roller and the transport rollers 17c and 19a are driven rollers. The paper-sheet 3 taken by the transport rollers 17c and 19a′ decelerates and stops, but when it is restricted from the upper side to the lower side by the flap 15, the paper-sheet is fed by the transport rollers 19a′ and 19a so as to be transported to the transport path 12. A paper-sheet detecting sensor 114 is disposed just before the three cooperative transport rollers 17c, 19a′ and 19a, and it is configured that a front end and a rear end of the paper-sheet are detected and a paper-sheet detection signal S14 is outputted to the control unit 50.
A punching process unit 20 is arranged on the downstream side of the transport path 12. In this embodiment, it is designed such that a predetermined angle is determined between the transport path 11 and the transport path 12 as above mentioned. For example, a first depression angle θ1 is set between a transport surface of the transport path 11 and a paper-sheet surface to be perforated of the punching process unit 20. Here, the paper-sheet surface to be perforated means a surface where holes are perforated in the paper-sheet 3. The punching process unit 20 is arranged so that the paper-sheet surface to be perforated can be set to a position having the depression angle θ1 on the basis of the transport surface of the transport path 11.
It is configured that in the punching process unit 20, two or more holes for the binding (hereinafter, referred to as “punch holes 3a”) are perforated at the one end of the paper-sheet 3 which switchbacks from the transport path 11 and transported by the transport path 12. The punching process unit 20 has, for example, a motor 22 that drives a reciprocatingly operable punch blade 21. The paper-sheet 3 is perforated by the punch blade 21 driven by the motor 22 for every sheet.
An openable and closable fence 24 that becomes a reference of the perforation position is provided in the punching process unit 20 and is used so as to attach the paper-sheet 3 thereto. Further, a side jogger 23 is provided in the punching process unit 20 so that the posture of the paper-sheet 3 can be corrected. For example, the front edge of the paper-sheet 3 is made to be attached uniformly to the openable and closable fence 24. The fence 24 becomes a positional reference at the time of aligning the paper-sheet edge portion. A paper-sheet detecting sensor 118 is disposed before the side jogger 23, and it is configured that the front end and the rear end of the paper-sheet are detected and a paper-sheet detection signal S18 is outputted to the control unit 50 (see
The punching process unit 20 stops the paper-sheet 3 by attaching it to the fence 24 and thereafter, perforates the front edge of the paper-sheet 3. It should be noted that a punch scrap storing unit 26 is provided under the punching process main body so that the punch scrap cut off by the punch blade 21 can be stored therein. A paper output roller 25 is provided on the downstream side of the punching process unit 20 and the paper-sheet 3′ after the paper-sheet perforation is made so as to be transported to the unit of the succeeding stage.
In this embodiment, a paper-sheet alignment and binding processing unit 110 as one block is arranged on the downstream side of punching process unit 20. The paper-sheet alignment and binding processing unit 110 has a binder paper alignment unit 30 and it is configured that it aligns positions of the punch holes of a plurality of paper-sheets 3′ which are released from the punching process unit 20 so as to be reserved (stored) temporarily.
The binder paper alignment unit 30 is arranged so as to set the paper-sheet-reserving unit surface at the position having a second depression angle θ2 by making a transport surface of a transport path 11 to be a reference. Here, the paper-sheet-reserving unit surface means a surface that reserves (stacks) the paper-sheets 3′ where the punch holes 3a are perforated. In this embodiment, a relation between the depression angle θ1 and the depression angle θ2 is set as θ1<θ2. With respect to the depression angle θ1, it is set as 0°<θ1<45° and with respect to the depression angle θ2, it is set as 0°<θ2<90° respectively. This is set for reducing a width of the device main body portion 101 and for linearly transporting the paper-sheets 3′ under this condition (see
A releasing unit 60 is arranged on the downstream side of the paper-sheet alignment and binding processing unit 110, and it is configured that a releasing process for a booklet 90 produced by the binding process unit 40 is carried out. The releasing unit 60 is constituted so as to include, for example, a first belt unit 61, a second belt unit 62 and a stacker 63.
It is configured that the belt unit 61 receives the booklet 90 that is dropping from the binder paper alignment unit 30, and switches the delivery direction. For example, it is configured that the belt unit main body is turned around toward a predetermined release direction from the position from which the paper-sheet transporting direction of the binder paper alignment unit 30 can be looked over. It is configured that the belt unit 62 receives the booklet 90 whose delivery direction is switched by the belt unit 61 and transports it in the relay manner. It is also configured that the stacker 63 accumulates the booklets 90 transported by the belt units 61 and 62.
The following will describe a configuration example of the paper-sheet alignment and binding processing unit 110 with reference to
It is configured that a projected engaged portion 46 is provided at a lower portion and an engaged portion 47 is provided at an upper portion, at predetermined positions of the front surface of the chassis 45 as well as a projected engaged portion 46 and an engaged portion 47, not shown, are also provided at predetermined positions of the back surface thereof, thereby supporting the binder paper alignment unit 30 on a left side surface of the chassis 45.
The binder paper alignment unit 30 has a main body board 900 and is provided with a right end frame 92a and a light end frame 92b, each of which are formed as parallelogram, at both side surfaces of the main body board (see
It is configured so that in the binder paper alignment unit 30, parts-mounting areas II and III that mount various kinds of configuration parts are defined within an area surrounded by the right end frame 92a, the left end frame 92b and the main body board 900. In this embodiment, the clamp movement mechanism 80 which constitutes an example of the paper-sheet fixation and movement mechanism is arranged on a boundary defining the parts-mounting areas II and III, a diagonal line of the parallelogram in the left end frame 92b in this embodiment. The clamp movement mechanism 80 is configured so as to move the bundle of paper-sheets 3″ stacked by the perforated paper-sheets 3′ to a paper-sheet transport direction with it being held by the clamp members.
In the parts-mounting region III of right side with reference to the attached position of this clamp movement mechanism 80, a paper-sheet curl pressing mechanism 31 and a paddle low roller 37 are arranged. The paper-sheet curl pressing mechanism 31 is arranged near a paper-sheet-proceeding port in the unit 30 and is configured so as to guide the paper-sheet 3′ to a predetermined position (in the paper-sheet-reserving unit 32 or the like) of the binder paper alignment unit 30 when the paper proceeds and to press a rear end side of the paper-sheet 3′ when the paper finishes proceeding. The binder paper alignment unit 30 has a width-alignment function of the front edge and corner portion of the paper-sheet. In this embodiment, a multiple-paddle shaped rotating member (hereinafter, referred to as a paddle roller 37) is provided in the unit 30 and is configured so as to attach the front edges of the paper-sheets 3′ to a reference position when the paper proceeds and to true up the side edges thereof for aligning the bundle of paper-sheets. A handle type clamp lever 840 shown in
In the parts-mounting region II of left side with reference to the above-mentioned clamp movement mechanism 80, an alignment-pin-driving mechanism 91 is arranged and is configured so as to realign the bundle of paper-sheets by utilizing the punch holes 3a perforated in the paper-sheets 3′. The binding process unit 40 is arranged on the downstream side of the above-mentioned alignment-pin-driving mechanism 91 and is configured so as to bind a plurality of paper-sheets 3″ that are aligned by the binder paper alignment unit 30 by means of binding component 43 to create a booklet 90. The booklet 90 is referred to as a bundle of paper-sheets 3″ which the binding component 43 is fitted to bind.
The binding process unit 40 is constituted by containing a binder cassette 42 in which the binding components 43 are mounted and a movement mechanism 41 for the binding process. The movement mechanism 41 operates so as to perform a reciprocation movement between the transport path of the bundle of paper-sheets in the binder paper alignment unit 30 and a position that is perpendicular to a transporting direction of the above-mentioned transport path 11. The binding process unit 40 contains the binder (binding component) cassette 42. A plurality of binding components is set in the binder cassette 42. Various kinds of the binding components are prepared by, for example, injection molding corresponding to thickness of the bundle of paper-sheets 3″.
The movement mechanism 41 for the binding process is also attached to a lower portion of the front surface of the chassis 45. In this embodiment, it is configured that the lower portion of the front surface of the chassis 45 reduces gradually in its width as it goes ahead toward the lower portion. In this portion, long aperture guide portions 441 and 442 each having an arc of a circle and a bearing portion 401 having U-shape are respectively provided.
In this embodiment, a movement mechanism rotating axis 41d, a projection portion 48 for guide and a gear axis 49 for limiting the driving shaft are arranged at predetermined positions of the movement mechanism 41. The movement mechanism rotating axis 41d is movably engaged with the above-mentioned bearing portion 401, the projection portion 48 is engaged with the long aperture guide portion 441 and the gear axis 49 is movably engaged with the long aperture guide portion 442. When performing the bind processing, the movement mechanism 41 operates with reference to the movement mechanism rotating axis 41d along the long aperture guide portions 441, 442 so as to be limited as the arc of the circle indicated by an arrow Y shown in the figure.
