The present application claims priority to and incorporates by reference the entire contents of Japanese Patent Application No. 2012-057257 filed in Japan on Mar. 14, 2012 and Japanese Patent Application No. 2012-253025 filed in Japan on Nov. 19, 2012.
1. Field of the Invention
The present invention relates to a sheet post-processing apparatus and an image forming apparatus.
2. Description of the Related Art
In image forming apparatuses such as a laser printer and a color image copying machine using the electrophotographic process, in general, the following method is adopted. Image data input from a personal computer or an image input device is exposed by a laser or the like to form an electrostatic latent image on an image carrier such as a photosensitive drum. Toner is developed by a developing device and then transferred to a sheet such as a form. The toner is then fused onto the sheet by a fixing unit of the heating roller type or the like to fix an image, and the sheet is discharged.
Image forming apparatuses aiming at automation of operations are also provided. These apparatuses are connected with a post-processing apparatus for performing post-processing including stapling, punching, sorting (gathering), bookbinding, and folding. Sheet post-processing by the post-processing apparatus includes stacking processing for sorting sheets for every copy and stacking them on a discharge tray and stapling processing for stapling post-processed sheets for every predetermined number of sheets and stacking them on a stack tray.
As an image forming apparatus equipped with a post-processing apparatus, an image forming apparatus disclosed in Japanese Patent No. 4199203 is known for example. The image forming apparatus includes a document scanning unit arranged at the top of the apparatus body, a paper feeding unit arranged at the bottom of the apparatus body, a printing unit arranged in between the document scanning unit and the paper feeding unit, a sheet post-processing unit that can perform a plurality pieces of sheet post-processing on sheets that are conveyed from the apparatus body after being printed by the printing unit, and a discharging unit to which the sheets after post-processing are discharged, both units arranged in a space within the apparatus body.
In the image forming apparatus disclosed in Japanese Patent No. 4199203, however, when sheets are conveyed from the apparatus body through the short edge feed (SEF), post processing can be performed on the short edge side that orthogonal to the sheet conveying direction, but not on the long edge side that is parallel to the sheet conveying direction. There is also a problem that, because a punching unit and a staple unit in the sheet post-processing unit are collaterally arranged in the horizontal direction, the apparatus body has a large lateral size.
Therefore, there is a need to provide a sheet post-processing apparatus that can incorporate a plurality pieces of post-processing units for performing post-processing on sheets in a space-saving manner, switch the sheet conveying direction smoothly, and perform post-processing on sheets without degrading productivity and to provide an image forming apparatus including the post-processing apparatus.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an embodiment, there is provided a sheet post-processing apparatus that includes a first conveying unit configured to convey a sheet; a holding unit configured to hold the sheet conveyed by the first conveying unit; a first post-processing unit configured to perform a post-process on the sheet conveyed by the first conveying unit; a second post-processing unit configured to perform a post-process on the sheet conveyed by the first conveying unit, the second post-processing unit being arranged below the first post-processing unit; a moving unit configured to move the holding unit from the first post-processing unit to the second post-processing unit; a second conveying unit configured to convey the sheet subjected to the post-processed by the first post-processing unit or the second post-processing unit in a direction orthogonal to a direction in which the sheet is conveyed by the first conveying unit; and a stacking unit configured to stack the sheet conveyed by the second conveying unit.
According to another embodiment, there is provided an image forming apparatus that includes an image scanning unit configured to read image information; an image forming unit configured to form an image on a sheet based on the read image, the image forming unit being arranged below the image scanning unit; and the sheet post-processing apparatus according to the above embodiment, arranged in between the image scanning unit and the image forming unit, wherein the sheet on which the image has been formed is conveyed to the first conveying unit.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Hereinafter, an embodiment of an image forming apparatus including a sheet post-processing apparatus according to the present invention will be described with reference to the accompanying drawings.
Overall Configuration
The image forming unit 100 is what is called a tandem-type color image forming unit of the indirect transfer type. The image forming unit 100 includes an image forming part 110 around whose central part a four-color image forming station 111 is arranged, an optical writing unit (not illustrated) that is provided adjacently below the image forming part 110, a paper feeding unit 120 that is provided below the image forming part 110, a feeding conveying path (vertical conveying path) 130 that conveys a sheet picked up by the paper feeding unit 120 to a secondary transfer unit 140 and a fixing unit 150, a discharging conveying path 160 that conveys the sheet on which an image is fixed to the sheet post-processing apparatus 200 side, and a duplex conveying path 170 that reverses the sheet with the image formed on its one surface and allows image formation on the other surface.
