This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2003-319964, filed Sep 11, 2003, the entire contents of all of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a sheet reverse controller for reversing the conveying direction of sheets, for example, mails being conveyed.
2. Description of the Related Art
As a sheet processing apparatus, a mail processing apparatus to process mails such as, for example, sealed letters, post cards, etc. and a banknote processing apparatus to process banknotes are known. For example, a mail processing apparatus is composed of a sheet take-out unit to take out sheets such as sealed letters, post cards, etc. one by one that are set by operator, a sheet conveying unit to convey taken out sheets between various units on a conveying path, a discrimination unit to read image data from the front and back surfaces of sheets conveyed and discriminate a position where a stamp is pasted, a twist reverse unit to reverse the front and back surfaces of a sheet by turning it by 180° centering on the conveying direction with a twist reverse belt, a reverse controller to reverse the front and rear ends in the sheet conveying direction and the front and back of sheet at the same time, a stamping unit to stamp a postmark on a pasted stamp, a stacker to stack sheets in a stacking storage, and gates to sort sheets to respective units selectively.
In the mail processing unit, a twist reverse unit and a reverse controller are selectively used to move the position of a stamp pasted on a sheet to a position where a postmark can be stamped. A twist reverse unit turns (twist reversing) a sheet by 180° centering on the direction same as the sheet conveying direction. The reverse controller reverses the front and rear ends of a sheet in the conveying direction and the front and back of a sheet at the same time (the switchback reversing).
This will be explained taking an example of a sheet with a stamp on the upper side of the downstream side in the conveying direction on the right hand side surface toward the downstream side of the conveying direction when a sheet is conveyed in the erected state. When this sheet is twisted with a reverse controller, the stamped position comes to the left-hand surface toward the downstream in the conveying direction and at the downside of this surface. Further, when this sheet is switchback reversed with a reverse controller, the stamped position comes to the right hand side surface toward the downstream of the conveying direction and at the upstream side of the conveying direction and the downside on this surface.
As disclosed in Japanese Patent Application Publication No. 7-232847, an apparatus provided with a normal/reverse rotation roller, a hit blade, etc. to convey a sheet that is conveyed directly in the straight direction or in the reverse direction is devised as a sheet reverse controller.
In a sheet processing apparatus including a mail processor, a conveying unit and other units are so controlled as to maintain a space (gap) between conveying sheets or a distance (pitch) between front edges of sheets being conveyed. However, in a reverse controller, when sheets are reversed, complicates controls to accelerate or decelerate a conveying speed of sheets. Therefore, before and after the reversing operation, a gap or pitch between sheets tend to change. In particular, when a cap or pitch after the reversing operation becomes short, sheets come too close each other in the conveying unit at the downstream side and sheets tends to jam easily.
It is an object of the present invention to provide a reverse controller of sheets capable of reducing generation of jamming by reducing change in gap or pitch of sheets before and after the reversing operation of sheets.
According to the present invention, there is provided a sheet reverse controller comprising: first conveying means for conveying a sheet in a first direction; a reverse unit to reverse the sheet conveyed from the first conveying means in a second direction differing from the first direction; second conveying means for conveying the sheet reversed in the reverse unit in the second direction; a sensor provided on the second conveying means to detect the sheet; calculation means for calculating a space between the sheets based on the detected result of the sensor; and a controller to control the conveying velocity of the second conveying unit so as to decelerate the conveying velocity of the sheet when the space between the sheets is shorter than a specified value and accelerate the conveying velocity of the sheets when a space between the sheets is longer than a specified value.
One embodiment of the present invention will be explained below referring to attached drawings.
A take-out controller 3 is connected to main controller 2 and receives/transmits various data, and is composed of memories storing drivers to operate a take-out portion 13 that will be described later.
A conveying controller 4 is connected to main controller 2, receives/transmits various data and is composed of a memory storing drivers to operate a twist reverse unit 18, a reverse controller 19 and a conveying unit 14.
As shift sensor controller 5 is connected to main controller 2, receives/transmits various data, receives detected data of sheet 12 from shift sensors 35 and 53 installed in reverse controller 19 and conveying unit 14 that will be described later and transmits this detected data to main controller 1.
Gate controller 6 is connected to main controller 2, receives and transmits various data and controls the operations of gates 15a, 15b and 15c.