On the other hand, the clamp movement mechanism 80 is provided with roller members 817, 818 at both sides of its lower forward end and the movement mechanism 41 is provided with openings 44a, 44b each having Y-shape at both sides of its upper forward end. In this embodiment, when performing the bind processing on the binding component 43, only a paper-sheet fixation and movement section 880 in the clamp movement mechanism 80 drops by its self weight so that it is configured that the roller member 817 is fitted into the opening 44a and the roller member 818 is fitted into the opening 44b, with a self-aligning method. Thus, a structure is made such that by fitting the roller members 817, 818 into the openings 44a, 44b, the movement mechanism 41 is connected on a straight line and a center position of the bundle of paper-sheets 3″ is guided to a center position of the binding component 43.
The movement mechanism 41 pulls out one piece of binding components 43 from the binder cassette 42 to hold it and in this state, rotates to a position from which the paper-sheet transporting direction I of the binder paper alignment unit 30 can be looked over. At this position, the movement mechanism 41 receives the bundle of paper-sheets 3″ whose punch holes are position-aligned from the binder paper alignment unit 30 and inserts the binding component 43 into the punch holes thereof to execute the binding process (automatic book-making function).
The following will describe a paper-sheet handling example with respect to a paper-sheet handling method relating to the invention with reference to process diagrams shown in
The paper-sheet 3 shown in
In the punching process unit 20, as shown in
The following will describe a configuration example of the paper-sheet curl pressing mechanism 31 and its periphery mechanism with respect to the binder paper alignment unit 30 with reference to
The binder paper alignment unit 30 shown in
It is configured that the paper-sheet curl pressing mechanism 31 guides the paper-sheet 3′ to the paper-sheet-reserving unit 32 when the paper proceeds and presses a rear end side of the paper-sheet 3′ when the paper finishes proceeding. The paper-sheet-reserving unit 32 stacks the paper-sheets 3′ and temporarily reserves them.
The shutter 83 is arranged near a paper-sheet-taking-out port of the paper-sheet-reserving unit 32 and shuts the transport of the paper-sheets 3′ to the paper-sheet transporting direction I when aligning the bundle of paper-sheets. Inside of the shutter 83 (at a side of the paper-sheet-reserving unit 32), a clamp member constituted of a movable upper arm 801b and a fixed lower arm 801a in the clamp movement mechanism 80 is opened and the paper-sheets 3′ are bound under this condition. When taking out the paper-sheets, the shutter 83 is opened and they are transported to a next step with the bundle of paper-sheets being clamped by the upper arm 801b and the lower arm 801a.
The paper-sheet curl pressing mechanism 31 shown in
The curl fence portions 34a, 34b are arranged at light and left near the paper-taking-out port of the paper-sheet-reserving unit 32. The curl fence portions 34a, 34b press the rear end side of the paper-sheet 3′ guided by the rear guide portions 304a, 304b and the curl guide portions 305a, 305b and operate to receive a forward end portion of a next paper-sheet 3′.
The light and left curl fence portions 34a, 34b are attached on a power transmission shaft (curl fence shaft) 307. A motor 301 is attached to an end of the power transmission shaft 307 through a reduction gear 309. The motor 301 constitutes an example of driving portion and rotates the curl fence portions 34a, 34b around a predetermined direction.
The curl fence portion 34a is constituted by including a disk-like rotation main body 341 and plural projections 342. The rotation main body 341 has an axis 341a. To the axis 341a, the power transmission shaft 307 is attached. On a circumferential portion of the rotation main body 341, for example, four projections 342 are arranged on every 90 degrees. Each of the projections 342 has a shape projecting toward a direction parallel to the axis 341a. Configuring the curl fence portion 34a as this enables curled paper-sheet 3′ to be pressed by any of the projections 342 during a period of paper-aligning-and-temporarily-reserving time.
For example, by rotating the projections 342 upwards for every time when the paper-sheet proceeds, it is possible to keep a condition in which a curled portion of the paper-sheets 3′ stacked is pressed. It is to be noted that the curl fence portion 34b is configured and functioned similar to the curl fence portion 34a with reference to a structure and a function thereof, thereby omitting the explanation thereof.
The rear guide portions 304a, 304b are arranged near the light and left curl fence portions 34a, 34b (see
Each of the above-mentioned rear guide portions 304a, 304b has a movable structure so as to have a paddle-like projection, not shown. Such a movable structure enables the paper-sheet 3′ to be guided up to a position just near any of the projections 342 and enables it to be prevented from being smashed against the projection 342 even if the curled paper-sheet 3′ proceeds, thereby allowing any jam based on this smash to be prevented.
The curl guide portions 305a, 305b are arranged under the power transmission shaft 307 that connects the above-mentioned curl fence portions 34a, 34b (see
It is configured that an upper guide 310 is attached to the guide-supporting rod 303b and guides the paper-sheet 3′ to the paper-sheet-reserving unit 32 with holding its rear end portion. The curl guide portions 305a, 305b are made by, for example, injection molding of resin and is provided with a bottom portion having R-surface with an arc of a circle. Of course, the curl guide portions 305a, 305b made of metal plate may be used. The size of each thereof is 20 mm to 30 mm in width and around 60 mm to 80 mm in length. The thickness thereof is around 8 mm to 10 mm. Such a configuration enables, when the curled paper-sheet 3′ proceeds, any force lifting this paper-sheet to be reduced, thereby allowing any jam because the curled paper-sheet 3′ proceeds to be prevented.
The above-mentioned rear guide portion 304a is engaged with a cam 311 that is linked with the curl fence portion 34a. When the paper-sheet finishes proceeding, it is configured so as to be retracted (waited) from a rotation locus of the curl fence portion 34a by means of the driving of the cam 311. It is configured that for example, the cam 311 of the rear guide portion 304a is connected by followering, which rotates together with the rotation of the curl fence portion 34a. Such a configuration allows the rear guide portion 304a to rotate at the same time when the curl fence portion 34a rotates and to be retracted from a rotation locus of the curl fence portion 34a when the paper-sheet finishes proceeding, thereby enabling it to be prevented from being interfered with the projection.
Further, the rear guide portion 304a is configured so as to be rotatable so that a position closely near the projection 342 can be even configured as a guide, which enables any jam to be prevented. It is to be noted that relating to the cam 311 and followering, the curl fence portion 34b is configured and operated similar to the curl fence portion 34a, thereby omitting the explanation thereof.
To the other end of the above-mentioned power transmission shaft 307, a disk 307a having a predetermined shape (in this embodiment, quatrefoil like one) is mounted, which is used for detecting a home position of the curl fence. A sensor for detecting the home position of the curl fence (hereinafter, referred to as “HP sensor 117”) is mounted at a position which is concerned with this disk 307a. It is configured that the HP sensor 117 detects a stop position of the curl fence portions 34a, 34b which are rotated by the motor 301. As the HP sensor 117, an optical sensor (a light-emitting-and-receiving device) of transmission type is used.
Inside the paper-sheet-taking-out port of the paper-sheet-reserving unit 32, which is shown in
In this embodiment, it is configured that on the downstream side of the side jogger 70, that is, near the paper-sheet-taking-out port in the unit body, an alignment-pin-driving mechanism 91 (see
Inside the paper-sheet outlet in paper-sheet-reserving unit 32, besides the side jogger 70, a supply roller 33 (not shown) and press rollers 38 are disposed (see
At the paper-sheet-taking-out port, the shutter 83 is provided, which operates to open and close the transport path, not shown, of the bundle of paper-sheets 3″ to the paper-sheet transporting direction I. For example, it is configured that if the shutter 83 is opened, with the above-mentioned supply roller 33 and press rollers 38, the bundle of paper-sheets 3″ is transported (discharged) along the paper-sheet transporting direction I. By thus configuring the rollers for taking out paper-sheets, even in a case where the bundle of paper-sheets 3″ is not bound with the binding component 43, it is possible to transport the bundle of paper-sheets 3″ to the next step in a condition where they are kept as a bundle.
The following will describe a configuration example of the side jogger 70 in the binder paper alignment unit 30 with reference to
The side jogger 70 shown in
The main body housing portion 71 is configured to have an upper surface site and a back surface site. The main body housing portion 71 is formed into a box-like body by folding back an iron plate. The upper surface site of the box-like body is open. In this embodiment, the back surface site of the main body housing portion 71 is arranged to be regions where the motors are to be installed. Its upper surface site is arranged to be a region for the movable stages.
In the region for the movable stages, the width-truing-up guide 72a, the width-truing-up reference guide 72b, the rails 73a and 73b, and the movable stages 75a and 75b are disposed. For example, the rails 73a and 73b are disposed in such a manner as to bridge the two wall surfaces inside the main body housing portion 71. The rails 73a and 73b are mounted so that two round rods are attached to positions going through the right-side end and the left-side end of the main body housing portion 71 respectively. With the rails 73a and 73b, a couple of movable stages 75a and 75b is engaged in such a manner that they can be moved in the right-and-left direction.
The movable stages 75a and 75b are made of, for example, molded resin and the movable stages 75a and 75b have openings (not shown) that are formed therein in such a manner as to pass through in the right-and-left direction, so that through these openings, the rails 73a and 73b may pass. Of course, the rails 73a and 73b are not limited to an aspect that they may pass through the openings but may be of such an aspect that the movable stages 75a and 75b may be fitted with drive wheels so as to travel on the rails 73a and 73b.