The image forming part 110 includes photosensitive drums for each of the YMCK (Y: yellow, M: magenta, C: cyan, and K: black) colors of the image forming station 111, a charging unit, a developing unit, a primary transfer unit, a cleaning unit, and a neutralization unit, each of which is arranged along the perimeter of the photosensitive drum, an intermediate transfer belt 112 that intermediately transfers an image formed on the photosensitive drum using the primary transfer unit, and an optical writing unit that writes an image onto each photosensitive drum for the corresponding color. The optical writing unit is arranged below the image forming station 111, while the intermediate transfer belt 112 is arranged above the image forming station 111. The intermediate transfer belt 112 is rotatably supported by a plurality of support rollers, one support roller 114 of which faces a secondary transfer roller 115 through the intermediate transfer belt 112, thereby allowing an image on the intermediate transfer belt 112 to be secondarily transferred to the sheet. Because the image forming process of the tandem-type color image forming unit of the indirect transfer type is publicly known, and it does not directly relate to the subject of the present invention, its detailed description will be omitted.
The paper feeding unit 120 includes a paper feed tray 121, a pick-up roller 122, and a feeding conveying roller 123, and feeds a sheet picked up from the paper feed tray 121 upward along the vertical conveying path 130. An image is transferred to the fed sheet in the secondary transfer unit 140, and the sheet is fed into the fixing unit 150. The fixing unit 150 includes a fixing roller and a pressing roller. When the sheet passes through the nip between both rollers, the fixing unit 150 applies heat and pressure on the sheet, thereby allowing toner to be fixed onto the sheet.
The discharging conveying path 160 and the duplex conveying path 170 are provided at the downstream of the fixing unit 150. Both paths are bifurcated into two directions by a bifurcating claw 161, thereby allowing the sheet conveying path to be selected between a case of the sheet being conveyed to the sheet post-processing apparatus 200 side or a case of the sheet being conveyed to the duplex conveying path 170. At the direct upstream side of the bifurcating claw 161 in the sheet conveying direction, provided is bifurcating conveying rollers 162, thereby exerting a conveying force to the sheet.
The sheet post-processing apparatus 200 is arranged in a space formed in between the image forming unit 100 and the image scanning unit 300 of the apparatus body. The sheet post-processing apparatus 200 performs predetermined post-processing on a sheet with an image formed thereon conveyed from the image forming unit 100 and stacks the sheet on the discharge tray 210 that is positioned at the endpoint, details of which will be describe later.
The image scanning unit 300 optically scans a document set on a contact glass and reads an image on the document surface. Because the structure and functions of the image scanning unit 300 are publicly known, and it does not directly relate to the subject of the present invention, its detailed description will be omitted.
In the image forming unit 100 configured as outlined above, image data to be used in writing is generated based on document data read by the image scanning unit 300 or print data transferred from an external PC and the like. Based on the image data, the optical writing unit performs optical writing on each photosensitive drum. Images formed on each photosensitive drum for the corresponding color are successively transferred to the intermediate transfer belt 112, and a color image on which images with four colors are superimposed is formed on the intermediate transfer belt 112. A sheet is fed from the paper feed tray 121 in accordance with the image formation. The sheet is temporarily stopped at the position of a registration roller (not illustrated) right in front of the secondary transfer unit 140, is fed in synchronization with the leading end of an image on the intermediate transfer belt 112, is secondarily transferred by the secondary transfer unit 140, and is fed into the fixing unit 150.
The sheet on which the image has been fixed by the fixing unit 150 is conveyed, by the switching operation of the bifurcating claw 161, to the discharging conveying path 160 side for the time after the printing of single-sided printing and the time after the printing of duplex printing, and is conveyed to the duplex conveying path 170 side for the time after the single-sided printing of duplex printing. The sheet conveyed to the duplex conveying path 170 after single-sided printing is, after being reversed, fed finally into the secondary transfer unit 140, where an image is formed on the blank side, and is then sent back to the discharging conveying path 160 side. The sheet conveyed to the discharging conveying path 160 side is conveyed to the sheet post-processing apparatus 200, and is, after being subjected to predetermined post-processing or without post-processing, discharged to the discharge tray 210.