Sheet processing apparatus 1 shown in
Plural sheets 12 are stacked in take-out portion 13 in the random direction by operator who operates sheet processing apparatus 1. Plural sheets 12 stacked in take-out portion are separated one by one and taken out on conveying unit 14 and conveyed to discrimination unit 15. Discrimination unit 15 reads image data on the front and back sides of sheet 12, discriminates the position of a stamp put on sheet 12 and sends the discrimination result to main controller 1. Main controller 2 judges whether sheet 12 is an object for rejection based on the result of discrimination from discrimination unit 15. When sheet 12 is an object for rejection, gate 25a operates to send it to reject stacker 17. Further, when sheet 12 is judged to be other than an object for rejection, main controller 2 judges the necessity for twist reverse or switchback reverse from the position of a stamp put on sheet 12 and selects gate 15b or gate 25c and actuates it.
Position of a stamp put on sheet 12 and the movement of stamp position pursuant to the twist reverse or the switchback reverse of sheet 12 will be explained. In a case where a stamp is on the upside of the right side in the downstream conveying direction of a sheet when it is conveyed in the erected state, the position of a stamp comes to the downside on the left side to the downstream in the conveying direction when sheet 12 is twist reverse with twist reverse unit 18. Further, when this sheet 12 is switchback reversed by reverse controller 19, the stamp position comes to the downside at the upstream side in the conveying direction on the right side surface to the downstream in the conveying direction. Further, when this sheet 12 is switchback reversed by reverse controller 19, the stamp position comes to the downside at the upstream side in the conveying direction on the right side surface to the downstream in the conveying direction.
When sheet 12 is twist reversed or switchback reversed selectively, a stamp pasted on sheet 12 being conveyed comes to a specified position, for example, the downstream side in the conveying direction and upside on the right side surface to the downstream in the conveying direction. This specified position is a place where a postmark can be stamped by seal unit 20 and is a position over which a stamp on sheet 12 passes.
Sheet 12 stamped in seal unit 20 is conveyed to stacker 21 and stacked in the stacking portion sequentially.
Conveyor in main body 27 is composed of a conveying roller 31 and a conveying belt 33 likewise conveying unit 14 and conveys sheet 12 by holding it with conveying belt 33. Conveyor in main body 27 is provided with shift sensors 35 and detects sensor 12. The reverse operation of reverse unit 29 is triggered by this detection. Shift sensors 35 detect a length of sheet 12 by detecting its front and rear ends.
Reverse unit 29 is composed of a normal/reverse rotation roller 37 equipped with a driving source independent from conveying roller 31, etc., a pinch roller 39 that is driven following normal/reverse rotation roller 37, and guides 41 and 41 to lead sheet 12. Pinch roller 39 is attached rotatably to one end of an L-shaped lever 44. L-shaped lever 44 is supported in the oscillating state via a rotation fulcrum. The other end of L-shaped lever 44 is kept pilled by the restoring force of a spring 45 and pinch roller 39 is pressed against formal/reverse roller 37 by the oscillation of L-shaped lever 44 in the counterclockwise direction.
At the transfer portion between conveyor in a main body 27 and reverse unit 29, there is provided a hit lever 47 which is driven by a solenoid and oscillates. When lever 47 is oscillated, the front end of reversed sheet 12 is led to an exit side 19b of reverse controller 19.
Next, the operation of reverse controller 19 will be explained referring to
Sheet 12 is conveyed to reverse unit 29 while being led by guides 41 and 41 and held by normal/reverse rotation roller 37 and pinch roller 39 (T=t1). At this time, pinch roller 39 rotates centering around pinch roller rotation fulcrum 43 according to a thickness of sheet 12 and escapes by the thickness of sheet 12. Further, normal/reverse rotation roller 37 is normally rotating clockwise at a peripheral velocity V=V0 in
Normal/reverse rotation roller 37 starts to accelerate (T=t1) in a moment to hold sheet 12 based on the detection of the front end of sheet 12 by shift sensors 35 and accelerate to peripheral velocity V=V1. Then normal/reverse rotation roller 37 rotates at the constant velocity V=V1 while T=t2. At a time T=t2, normal/reverse rotation roller 37 starts to decelerate from peripheral velocity V1 and stop the rear end of sheet 12 at the reference position (T=t3).