The movable stage 75a is fitted with the width-truing-up reference guide 72b at its upper left end, while it is fitted with the width-truing-up guide 72a at its upper right end. As the width-truing-up guide 72a and the width-truing-up reference guide 72b, for example, an iron plate which is folded back into a deformed U-shape and treated may be used. The width-truing-up guide 72a and the width-truing-up reference guide 72b are formed in such a manner that they may become larger on the upstream side and smaller on the downstream side in width. This is done so in order to guide the curled paper-sheet 3′ up to the forward end of the paper-sheet-reserving unit 32 with a good reproducibility.
The upstream sides of the width-truing-up guide 72a and the width-truing-up reference guide 72b have shapes (flaps) whose upper end portion is jumped up and the lower end portions thereof have shapes which droop oppositely in order to guide paper. These shapes are formed to guide the paper-sheet 3′ sent over from the punching process unit 20 to the clamp movement mechanism 80 together with the paddle roller 37.
Further, in the motor installing regions arranged on the back surface site of the main body housing unit 71, the motors 74a and 74b are installed. As the motors 74a and 74b, a stepping motor may be used respectively. The motors 74a and 74b are arranged so that their motor rotary shafts may pass from the back surface site of the main body housing unit 71 through the upper surface site thereof.
In this embodiment, on the side of the upper surface site of the man body housing portion 71, driven pulleys 77a and 77b are mounted. Between the belt driving pulley 76a and the driven pulley 77a, a non-terminal belt 78a is engaged. Similarly, between the belt driving pulley 76b and the driven pulley 77b, a non-terminal belt 78b is engaged.
Such a configuration can be given that by engaging portions of the belts 78a and 78b with the movable stages 75a and 75b so as to enable belt-driving the movable stages 75a and 75b respectively, the width-truing-up guide 72a and the width-truing-up reference guide 72b can be moved in a direction perpendicular to the paper-sheet transport direction.
The following will describe a configuration example of the alignment-pin-driving mechanism 91 with reference to
The alignment-pin-driving mechanism 91 is equipped to a main body board 900, which provides a base for the binder paper alignment unit 30 and a base for the clamp movement mechanism 80, and configured to have the alignment pins 85a and 85b, a motor 89, an alignment pin home position sensor (hereinafter referred to as an “HP detection sensor 93”), and an alignment pin upper end detection sensor (hereinafter referred to as an “upper end detection sensor 94”).
The main body board 900 is provided with a right edge frame 92a (right edge side surface frame) and a left edge frame 92b (left edge side surface frame) having predetermined shapes on both sides thereof respectively. In this embodiment, the right edge frame 92a has two sliding grooves 921 and 922, while the left edge frame 92b has two sliding grooves 923 and 924. To these sliding grooves 921 to 924, the paper-sheet fixation and movement section 880 shown in
In this embodiment, an iron plate which is folded back may be used as the main body board 900 which is mounted so that it supports the right-edge and left-edge frames 92a and 92b. The right-edge and left-edge frames 92a and 92b are provided with motor-mounting areas, the right-edge frame 92a is provided with a mounting area for a clamper 82a and the left-edge frame 92b is provided with a mounting area for a clamper 82b, respectively.
The right-edge frame 92a shown in
Thus, it is possible to produce a restricted condition of the lower arms 801a of the right and left end sides when aligning the bundle of paper-sheets and it is possible to release the restricted condition of the lower arms 801a when moving the bundle of paper-sheets. Furthermore, when moving the bundle of paper-sheets, the bundle of paper-sheets 3″ is apart from a bottom of the bundle-of-paper-sheets transport path of the binder paper alignment unit 30 so that any flexion occurred in the bundle of paper-sheets 3″ when guiding it to a predetermined position (a center) of the binding process unit 40 can be reduced. This enables the bundle of paper-sheets 3″ to be prevented from being scratched, damaged or shared in the paper-sheets.
Further, it is configured that the main body board 900 is fitted with the motor 89 for the alignment pins, which drives the alignment pins 85a and 85b upward and downward. As the motor 89, a DC motor is used. The motor 89 is engaged with a decelerating gear 98 (gear unit), which converts the motor rotation number at a predetermined decelerating ratio. The decelerating gear is engaged with an up-down rack member (hereinafter referred to as an UD rack 95), which moves up and down based on a torque converted at the predetermined decelerating ratio.
To one end of the UD rack 95, a plate 97 having a predetermined shape is connected. To the other end of the plate 97, arms 99a and 99b having predetermined shapes are engaged commonly around a rotary shaft. It is configured that the arms 99a and 99b may be opened in an X-shape or closed in a straight-line shape with respect to the rotary shaft, a center of which is supported by the rotary shaft (see
In this embodiment, one end of each of the arms 99a and 99b is engaged with the main body board 900 at its predetermined position in a rotatable and slidable manner. The other end of each of the arms 99a and 99b is engaged with a link 96 having a predetermined shape in a rotatable and slidable manner. The link 96 has, for example, an inverted π shape so that the other end of the arm 99a is engaged with one end of the inverted π shape in a rotatable and slidable manner and the other end of the arm 99b is engaged with the other end thereof in a rotatable and slidable manner.
With one end portion of the link 96, the alignment pin 85a is engaged and with the other end portion of the link 96, the alignment pin 85b is engaged. The alignment pins 85a and 85b constitute one example of bar-shaped bodies for alignment, and it is configured that they align the punched holes 3a in the bundle of paper-sheets 3″ temporarily reserved in the paper-sheet-reserving unit 32. For example, the alignment pins 85a and 85b are inserted into predetermined two of the punched holes 3a in the bundle of paper-sheets 3″ (see
It is to be noted that the HP detection sensor 93 is fitted to a predetermined position of the left edge frame 92b and detects a home position (lower edge) of each of the alignment pins 85a and 85b to output an HP detection signal S93. In the left edge frame 92b, the upper end detection sensor 94 is fitted to a predetermined position thereof above the HP detection sensor 93 and detects an upper edge position of each of the alignment pins 85a and 85b to output an upper end detection signal S94 (see
Here, a description will be given of an operation example of the alignment pins 85a and 85b in the alignment-pin-driving mechanism 91 with reference to
According to the operation example in the alignment-pin-driving mechanism 91 before the pins pass through as shown in
The following will describe an operation example in the alignment-pin-driving mechanism 91 when pins pass through. In
If the UD rack 95 moves upward, the rotary shaft of the arms 99a and 99b placed in the closed state is pulled upward. If the rotary shaft of the arms 99a and 99b is pulled upward, the arms 99a and 99b are opened in the X-shape. If the arms 99a and 99b are opened in the X-shape, the link 96 is pulled upward. If the link 96 is pulled upward, the alignment pins 85a and 85b are pulled upward. As a result thereof, the alignment pins 85a and 85b pass through the punched holes 3a in the bundle of paper-sheets 3″. The upper end detection sensor 94 detects the upper end position of the alignment pins 85a and 85b and outputs the upper end detection signal S94 to the control unit 50. It is thus possible to insert the alignment pins 85a and 85b into the punched holes 3a, thereby aligning the bundle of paper-sheets 3″.
The following will describe a configuration example of the clamp movement mechanism 80 as a first embodiment in the binder paper alignment unit 30 with reference to
The paper-sheet fixation and movement section 880 and a clamp-opening-and-closing driving section 881 constitute separated structures. In this embodiment, when the bundle of paper-sheets is aligned, the paper-sheet fixation and movement section 880 and a clamp-opening-and-closing driving section 881 are engaged with each other while when the bundle of paper-sheets is moved, the paper-sheet fixation and movement section 880 and a clamp-opening-and-closing driving section 881 are separated from each other. This is because the paper-sheet fixation and movement section 880 can drop by its weight to the binding process unit 40 with the bundle of paper-sheets 3″ being fixed.
The paper-sheet fixation and movement section 880 is movably mounted with respect to the right edge frame 92a and the left edge frame 92b on both sides of the main body board 900 and operates to hold and fix the bundle of paper-sheets 3″ or freely release it independently of the clamp-opening-and-closing driving section 881. The paper-sheet fixation and movement section 880 has a right end side clamp member (hereinafter merely referred to as a “clamper 82a”) and a left end side clamp member (hereinafter merely referred to as a “clamper 82b”). Each of the clampers 82a, 82b has a lower arm 801a which constitutes one example of the fixing clamp member and an upper arm 801b which constitutes one example of the movable clamp member. It is configured that the upper arm 801b can be moved on an up and down direction.
For example, the lower arm 801a and the upper arm 801b are disposed at the respective right and left end sides of the binder paper alignment unit 30 and the upper arm 801b is driven so as to be closed for each one paper-sheet or each plural paper-sheets when aligning the bundle of paper-sheets for aligning the paper-sheets 3′. It is thus possible to correct the curl of the paper-sheet 3′. It is configured that the paper-sheet fixation and movement section 880 also moves with the bundle of paper-sheets 3″ being fixed when the bundle of paper-sheets is moved. In this embodiment, it is configured that the bundle of paper-sheets 3″ is released from the fixation when the bundle of paper-sheets is aligned and after the alignment-by-pins has been performed, the bundle of paper-sheets 3″ is moved toward a downstream side from a paper-sheet curl pressing mechanism 31 along the paper-sheet transport direction with an end thereof at a side of punch holes being fixed.