Sheet Post-Processing Unit
A sheet receiving unit of the sheet post-processing apparatus 200 includes a pair of entrance rollers 201a that receive the sheet P from the discharging conveying path 160 of the image forming unit 100 and a feed guiding plate 501 for conveying the received sheet to the punching unit 600. The sheet is conveyed along the feed guiding plate 501 through rotation of the pair of entrance rollers 201a by an entrance motor (not illustrated). At the upstream side of the pair of entrance rollers 201, arranged is an entrance sensor 203 (see
In the configuration of the sheet post-processing apparatus 200 at the downstream of the pair of entrance rollers 201, as illustrated by the arrow A in
The sheet P discharged from the pair of entrance rollers 201a enters the punch stage with one edge (the upper long edge in
After one of the sheet long edges falls from the punch stage to the staple stage, and the entire sheet is placed on the staple tray 206, process differs depending on shift modes, one that shifts and discharges a sheet and the other that staples a plurality of sheets and discharges them. Each mode will be described together with its corresponding structure.
Shift Mode
The shift mode is a mode in which, without a punching process or a stapling process performed on sheets, the discharging position is shifted along the direction perpendicular to the sheet conveying direction when the sheets are discharged on the discharge tray 210, and the sheets are sorted for every predetermined number of sheets.
As illustrated in
After the sheet falls to the staple stage, one of the long edges (the right-hand long edge in
A sheet retainer 220 for retaining sheets stacked on the discharge tray 210 is arranged at the mounting part of the discharge tray 210 to the body part of the sheet post-processing apparatus 200. Sheet retaining release operation and sheet retaining operation are performed by turning on and off of a solenoid 221. In other words, the solenoid 221 is turned on in accordance with the feeding of a sheet to release the pressing operation of the sheet retainer 220. When the sheet trailing end passes through the discharging rollers 209, the solenoid 221 is turned off to perform sheet retaining.
The discharge tray 210 includes a fixed tray unit 222a at the downstream side in the conveying direction and a movable tray unit 222b at the upstream side. The movable tray unit 222b moves vertically by a tray DC motor 223a and a cam and link mechanism 223b. The movable tray unit 222b is pivotally supported in an oscillatable manner by the fixed tray unit 222a through a pivot 223c with its end at the upstream side being an oscillating end. The working end of the cam and link mechanism 223b is connected to the movable tray unit 222b. An end of the movable tray unit 222b at the upstream side in the sheet conveying direction is a free end. As a result, when the tray DC motor 223a rotates, the movable tray unit 222b, in accordance with the rotation, oscillates about the pivot 223c. When the number of discharged sheets amounts to a predetermined number, the tray DC motor 223a rotates through an instruction from a control unit, which will be described later, thereby moving downward the movable tray unit 222b.
A tray sheet surface sensor (not illustrated) is arranged on the sheet retainer 220. When the tray sheet surface sensor is off while sheet retaining is performed by the sheet retainer 220, the free end of the movable tray unit 222b is moved upward until the tray sheet surface sensor is turned on. When the tray sheet surface sensor is on, the free end of the movable tray unit 222b is moved downward once until the sheet surface sensor is turned on, and then moved upward until it is turned on again, thereby maintaining the height of the free end of the movable tray unit 222b in the discharge tray 210 on which sheets (or a batch of sheets) are stacked constant.
By thus moving upward and downward the free end of the movable tray unit 222b in accordance with the sheet stacking condition of the discharge tray 210 and maintaining the distance from the nip of the discharging rollers 209 to the sheet stacking unit of the movable tray unit 222b constant, the contact angle between a sheet discharged from the discharging rollers 209 and the movable tray unit 222b can be kept constant so as to stabilize the alignment quality of the sheets stacked on the discharge tray 210 and allow stacking of a large number of sheets. By repeating the foregoing operation, sorted sheets are stacked on the discharge tray 210.
Staple Mode
The staple mode is a mode, in which when sheets are discharged, they are stapled by the stapling unit 700 for every predetermined number of sheets and are discharged. In the staple mode, one of the sheet long edges is pushed out of the punching unit 600 by the two clamps 401, and the two clamps 401 move until the one of the sheet long edges abuts against the trailing-end reference fences 207 through the vertical operation of the clamp unit 400, which will be described later, thereby performing alignment in the conveying direction on the staple stage. This alignment is performed based on the trailing-end reference fences 207.