While sheet 12 is kept stopped or while from the rear end of sheet 12 is released from pinching by belt 33 to stopped, hit lever 47 is actuated and the rear end of sheet 12 (the end in the conveying direction of sheet 12 after reversed) is directed toward exit side 19b.
At a time T=4, normal/reverse rotation roller 37 starts to rotate in the reverse direction (the counterclockwise direction in
At T=t6, normal/reverse rotation roller 37 starts the rotation in the normal direction again and the peripheral velocity V reaches V0 (V=V0) at T=t7.
In reverse controller 19, normal/reverse rotation roller 37 performs a series of operations; that is, normal rotation at a constant velocity, acceleration, normal rotation at a constant velocity, acceleration, stop, acceleration in reverse rotation and reverse rotation at a constant velocity. Thus, a space; that is, a gap (or pitch) between sheets 12 is maintained and therefore, it is possible to make a gap (or pitch) and improve the processing capacity of sheet processing apparatus 1. Here, a gap is a distance to the front end of another sheet 12 being conveyed at the upstream side in the conveying direction rather than this sheet 12. Further, a pitch is a distance from the front end of sheet 12 being conveyed to the front end of another sheet 12 being conveyed at the upstream side in the conveying direction rather than this sheet 12.
Further, the accelerating operation of normal/reverse rotation roller 37 is made at a different acceleration curve (accelerating inclination) based on the detection result of length of sheets 12 by shift sensors 35. The longer the conveying direction of sheet 12 is, the larger acceleration curve (accelerating inclination) is demanded. When sheets 12 that are conveyed are in the same size such as tickets or checks or when a difference in length is small as in banknotes, it is not required to change an acceleration curve.
Next, causes for changing a gap (or a pitch) of sheet 12 before and after the reverse in the revere operation in reverse controller 19 will be explained.
When the stop position of sheet 12 is shifted to the upstream side in the conveying direction and stops there, a gap (or a pitch) with sheet 12 conveyed at the downstream side in the conveying direction rather than this sheet 12 becomes shorter than that before the reverse operation. When a gap (or a pitch) between sheets 12 becomes short, the jamming tends to generate. To reverse sheet 12 by considering the change of this gap (or pitch), it is necessary to set a gap (or a pitch) rather long. If a gap (or a pitch) between sheets is long, conveying density becomes low and the processing throughout of sheet processing apparatus 1 drops.
Shift sensor 53 detects a gap (or a pitch) between a sheet 12 reversed by reverse controller 19 and another sheet conveyed at the downstream side in the conveying direction of this sheet 12. Based on the result of this detection, when a gap (or a pitch) becomes short, driving roller 49 and pinch roller 52 decelerate at a moment when they hold a sheet 12 and decelerate a sheet 12 and a gap (or a pitch) with another sheet 12 being conveyed at the downstream side in the conveying direction is corrected to a proper length.
On the contrary, when the conveying position of sheet 12 is shifted and a gap (or a pitch) between sheets 12 becomes long at the upper stream side in the conveying direction than reverse controller 19, this change in gap (or pitch) is detected by shift sensor 53. Based on this detected result, driving roller 49 and pinch roller 51 are accelerated at a moment when they hold sheet 12 and correct a gap (or pitch) to shift sheet 12 to the downstream side in the conveying direction to a position originally sheet 12 should have been conveyed.
In
According to the first embodiment, change in gap (or pitch) of sheets 12 after reversed by reverse controller 19 can be resolved by correcting a gap (or pitch) not only when a gap (or pitch) becomes short but also when it becomes long.
Next, a second embodiment will be explained referring to
Driving roller 57 receives a driving force from conveying unit 14 of sheet processing apparatus 1 and rotates at the same peripheral velocity as the conveying velocity of conveying unit 14. Further, driving roller 57 is equipped with a one-way clutch that freely rotates only in the direction to which sheet 12 is pulled out. Therefore, when a sheet 12 is pulled out in a moment when normal/reverse rotation roller 37 and pinch roller 39 hold sheet 12, the rear end of sheet 12 does not resist even when it remains in the vicinity of exit in main body conveyor.