In this embodiment, when the bundle of paper-sheets is aligned, the upper arm 801b stops while being opened to an arbitrary intermediate position which is a larger width than a thickness of the bundle of paper-sheets 3″ and is smaller than a height of the bundle-of-paper-sheets-transporting path and waits at this position until it is detected by the upper end detection sensor 94 that the alignment pins 85a, 85b have reached the upper edge position. The left end side clamper 82b is also configured similarly.
It is configured that in the paper-sheet fixation and movement section 880, a spring 816 constituting an example of an urging member is mounted on the lower arm 801a and the upper arm 801b so that when the bundle of paper-sheets is aligned, the upper arm 801b is urged to a side of the fixed lower arm 801a to hold a clamp closing situation. When the bundle of paper-sheets is moved, it is configured so as to be always urged to a closing direction in order to hold the bundle of paper-sheets 3″.
On the clamper 82a mounted on a right end side of the above-mentioned main body board 900, a joint plate 801 with limiting holes, which constitutes one example of a clamp-attaching board, is mounted. The joint plate 801 has a sword-pointed shape (a forward end sword-pointed shape) in which the forward end is pointed) and has an axis hole 807a on an end thereof and a long hole 808a at a predetermined position on the other end thereof. The joint plate 801 also has elongated limiting holes 806a, 806b to regulate clamp opening and closing.
The clamper 82a is configured to have the lower arm 801a and the upper arm 801b. With one end of the lower arm 801a, the lower shaft 804 is movably fitted. With one end of the upper arm 801b, the upper shaft 803 is movably fitted.
The clamper 82b facing the clamper 82a is provided with a joint plate having a similar sword-pointed shape and having an axis hole 807a on an end thereof and a long hole 808a at a predetermined position on the other end thereof. The other ends of the lower arm 801a and upper arm 801b at the left end side are engaged with an axis hole 807b of the joint plate 802 with the limiting holes, the other ends of the lower arm 801a and upper arm 801b at the right end side are engaged with an axis hole 807a of the joint plate 801 with the limiting holes and fulcrums each shared by the end of the lower arm 801a and the end of the upper arm 801b are movably engaged via a fulcrum shaft member 805 at right and left end sides.
The lower shaft 804 provided on the other edge of the lower arm 801a at the right end side is movably fitted into the limiting hole 806a having a long hole shape and similarly, the upper shaft 803 provided on the other edge of the upper arm 801b at the right end side is movably fitted into the limiting hole 806b having a long hole shape. The lower shaft 804, not shown, provided on the other edge of the lower arm 801a at the left end side is movably fitted into the limiting hole 806a of the joint plate 802 and similarly, the upper shaft 803 provided on the other edge of the upper arm 801b at the left end side is movably fitted into the limiting hole 806b of the joint plate 802.
In this embodiment, on the joint plates 801, 802 at right and left end sides, it is assembled so as to expose an edge portion of the lower shaft 804 at the limiting hole 806a and to expose an edge portion of the upper shaft 803 at the limiting hole 806b, respectively. It is thus possible to move the upper shaft 803 and the lower shaft 804 within the limiting holes 806a, 806b along a direction (hereinafter, referred to as a “clamp-opening-and-closing direction”) perpendicular to the paper-sheet transporting direction in the joint plate 801 at the right end side. It is also possible to move the upper shaft 803 and the lower shaft 804 within the limiting holes 806a, 806b each having a long hole shape along the clamp-opening-and-closing direction in the joint plate 802 at the left end side.
The configuration members of the clamper 82b that are similar to those of the clamper 82a are formed similar to those of right end side so that the description thereof will be omitted. The clamper 82b and the clamper 82a are engaged with each other by their rear edges via the above-mentioned fulcrum shaft member 805 and at their front edges, the upper shaft 803 and the lower shaft 804 are movably engaged with the joint plates 801 and 802 with the limiting holes.
Further, the clampers 82a, 82b have a structure such that it moves toward a downstream side with respect to the main body board 900 along the paper-sheet transport direction I with the bundle of paper-sheets 3″ being fixed. For example, it is configured that predetermined parts of the clamp movement mechanism 80 are movably engaged with the two sliding grooves 931, 922 of the right edge frame 92a and the two sliding grooves 932, 924 of the left edge frame 92b, which are shown in
The clamp-opening-and-closing driving section 881 is mounted on the main body board 900 or the right edge frame 92a and the left edge frame 92b, which are positioned at both sides thereof, and drives the upper arms 801b of the left end side and the right end side. For example, the clamp-opening-and-closing driving section 881 is configured to include a motor 86, cams 87a, 87b and a gear unit 88 which are used for opening the upper arms 801b and pushes (moves) the upper arms 801b up to a predetermined position with respect to the lower arms 801a to release the bundle of paper-sheets 3″ when the bundle of paper-sheets is aligned. Each of the cams 87a, 87b has a deformed ellipse shape in which two arcs of circles (curved parts) that are different from each other in a radius and a projection shape between the arcs of circles having the different radii are formed (see
In this embodiment, the clamp-opening-and-closing driving section 881 keeps the clamp-opening situation by exceeding the urging force by the spring 816 shown in
The clamp-opening-and-closing driving section 881 operates to start movement of the upper arms 801b with respect to the lower arms 801a at the same time when the alignment-pin-driving mechanism 91 passes the alignment pins 85a, 85b through the punch holes of the paper-sheets 3′. It is thus possible to reduce any frictional resistance between the paper-sheets. Further, by setting the retracted position of the upper arms 801b with respect to the lower arms 801a to an intermediate position, the bundle of paper-sheets can be aligned without lifting the paper-sheets 3′ by the alignment pins 85a, 85b so that it is possible to reduce any variations in the conditions of the paper-sheets 3′. Here, the intermediate position is referred to as a position between the clamp-closing position and the clamp-complete-opening position.
The motor 86 of the clamp-opening-and-closing driving section 881 is mounted in a motor mounting region provided inside the left edge frame 92b shown in
Each of the upper arms 801b of the clampers 82a, 82b includes a roller 826 for opening and closing the clamp. Each roller 826 forms a cam operative region and is engaged with the cam 87a or 87b so as to receive any force from the clamp-opening-and-closing driving section 881, thereby opening the upper arms 801b.
For example, when the bundle of paper-sheets is aligned, the motor is driven in the clamp-opening-and-closing driving section 881 so that the cams 87a, 87b are driven through the gear unit 88. The cam 87a pushes the roller of the upper arm 801b of the right end side to open the clamper 82a of the right end side and the cam 87b pushes the roller 826 of the upper arm 801b of the left end side to open the clamper 82b of the left end side. In this embodiment, the clamp-opening-and-closing operation is performed by attaching the rollers 826 to the cams 87a, 87b with cooperation of the springs 816.
When the bundle of paper-sheets is moved (in the bind process), the cams 87a, 87b are driven so that the upper arms 801b can be retracted from the rollers 826, thereby causing them to be closed by the springs 816 to hold the bundle of paper-sheets 3″. In this condition, the rollers 826 of the paper-sheet fixation and movement section 880 and the cams 87a, 87b of the clamp-opening-and-closing driving section 881 are disengaged with each other, so that the clampers 82a, 82b can be moved to the binding process unit 40 with the bundle of paper-sheets being held. It is thus configured that the respective clampers 82a, 82b are opened or closed in synchronization with them.
When aligning the bundle of paper-sheets, the paper-sheet fixation and movement section 880 and the clamp-opening-and-closing driving section 881 are connected through the rollers 826 and the cams 87a, 87b and when moving the bundle of paper-sheets (in the bind process), it is separated from the clamp-opening-and-closing driving section 881 so that the clampers 82a, 82b are always closed, thereby enabling the condition in which the bundle of paper-sheets 3″ is held to be kept. Namely, when the paper-sheet fixation and movement section 880 is separated from the clamp-opening-and-closing driving section 881, the condition in which the bundle of paper-sheets 3″ is fixed is kept so that it can drop by its weight to the binding process unit 40 under this condition.
It should be noted that the alignment-pin-driving mechanism 91 shown in
A shutter 83 is movably mounted on the front face of the main body board 900 and operates so as to limit the release of the bundle of paper-sheets 3″ stored in the paper-sheet-reserving unit 32. It is configured that the shutter 83 is driven up and down in the direction perpendicular to the transporting direction of the bundle of paper-sheets 3″. It is configured that sliding and guiding members 811, 812 are provided on both sides of the shutter 83 and the shutter 83 slides along the sliding and guiding members 811, 812. In this embodiment, when the clampers 82a, 82b make the bundle of paper-sheets 3″ to be in a free release state, it is possible to stop the natural drop of the bundle of paper-sheets 3″ by closing the shutter 83.
The shutter 83 is mounted on a solenoid via a driving shaft, which is not shown, and it is configured that the shutter 83 opens and closes by the reciprocating movement thereof. Of course, it is not limited to this and the shutter 83 can open and close by converting a rotational movement of the motor, which is not shown, to a reciprocating movement thereof.
Also, the alignment-pin-driving mechanism 91 is provided inside the front surface part of the main body board 900 and the alignment pins 85a, 85b are driven upward and downward. In this embodiment, it is configured that by passing the alignment pins 85a, 85b into the punch holes 3a of the bundle of paper-sheets 3″ before the binding process, the positions thereof are realigned. The front edges of respective alignment pins 85a, 85b have conical shapes. For example, the bundle of paper-sheets 3″ is made to be sandwiched and held between the upper portion pressing member 84a and the lower portion pressing member 84b before inserting the alignment pins 85a, 85b as shown in
Here, a description will be given of a configuration example of the comb-shaped pressing members 84a, 84b with reference to
In this embodiment, the comb-shaped upper part pressing member 84b shown in
The comb-shaped sites are formed with a mixture of long tooth sites 847 and short tooth sites 848. The long tooth sites 847 are arranged so as to project forward more than the edge portion of the bundle of paper-sheets 3″, while the short tooth sites 848 is arranged so as to project short of the edge portion of the bundle of paper-sheets 3″. This is done so in order to fit the long tooth sites 847 into sites selectively opened in the shutter 83, thereby improving an accuracy at which the upper part pressing member 84b and the lower part pressing member 84a are held and fixed and the function of closing the shutter.
In this embodiment, in order to align the positions of the holes in the bundle of paper-sheets 3″ by using the alignment pins 85a, 85b, the clampers 82a, 82b are opened in a condition where the shutter 83 shown in
The following will describe an example of a pantograph structure of the paper-sheet fixation and movement section 880 in the clamp movement mechanism 80 with reference to
In this embodiment, the lower shaft (a shaft) 804 on the lower arm 801a and the upper shaft (a shaft) 803 on the upper arm 801b are respectively engaged with one ends of isometric link members 813a, 813b as well as the other ends of the corresponding isometric link members 813a, 813b are engaged with the long hole 808a (see
Although not shown, on the other side, the lower shaft 804 on the lower arm 801a and the upper shaft 803 on the upper arm 801b are respectively engaged with one ends of isometric link members 813a, 813b as well as the other ends of the corresponding isometric link members 813a, 813b are engaged with the long hole 808b of the joint plate 802 via an engaging member 809b, which results in a fact that the paper-sheet fixation and movement section 880 forms a pantograph structure.
In this embodiment, it is configured that in each of the joint plates 801, 802, the upper arm 801b and the lower arm 801a are linked by the isometric link members 813a, 813b having the pantograph structure so that the engaging member 809a of the isometric link members 813a, 813b is always positioned at a center of the upper arm 801b and the lower arm 801a.
Such a pantograph structure enables a fulcrum of the isometric link members 813a, 813b of one side to be connected with the joint late 801 by the engaging member 809a and enables a fulcrum of the isometric link members 813a, 813b of the other side to be connected with the joint plate 802 by the engaging member 809b, which is not shown, whereby allowing a center position of the bundle of paper-sheets 3″ to be directly guided to the movement mechanism 41 for the binding process in the binding process unit 40, thereby enabling a guide structure of the center position of the bundle of paper-sheets 3″ to be simplified. Further, the center position varies linearly based on a thickness of the bundle of paper-sheets 3″ so that complex process and control become unnecessary.
A roller member 817 is provided at a forward end side of the joint plate 801 that has the engaging member 809a engaging with such isometric link members 813a, 813b and a roller member 818 is also provided at a forward end side of the joint plate 802, as shown in
In this embodiment, the fulcrum shaft member 805 is movably engaged with the sliding grooves 922 and 924 having long hole shapes as shown in
In this embodiment, on the joint plate 802 shown in
In the lead plate 801′ provided on the above-mentioned joint plate 801, a roller member 827 is provided at a lower end thereof. The roller member 827 is engaged with a cam 402 having a fan shape, which is provided on the movement mechanism 41.
A shape of the cam 402 has a part of an arc of a circle centering around the movement mechanism rotating axis 41d shown in
Thus, by configuring the clamp movement mechanism 80 and its peripheral mechanism and attaching the main body board 900, the right edge frame 92a and the left edge frame 92b to which these parts are attached to a chassis 45 of the binding process unit 40, the paper-sheet alignment and binding processing unit 110 as one block can be configured.
The following will describe a connection example of the paper-sheet fixation and movement section 880 and the movement mechanism 41 in the paper-sheet alignment and binding processing unit 110. It is configured that the binding process unit 40 is provided on a downstream side of the clamp movement mechanism 80 shown in
It is configured that when moving the bundle of paper-sheets, the binding process unit 40 receives the binding component 43 from the binder cassette 42 and is moved from the downward direction of the binder cassette 42 to the downward direction of the binder paper alignment unit 30 as well as the cam 402 is brought downwards by the movement mechanism 41 so that the paper-sheet fixation and movement section 880 is configured to drop by its weight from its home position HP′ to a retracted position of the cam 402. In this moment, by the openings 44a, 44b (engaging portions) each having Y-shape which are provided on a forward end of the movement mechanism 41, the roller members 817, 818 provided on the lower end of the paper-sheet fixation and movement section 880 are received.
When the binding component 43 is attached to the bundle of paper-sheets 3″ by the movement mechanism 41, the cam 402 is lifted upwards and the movement mechanism 41 is retracted to the downward direction of the binder cassette 42 so that the paper-sheet fixation and movement section 880 returns to its home position HP′ and the lower arm 801a and the upper arm 801b become movable when delivering the booklet.
Thus, the roller members 817, 818 are engaged with the openings 44a, 44b each having Y-shape in the binding process unit 40 with a self-aligning method when moving the bundle of paper-sheets (in the binding process) so that it is possible to link the clamp-opening operation conforming with an operation timing of a ring binding by the binding process unit 40. In this embodiment, a center position of the bundle of paper-sheets 3″ is guided to a center position of the binding component 43 when performing the binding process by the binding component 43 on the bundle of paper-sheets and the binding process in which the binding component 43 is certainly bound with the bundle of paper-sheets 3″ can be performed.
The following will describe operation examples in the clamp movement mechanism 80 with reference to
In the embodiment, according to the operation example (part one) in the clamp movement mechanism 80, an assumption is a case where each time the paper-sheet 3′ comes in the paper-sheet-reserving unit 32 and butts against the shutter 83 in a condition where the shutter 83 shown in
According to the operation example when aligning the bundle of paper-sheets in the clamp movement mechanism 80 shown in
In this embodiment, the comb-shaped upper part pressing member 84a attached to the upper shaft 803 and the comb-shaped lower part pressing member 84b attached to the lower shaft 804, which are shown in
In this moment, the cams 87a and 87b take on a predetermined posture at a cam retracting position Pc (non-home position). For example, it is a condition where protrusions of the cams 87a and 87b face right beside. This condition is a condition where the clampers 82a and 82b are closed by the urging force of the spring 816 shown in
In this embodiment, it is configured that a home position sensor 821 (hereinafter referred to as an HP sensor 821) for clamping is disposed near the cam 87b and detects a home position (HP) of the clamper 82b etc. to output a home position detection signal (hereinafter referred to as a cam HP detection signal S21) to the control unit 50. The home position HP of the clamper 82b is set to a position (clamp closing position) to which the upper arms 801b have moved lower most. The clamper 82a is also set similarly and its description will be omitted.
Further, a paper-sheets thickness detection sensor 822 is disposed on the main body board 900 and a slit portion 823 is formed in each of the upper arms 801b and may be used in conjunction with this paper-sheets thickness detection sensor 822. As the paper-sheets thickness detection sensor 822, a transmission type photo-sensor is used.
For example, the slit portion 823 includes slit shapes having a predetermined pitch therebetween, so that each time the bundle of paper-sheets 3″ reaches a constant thickness, an edge of any upper arm 801b is detected by the paper-sheets thickness detection sensor 822, and the upper arms 801b perform opening and closing operations, thereby detecting the thickness of the paper-sheets. An amount when closing and opening the clampers 82a, 82b varies based on the thickness of the bundle of paper-sheets so that by detecting the edge thereof, it is possible to detect the thickness of the bundle of paper-sheets 3″. It is thus configured that the paper-sheets thickness detection sensor 822 detects the thickness of the paper-sheets 3″ coming into the binder paper alignment unit 30 and stacked (bundled) there and output a paper thickness detection signal (not shown) to the control unit 50. It should be noted that the clamp position is positioned at a position where the binding component 43 is bound so that it is possible to detect the thickness when performing the binding operation accurately.
A 50-paper-sheets thickness detection sensor (hereinafter referred to as a 50-sheets sensor 824) is also disposed on the main body board 900 adjacent to the paper-sheets thickness detection sensor 822 and a light blocking unit 825 is mounted on the upper arms 801b and used in conjunction with this 50-sheets sensor 824. It is configured that the 50-sheets detection sensor 824 detects a thickness of the paper-sheets 3″ when they are stacked as many as 50 sheets and output a 50-sheets detection signal S42 to the control unit 50.
According to the operation example (part two) when aligning a bundle of paper-sheets in the clamp movement mechanism 80 shown in
In the clamp movement mechanism 80, the cams 87a and 87b take on predetermined postures at a clamp opening position (home position HP) thereof. For example, in a condition where the clampers 82a and 82b shown in
In this moment, at each of the clampers 82a and 82b, the protrusion of the cam 87a is pressed by the roller 826 of the lower arm 801a and the protrusion of the cam 87b is pressed by the roller 826 of the upper arm 801b, thereby opening the clampers 82a and 82b synchronously with each other. In the joint plates 801 and 802 having the limiting holes, the lower arm 801a and the upper arm 801b operate to open by using the fulcrum shaft member 805 as a movable reference. In this moment, the lower shaft 804 and the upper shaft 803 are limited in movement by the elongated limiting holes 806a and 806b in the joint plates 801 and 802, so that a width to which the clamps are opened may be limited in the joint plates 801 and 802. The driving force is transmitted to the lower shaft 804 attached to the lower arms 801a movably and the upper shaft 803 attached to the upper arms 801b movably.