A series of operations in the second embodiment will be explained. First, sheet 12 conveyed through entrance side 19a is held by normal/reverse rotation roller 37 and pinch roller 39 at its front end and pulled out to reverse unit 29 side as accelerated. At this time, the rear end of sheet 12 is held between driving roller 57 and pinch roller 59. However, it escapes in the pulled-out direction by one-way clutch of driving roller 57 and therefore, it is free from resistance by being held by driving roller 57 and pinch roller 59.
Therefore, by preventing the shift of the stop position sheet 12, it becomes possible to reduce change in gap (or pitch) after reversed and generation of jamming. Driving roller 57 and pinch roller 59 are one set but it is not necessary to restrict especially and plural sets may be installed according to the shape of conveying unit 14 or other conditions.
A series of reverse operations of reverse controller 19 equipped with swingable tension roller 61 will be explained. When front end of sheet 12 conveyed through entrance side 19a passes shift sensors 35, its front and rear ends are detected. With this detection as a trigger, swingable tension roller 61 is separated from conveying belt 33 in a moment when sheet 12 is held by normal/reverse rotation roller 37 and pinch roller 39, conveying belt 33 of exit in main body conveyor 55 is freed. At this time, as conveyor belt 33 is freed, the rear end of sheet 12 does not give a resistance to the acceleration operation of normal/reverse rotation roller 37. By preventing the shift of the stop position of sheet 12, it is possible to reduce change in a gap (or a pitch) of sheet 12 before and after the reverse operation of reverse controller 19.
These plural rollers are composed of driving rollers 63 and 63 which rotate at the same conveying velocity as conveying unit 14 of sheet processing apparatus 1, an acceleration drive roller 65 which rotates at a conveying velocity faster than driving rollers 63, and pinch rollers 67, 67 and 67 which are arranged opposing to drive rollers 63 and 63 and acceleration drive roller 65 and give pinch pressure. Further, guides 41, 41, 41 and 41 are provided to lead sheet 12 to reverse unit 29.
Sheet 12 is accelerated every time when passes drive rollers 63 and 63 and acceleration drive roller 65. Drive rollers 63 and 63 are provided with a one-way clutch and accelerate the conveying velocity of sheet 12 without receiving a resistance.
The axis of abscissas of the graph shows a time T (s), and the axis of ordinate shows a peripheral velocity (a conveying velocity) V (m/s) of normal/reverse rotation roller 37. Peripheral velocities of normal/reverse rotation roller 37 are V0=3 m/s and V1=5 m/s. Here, the peripheral velocity V0 of normal/reverse rotation roller is almost the same velocity as the conveying velocity of conveying unit 14. However, the peripheral velocity is changed properly according to various characteristic amounts such as size, stiffness, weight, etc. of sheet 12 that is conveyed and not particularly restricted.
Conveying velocity of drive rollers 63 and 63 shown in
Further, when shift sensors 35 detect the rear end of sheet 12, normal/reverse rotation roller 37 starts to decelerate after a specified time from the detected time (t11) and stops to rotate (t12). At this time, it becomes possible to make the rear end positions of sheets 12 (or the front end after reversed) uniform at the same deceleration curve irrespective of the length of sheet 12 in the conveying direction.
Further, it becomes possible to reduce change in pitch (or gap) between sheets 12 and reduce generation of jamming before and after the reverse operation of reverse controller 19. Here, acceleration drive roller 65 and pinch roller 67 are not restricted to be one set but plural sets of acceleration drive rollers 65 equipped with a one-way clutch may be provided so as to accelerate in stages.
Further, as a modification of the fourth embodiment, acceleration drive rollers 65 may be constructed with drive rollers equipped with a one-way clutch so as to accelerate normal/reverse rotation roller 37 in a moment when it holds sheet 12. At this time, the conveying velocity of normal/reverse rotation roller 37 is so controlled as shown in
From the explanations of the first through the fourth embodiments described above, it is possible to provide a reverse controller 1 of sheet 12 capable of reducing generation of jamming by reducing change in gap or pitch between sheets 12 before and after the reverse operation of sheet 12.
As described above, the sheet reverse controller of the present invention has the structure and actions as described above and is capable of reducing generation of jamming by reducing change in gap or pitch between sheets before and after the sheet reversing operation.
Number | Date | Country | Kind |
---|---|---|---|
2003-319964 | Sep 2003 | JP | national |