As a result thereof, the bundle of paper-sheets 3″ is released free by the comb-shaped upper part pressing member 84b attached to the upper shaft and the comb-shaped lower part pressing member 84a attached to the lower shaft 804. Even if these clampers 82a and 82b makes the bundle of paper-sheets 3″ free released, the bundle of paper-sheets 3″ may be prevented from falling naturally because the shutter 83 is closed.
Then, it is configured that the motor 89 is driven and the normal-directional rotation movement of the motor 89 is converted into a pin raising movement by the alignment-pin-driving mechanism 91 shown in
According to the operation example (part three) when aligning a bundle of paper-sheets in the clamp movement mechanism 80 shown in
According to the clamp movement mechanism 80, the cams 87a and 87b stay in a condition where they have returned from the clamp releasing position (home position HP) to the cam retracting position Pc and their protrusions face right beside. In this condition, the motor 86 rotates reversely and transmits the motor torque to the cams 87a and 87b via the gear unit 88 in which rotation number is converted to a predetermined gear ratio. Then, it is based on a result such that the cams 87a and 87b have rotated by 90 degrees counterclockwise from the clamp releasing position (home position HP) to return to the cam retracting position Pc thereof.
Through the cam retracting operations, the clampers 82a and 82b take on predetermined postures at arbitrary positions in accordance with the thickness of the bundle of paper-sheets 3″ owing to the urging force of the spring (not shown). For example, at the clampers 82a and 82b, respectively, the protrusion of the cam 87a is not pressed by the roller 826 of the lower arm 801a and the protrusion of the cam 87b is not pressed by the roller 826 of the upper arm 801b, thereby closing the clampers 82a and 82b synchronously with each other.
In the joint plates 801 and 802, the lower arm 801a and the upper arm 801b operate so as to be closed by using the fulcrum shaft member 805 as a movable reference. The driving force is transmitted to the lower shaft 804 movably attached to the lower arm 801a and the upper shaft 803 movably attached to the upper arm 801b. As a result thereof, the bundle of paper-sheets 3″ may be held and fixed by the comb-shaped upper part pressing member 84b attached to the upper shaft 803 and the comb-shaped lower part pressing member 84a attached to the lower shaft 804.
Then, it is configured that the motor 89 is driven and its reverse-directional rotation movement is converted into a lowering movement by the alignment-pin-driving mechanism 91 shown in
According to the operation example (part four) when aligning the bundle of paper-sheets in the clamp movement mechanism 80 shown in
Here, a supplemental description will be given of a movement example of the paper-sheet fixation and movement section 880 with reference to
Lifting power of the paper-sheet fixation and movement section 880 in this moment is given by the movement mechanism 41 of the binding process unit 40. For example, by lifting the cam 402 having the fan shape of the movement mechanism 41, the roller member 827 is lifted up. This causes the paper-sheet fixation and movement section 880 to return to its home position HP′. In order to discharge the booklet, the lower arms 801a and the upper arms 801b are then made movable.
The following will describe a configuration example of a control system of the binder paper alignment unit with reference to
The motor drive units 35 and 36, the HP detection sensor 93 for the alignment pins, the upper end detection sensor 94, an HP sensor 115 for the press rollers, an HP sensor 117 for the curl fence, the paper-sheet detection sensor 119, a discharge roller drive unit 122, motor drive units 180 to 185, and the HP sensor 821 for clamping are connected to the control unit 50 shown in
The paper-sheet detection sensor 119 detects the paper-sheet 3′ discharged from the punch processing unit 20 and outputs a paper-sheet detection signal S19 to the control unit 50. Based on the paper-sheet detection signal S19, the control unit 50 controls the motor drive units 35 and 36 and the motor drive units 180 to 185. For example, it outputs a motor control signal S36 to the motor drive unit 36 based on the paper-sheet detection signal S19.
A discharge roller rotating motor 205 is connected to the discharge roller drive unit 122. The discharge roller drive unit 122 receives a motor control signal S22 from the control unit 50 to drive the motor 205 so that the discharge roller 25 may rotate. The paper-sheet 3′ discharged from the punch processing unit 20 is transported by the rotation of the discharge roller 25 to come into the binder paper alignment unit 30.
The HP sensor 117 detects a position of any protrusions 342 on the curl fence unit 34b etc. and outputs a home position (hereinafter referred to as an HP) detection signal S17 to the control unit 50. The control unit 50 outputs a motor control signal S35 to the motor drive unit 35 based on the paper-sheet detection signal S19 and the HP detection signal S17.
A curl fence rotating motor 301 is connected to the motor drive unit 35. The motor drive unit 35 receives the motor control signal S35 from the control unit 50 to rotate the motor 301, thereby driving the curl fence units 34a and 34b. A paddle roller rotating motor 708 is connected to the motor drive unit 36. The motor drive unit 36 receives a motor control signal S36 from the control unit 50 to rotate the motor 708, thereby driving the paddle roller 37.
A motor 308 for the movement mechanism in the binding process unit 40 is connected to the motor drive unit 180. The motor drive unit 180 receives a motor control signal S80 from the control unit 50 to rotate the motor 308, thereby driving the movement mechanism 41. For example, it is configured that the clamp movement mechanism 80 opens the shutter 83 and lowers the fan-shaped cam 402 of the movement mechanism 41 so that the paper-sheet fixation and movement section 880 sandwiching the bundle of paper-sheets 3″ can be lowered and moved to a next step. Then, it is configured that the paper-sheet fixation and movement section 880 rises and releases the bundle of paper-sheets 3″ and closes the shutter 83 after the bundle of paper-sheets has been discharged.
The HP sensor 821 for clamping detects the clamp releasing position of the clamp movement mechanism 80. In the embodiment, it detects the home position HP of the cam 87a and 87b with respect to the home position (HP) of the clampers 82a and 82b or the like and outputs the cam HP detection signal S21 to the control unit 50. When aligning the bundle of paper-sheets, the control unit 50 controls the clamp member moving motor 86 via the motor drive unit 181 based on the cam HP detection signal S21.
The clamp member moving motor 86 is connected to the motor drive unit 181. The motor drive unit 181 receives a motor control signal S81 from the control unit 50 to drive the motor 86, thereby driving the clamp members such as the lower arm 801a and the upper arm 801b etc. When aligning the bundle of paper-sheets, the clamp members are opened. In the case of sandwiching the bundle of paper-sheets 3″, the clamp members are closed.
The HP detection sensor 93 detects the home position HP of the alignment pins 85a and 85b and outputs a pin HP detection signal S93 to the control unit 50. The home position HP of the alignment pins 85a and 85b is referred to as a position brought down from the paper-sheet alignment surface by a predetermined distance. The alignment pins 85a and 85b are arranged to wait at this position. The upper end detection sensor 94 detects an upper end of the alignment pins 85a and 85b and outputs a pin top detection signal S94 to the control unit 50. When aligning the bundle of paper-sheets, the control unit 50 controls the pin member moving motor 89 via the motor drive unit 182 based on the pin HP detection signal S93 and the pin top detection signal S94.
The alignment pin driving motor 89 is connected to the motor drive unit 182. The motor drive unit 182 receives a motor control signal S82 from the control unit 50 to rotate the motor 89, thereby driving the decelerating gear 98, the UD rack 95, the link 96, the X-shaped arms 99a and 99b, the alignment pins 85a and 85b, etc. When aligning the bundle of paper-sheets, the alignment pins 85a and 85b are inserted into the punched holes 3a in the bundle of paper-sheets 3″.
The motors 74a and 74b for the side jogger are connected to the motor drive unit 183. The motor drive unit 183 receives the motor control signal from the control unit 50 to rotate the motors 74a and 74b, thereby driving the side jogger 70. It is configured that when aligning the bundle of paper-sheets, the width-truing-up guide 72a and the width-truing-up reference guide 72b of the side jogger 70 true up the width direction of the bundle of paper-sheets 3″. When discharging the bundle of paper-sheets, the width-truing-up guide 72a and the width-truing-up reference guide 72b are retracted.
The HP sensor 115 detects the position of the press rollers 38 and outputs a roller detection signal S15 to the control unit 50. Home position of the press rollers 38 is referred to as a position lifted from the paper-sheet alignment surface by a predetermined distance. The press rollers 38 are arranged to wait at this position. When discharging the bundle of paper-sheets, the control unit 50 controls the supply roller and the press rollers 38 based on the roller detection signal S15.
A press roller moving motor 814 is connected to the motor drive unit 184. The motor drive unit 184 receives a motor control signal S84 from the control unit 50 to rotate the motor 814, thereby driving the press rollers 38. A supply roller rotating motor 815 is connected to the motor drive unit 185. The motor drive unit 185 receives the motor control signal S85 from the control unit 50 to rotate the motor 815, thereby driving the supply roller 33. It is configured that when discharging the bundle of paper-sheets, the above-mentioned supply roller 33 and press rollers 38 send the bundle of paper-sheets 3″ to a next step with a pressure being applied to it from its right surface and back surface sides.
The following will describe a control example when aligning the paper-sheets in the paper-sheet-handling device 100 with reference to
Under such control conditions, at step ST1 of a flowchart shown in
At step ST4, the upper arms 801b of the joint plates 801 and 802 are released up to a predetermined position thereof. In the embodiment, the lower arms 801a are fixed and only the upper arms 801b are driven. In the paper-sheet fixation and movement section 880, it is configured that the lower shaft 804 for the lower arms 801a is fitted and fixed into the V-shaped grooves 925 and 926 of the right-and left-edge frames 92a and 92b so that the lower arms 801a at right and left end sides are arranged to be flat-surfaced with the running surface of the paper-sheet-reserving unit 32.
Further, the upper arms 801b at right and left end sides are always urged toward their closing direction by the springs 816 and by the cam driving in the clamp-opening-and-closing driving section 881, the opening-and-closing operation is performed. In the embodiment, the clamp-opening-and-closing driving section 881 opens the upper arms 801b to the intermediate position thereof to facilitate the alignment of the bundle of paper-sheets 3″. In this moment, the alignment pins 85a and 85b are retracted to the outside of the bundle-of-paper-sheets transporting path.
At step ST5, the control unit 50 performs the pin alignment by projecting the alignment pins 85a and 85b from the side of the lower arms 801a to the side of the upper arms 801b. In this moment, simultaneously with the projection of the alignment pins 85a and 85b, the upper arms 801b start opening operations. A movement occurs where the alignment pins 85a and 85b are inserted with relaxing the force by which the paper-sheets 3′ are pressed. The upper arms 801b are opened up to an arbitrary intermediate position which is larger than a thickness of the booklet and smaller than the height of the bundle-of-paper-sheets-transporting path and are stopped there and they wait at this position until the upper end detection sensor 94 detects that the alignment pins 85a and 85b have reached the upper edge position thereof.
It is to be noted that the alignment pins 85a and 85b can be vibrated and/or the width-truing-up guide 72a and the width-truing-up reference guide 72b of the side jogger 70 also can be vibrated. This enables any frictional resistance in the paper-sheets 3′ to be reduced, thereby allowing the alignment pins to be easily inserted into and passed through the punch holes 3a under the condition where the upper arms 801b are opened to perform the pin alignment.
At step ST6, the control unit 50 determines whether the alignment pins 85a and 85b have passed through the punched holes 3a. In the embodiment, the upper end detection sensor 94 monitors a lapse of time from the start of the projection of the alignment pins 85a and 85b until their arrival at the upper end. If the alignment pins 85a and 85b fail to reach the upper end within a predetermined lapse of time, a shift is made to pin alignment retry operations.
The pin top detection signal S94 is output from the upper end detection sensor 94 to the control unit 50. The control unit 50 determines whether the upper end detection sensor 94 has detected the alignment pins' upper end based on the pin top detection signal S94. If the upper end detection sensor 94 does not detect the alignment pins' upper end, a shift is made to step ST16 to perform error handling.
If the upper end detection sensor 94 has already detected the alignment pins' upper end at the above-mentioned step ST6, a shift is made to step ST7. At the step ST7, since the alignment pins 85a and 85b are inserted into the bundle of paper-sheets 3″, the clampers 82a and 82b are closed. In this embodiment, the upper arms 801b are closed by retracting the cams 87a and 87b of the clamp-opening-and-closing driving section 881. It is thus possible to align the bundle of paper-sheets 3″ surely by closing the clampers 82a and 82b under a condition where the alignment pins 85a and 85b reach the upper end thereof, namely, the alignment pins 85a and 85b are passed through.
Thus, when the upper arms 801b are moved toward the closure direction to complete the closure thereof, a shift is made to step ST8 shown in
At step ST9, the control unit 50 then sets the movement mechanism 41 of the binding process unit 40 to the downward direction of the binder paper alignment unit 30. For example, the control unit 50 outputs the motor control signal S80 to the motor drive unit 180 to rotate the motor 308, thereby moving the movement mechanism 41 to a downward direction of the binder paper alignment unit 30. In this moment, the fan-shaped cam 402 keeps the roller member 827 engaged thereon.
At step ST10, it then brings down the paper-sheet fixation and movement section 880 sandwiching the bundle of paper-sheets 3″ and a shift is made to a next step. In this embodiment, the clamp movement mechanism 80 opens the shutter 83 and in the binding process unit 40, the movement mechanism 41 moves to the downward direction of the binder paper alignment unit 30 and drives so as to bring down the fan-shaped cam 402.
Simultaneously as this cam-bring-down operation is made, the lower shaft 804 of the paper-sheet fixation and movement section 880 is disengaged from the V-shaped grooves 925 and 926 of the right-and-left-edge frames 92a and 92b so that the lower arms 801a become their free conditions and by moving the fan-shaped cam 402 of the movement mechanism 41 to the downward direction, only the paper-sheet fixation and movement section 880 sandwiching the bundle of paper-sheets 3″ drops by its weight.
In this moment, the paper-sheet fixation and movement section 880 is separated from the driving of the cams 87a and 87b of the clamp-opening-and-closing driving section 881 at a point of time when it start moving to the binding process unit 40. This causes the clampers 82a and 82b to be always closed by urging force of the spring 816 so that only the paper-sheet fixation and movement section 880 can move to the binding process unit 40 with it sandwiching the bundle of paper-sheets 3″.
At step ST11, the movement mechanism 41 then performs binding process on the bundle of paper-sheets 3″. In this moment, the motor drive unit 180 rotates the motor 308 based on the motor control signal S80 received from the control unit 50, thereby attaching the binding component 43 on the bundle of paper-sheets 3″. The bundle of paper-sheets 3″ after the binding process is performed thereon becomes a booklet 90. Thereby, the alignment and binding processes of the bundle of paper-sheets 3″ are completed.
At step ST12, a retracting process of the booklet 90 is then performed. In this moment, the control unit 50 outputs the motor control signal S80 to the motor drive unit 180 to rotate the motor 308, thereby lifting the paper-sheet fixation and movement section 880 sandwiching the booklet 90.
For example, the shutter 83 is still opened by the clamp movement mechanism 80 and the binding process unit 40 drives so as to lift the fan-shaped cam 402. Simultaneously as this cam-lifting operation is made, the lower shaft 804 of the paper-sheet fixation and movement section 880 come into the V-shaped grooves 925 and 926 of the right-and-left-edge frames 92a and 92b so that the lower arms 801a become their restraint condition.
By lifting the fan-shaped cam 402 upward, the paper-sheet fixation and movement section 880 sandwiching the booklet 90 is returned to its home position HP. In this moment, the paper-sheet fixation and movement section 880 is engaged with the cams 87a and 87b of the clamp-opening-and-closing driving section 881 at a point of time when it finishes returning to the binder paper alignment unit 30. It is thus possible to perform the opening-and-closing operation again on the paper-sheet fixation and movement section 880 with sandwiching the booklet 90 by the clampers 82a and 82b which become their closed conditions by urging force of the springs 816 by means of the binder paper alignment unit 30.
At step ST13, the retracting process of the movement mechanism 41 is then performed. In this embodiment, simultaneously as the above-mentioned return of the paper-sheet fixation and movement section 880 is made, the movement mechanism 41 is moved from the downward direction of the binder paper alignment unit 30 to the downward direction of the binder cassette 42. In this moment, the fan-shaped cam 402 is still attached on the roller member 827. It is configured that the control unit 50 outputs the motor control signal S80 to the motor drive unit 180 to rotate the motor 308, thereby moving the movement mechanism 41 from the downward direction of the binder paper alignment unit 30 to the downward direction of the binder cassette 42.
At step ST14, the releasing process of the booklet 90 held at the home position HP is then performed. In this embodiment, the shutter 83 is still opened so that the clamp-opening-and-closing driving section 881 drives the cams 87a and 87b to open the upper arms 801b, thereby releasing the booklet 90. The booklet 90 drops by its weight onto the releasing unit 60 because the clampers 82a and 82b are opened.
Thereafter, at step ST15, the control unit 50 determines whether or not the booklet 90 is normally released. As standard for judging this, it is configured that a period of predetermined time relating to the release of the booklet 90 is monitored and if exceeding this, it is determined that the booklet 90 is not normally released. If the booklet 90 is normally released, paper-sheets-alignment-and-paper-sheets-binding-and-releasing control is normally terminated.
It is to be noted that if the alignment pins' upper end cannot be detected by the upper end detection sensor 94 even after the predetermined lapse of time elapses at the above-mentioned step ST6 and if the booklet 90 is not normally released at the step ST15, a shift is made to step ST16 to perform error handling because a case where any jam or the like occurs is supposed. For example, it is configured that an error display processing may be performed on a display unit (not shown) to indicate causes of the error or the like. In a second embodiment, it is configured that a jam process for the paper-sheets 3′ that fail to be aligned, the booklet that does not drop, and the like is performed.
In such a manner, according to the paper-sheet-handling device 100 according to the Embodiment 1, when moving the bundle of paper-sheets 3″ obtained by binding a plurality of paper-sheets 3′, the clamp-opening-and-closing driving section 881 keeps the clamp opened condition in which it exceeds the urged force of the springs 816 against the respective upper arms 801b in the paper-sheet fixation and movement section 880. Under this condition, it is configured that a plurality of paper-sheets 3′ is bound to obtain the bundle of paper-sheets 3″ so that the paper-sheet fixation and movement section 880 can be moved independently from the clamp-opening-and-closing driving section 881 with the bundle of paper-sheets 3″ being fixed.
Thus, the binder paper alignment unit 30 can have a configuration such that it is split into the paper-sheet fixation and movement section 880 and the clamp-opening-and-closing driving section 881, thereby enabling the bundle of paper-sheets 3″ to be easily moved to the binding step or the like with it being fixed by the paper-sheet fixation and movement section 880 mounting any necessary minimal mechanical parts.
Further, it is possible to make a movement area (a dead space) of the clamp mechanism less and to make a structure of the paper-sheet alignment and binding processing unit 110 more compact and simpler as compared with a method of moving the clamp-opening-and-closing driving section 881 mounted on the paper-sheet fixation and movement section 880 by another means for every clamp movement mechanism to transport the bundle of paper-sheets 3″ to the binding unit or a method of performing a ring binding process by moving the binding component 43 and the movement mechanism 41 of the binding process unit 40 to a predetermined position without moving the bundle of paper-sheets 3″.
In this connection, it is possible to make component parts and a control sequence for the clamp movement mechanism simpler as compared with a case where the clampers 82a and 82b are directly connected to a stepping motor or the like and driven thereby and the positions of the clampers 82a and 82b alter based on a thickness of the bundle of paper-sheets or a case where the paper-sheet transporting surface of the paper-sheet reserving unit 32 can be configured so as to rise and fall and the bundle of paper-sheets 3″ is controlled so as to prevent it from being bent in accordance with the number of stacked paper-sheets 3′.
Further, the harness processing is unnecessary because any movement of an electric part such as the motor 86 and the HP sensor 821 is not accompanied when moving the bundle of paper-sheets, thereby allowing a structure of the clamp movement mechanism 80 to be simplified. Further, since the lower arms 801a are fixed so as to be flat-surfaced with the paper-sheet transporting surface when aligning the bundle of paper-sheets and the upper arms 801b are opened, it is possible to align pieces of paper accurately with any curl in the paper-sheets 3′ being corrected by the paper-sheet curl pressing mechanism 31. This enables the paper-sheets 3′ to be aligned along the transporting surface, thereby allowing any stable paper alignment to be performed.
The following will describe a configuration example of a paper-sheet alignment and binding processing unit 110′ in a paper-sheet-handling device 100 as a second embodiment with reference to
The clamp lever 840′ is used when performing the error handling at the step ST16 of the first embodiment. For example, when aligning the bundle of paper-sheets, the clamp lever 840′ is manipulated if the jam process for the paper-sheets 3′ that fail to be aligned, the booklet that does not drop, and the like is performed. The clamp lever 840′ is attached to the cam cooperative member 819 constituting a shaft for the cams in the clamp-opening-and-closing driving section 881. For example, the cam cooperative member 819 extends to a front side thereof and the clamp lever 840′ is attached onto a shaft of the corresponding cam cooperative member 819.
The hook-type clamp lever 840′ shown in
In this embodiment, within the figure, when a lever angle θa is set to 0 degrees (θa=0°), a lever angle θb becomes 90 degrees (θb=90°) and relates to the home position HP of the cams 87a and 87b attached to the cam cooperative member 819. The clamp-opening-and-closing driving section 881 drives the cam cooperative member 819 between the lever angle θa and the lever angle θb (hereinafter, referred to as “normal operation range IV”). A lever angle θx is, for example, 115 degrees (θx=115°).
When such a clamp lever 840′ is provided, the lever angle θx of the lock position for opening the clamp and the lever angle θa or θb within the normal operation range IV of the cams 87a and 87b are made different from each other and unless the clamp lever 840′ is rotated up to its released position, a situation where a front cover or the like of the corresponding device cannot be closed occurs. In other words, it is possible to bring the clamp lever 840′ into an interference scheme when closing the cover so that by setting such a structure, it is possible to prevent the lock releasing from being forgotten.
The following will describe an example of an operation range of the cam 87a or the like in the clamp movement mechanism 80 with reference to
The cam 87a (87b is not shown) for bring the clamp up or down (U/D) shown in
The cam 87a has a shaft hole 828e to which the cam cooperative member 819 is engaged. The curved part 828a includes, for example, a side having an arc of a circle, which is based on a first radius r1 around the shaft hole 828e, and a side having a straight level, which extends from the side having the arc of the circle as well as the curved part 828c includes a side having an arc of a circle, which is on a basis of a second radius r2 (r2<r1), and a side having a straight level, which extends from the side having the arc of the circle.
A boundary between a terminal end of the side having the arc of the circle in the curved part 828a and the side having the straight level in the curved part 828c forms a projection. Inside this projection, the U-shaped part 828b is formed. A boundary between a terminal end of the side having the arc of the circle in the curved part 828c and the side having the straight level in the curved part 828a forms a projection. Inside this projection, the U-shaped part 828d is formed.
In this embodiment, the above-mentioned curved parts 828a and 828c and U-shaped parts 828b and 828d are supported by the spoke parts 828f on the shaft hole 828e. The cams 87a and 87b are produced as, for example, a resin-made part or a light-alloy-made part.
It is configured that the curved part 828a defines the normal operation range IV where the upper arms 801b is moved to a predetermined position with respect to the lower arms 801a as shown in
It is configured that the U-shaped part 828b is provided so as to be continuous with the curved part 828a and defines the lock position for opening the clamp. In this embodiment, the U-shaped part 828b has a dropping function to drop the roller 826 engaged with the upper arm 801b thereto at a position (θx=115°) rotated further from the normal operation range IV.
In this embodiment, within the figure, when a lever angle θa is set to degrees (θa=0°), a lever angle θb becomes 90 degrees (θb=90°) and relates to the home position HP of the cams 87a and 87b. The lever angle θx is 115 degrees (θx=115°) and is a position where the clamp lever 840′ is further rotated from the home position HP of the cams 87a and 87b by an angle of about 25 degrees (=115°-90°). By providing with such a U-shaped part 828b, it is possible to keep an opened condition of each of the upper arms 801b in the clampers 82a and 82b.
Here, a description will be given of an operation example of the cam 87b or the like when the clamp lever 840′ is manipulated in the binder paper alignment unit 30 with reference to
According to the clamp movement mechanism 80 in the binder paper alignment unit 30 shown in
In this embodiment, it is configured that when a message such as “Please remove the jam by manipulating the clamp lever” is displayed during a period of the error handling time at the step ST16 of the flowchart shown in
Thus, it is possible to make the lever angle θx on the lock position for opening the clamp and the lever angles θa and θb of the cams 87a and 87b within the normal operation range IV, as shown in
Thus, according to the paper-sheet-handling device 200 relating the second embodiment, when transporting the bundle of paper-sheets 3″ obtained by binding a plurality of paper-sheets 3′, the clamp-opening-and-closing driving section 881 is provided with the cams 87a and 87b for opening and closing the clamp so that when releasing the bundle of paper-sheets, the cams 87a and 87b move the upper arms 801b to a predetermined position with respect to the lower arms 801a by a designated curved part 828a defining the normal operation range IV to release the bundle of paper-sheets 3″. Further, when an error or the like occurs, with manipulating the clamp lever 840′, by rotating the cams 87a and 87b to the U-shaped parts 828b that are continuous with the curved parts 828a, it is possible to make the rollers 826 of the upper arms 801b drop to the U-shaped parts 828b.
Therefore, it is possible to lock the clamp movement mechanism 80 under the condition where the upper arms 801b are opened. This enables the jam-removing operation to be performed with the upper arms 801b being opened, thereby improving the operability when handling the error. Furthermore, since the lock position for opening the clamp is set to a position that is different from the normal operation range IV, the clamp lever 840′ can be an interference when the cover is closed. Employing such a clamp manipulation configuration enables release of the lock to be prevented from being forgotten. Furthermore, it is possible to reduce a burden of the control unit 50 as compared with a case where the detection of the lock position is performed utilizing the position sensor for the cams 87a and 87b and forgetting the release of the lock is informed to the user.
It has been explained in the above-mentioned embodiments 1 and 2 with respect to a case in which with reference to the up and down movement of the paper-sheet fixation and movement section 880 for moving the bundle of paper-sheets 3″, it is driven by the fan-shaped cam 402 through the movement mechanism 41, but it is not limited by this: whole of the paper-sheet fixation and movement section 880 is connected by a belt or a rack and pinion, and it may be moved by other driving means.
This invention is very preferable to be applied to a binding device for carrying out the binding processing to the recording paper-sheets released from a copy machine or a print machine for black-and-white use and for color use.
Number | Date | Country | Kind |
---|---|---|---|
2006-353012 | Dec 2006 | JP | national |
2006-353013 | Dec 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2007/074985 | 12/26/2007 | WO | 00 | 6/23/2009 |