At the completion of the abutting of the one of the sheet long edges, sheet alignment in the direction perpendicular to the sheet conveying direction on the staple stage by the staple jogger fences 208 arranged on the staple tray 206 described above in the description of the shift mode is performed.
The staple tray 206 includes a home sensor (not illustrated) that detects a standby position of the staple jogger fences (alignment plates) 208. The staple tray 206 is also provided with trailing-end reference fences 207 through a slider (not illustrated) on a guide shaft (not illustrated), and they can move in the same direction as the staple jogger fences (alignment plates) 208. A rack (not illustrated) is held by the slider and is coupled to a gear (not illustrated) that is arranged nearly at the center of the staple tray 206, thereby allowing the trailing-end reference fences 207 to move symmetrically with respect to the gear.
A guide is provided at the end of the trailing-end reference fences 207. A base (not illustrated) of the stapling unit 700 hooks the inside of the guide through the movement of the stapling unit 700, thereby allowing the trailing-end reference fences 207 to follow. When the stapling unit 700 moves in a direction toward the end of the staple tray 206, the separation between the trailing-end reference fences 207 becomes larger. When the stapler moves to the center of the staple tray 206, because the trailing-end reference fences 207 are biased toward the center of the staple tray 206 by a spring (not illustrated), the separation between the trailing-end reference fences 207 becomes smaller.
After stapling processing, the discharging guide plate 212 is moved downward to hold a batch of sheets by the discharging rollers 209 and the driven roller 213 attached to the discharging guide plate 212, and the batch of sheets are discharged to the discharge tray 210. While the batch of sheets is being discharged, the solenoid 221 is turned on to release the sheet retainer 220, and the movable tray unit 222b is moved downward by a predetermined amount. Next, the discharging guide plate 212 is moved upward with such timing that the trailing end of the batch of sheets passes through a batch discharge sensor 225 to prepare for the reception of the next sheet. The solenoid 221 turned off with the same timing to perform sheet retaining.
Next,
First, after conveying the end of the sheet P to the punching unit 600 by the entrance rollers 201a and the driven rollers 201b (see
When the sheet P moves to the staple stage, it moves to the sheet trailing-end abutting surfaces of the trailing-end reference fences 207 while being held by the two clamps 401, and when the trailing end of the sheet P reaches the abutting surfaces 207a of the trailing-end reference fences 207, the two clamps 401 open. The entrance slide guide plate 502 is slid and returned to the original position, and this operation supplies pressure for the driven rollers 201b, thereby allowing the next sheet to be received.
The driven roller 201b is rotatably attached to the entrance slide guide plate 502 as a guide plate. The entrance slide guide plate 502 includes guide pins 502a and 502b that project toward the near side of the sheet of
The driven roller 201b thus moves obliquely in the upstream direction by the nip formation release unit having the stepping motor 506 as the nip formation release driving source, the rack 507 of the entrance slide guide plate 502, the torque-limiter-equipped pinion 508 and the timing belt 509, thereby releasing the formation of the nip with the entrance roller 201a. Accordingly, because the retreat of the driven roller 201b is performed in the linear movement in the obliquely upstream direction, it follows a less redundant path than the conventional arcuate retreat path of a driven roller through the rotation of a guide plate, and sheet processing can be performed without degrading productivity. Therefore, the sheet conveying direction can be switched smoothly, sheets can be conveyed to the downstream side stably and processing on sheets can be performed.
The drive of the driven roller 201b can be achieved at low cost using the stepping motor 506 for rotating the entrance roller 201a.
Arriving at the staple stage, the clamp 401A moves to the abutting surface 207a of each of the trailing-end reference fences 207 while holding the sheet, and when one of the sheet long edges arrives at the abutting surface of each of the trailing-end reference fences 207, releases the holding of the sheet. The clamp 401B waits at the reception position so that the next sheet can be punched at the punch stage (see
The link 405 includes a linear arm that is rotatable with the center of rotation 404 that is rotatably driven by a driving source (not illustrated) as the fulcrum, and includes long channels 405a and 405b in between the center of rotation 404 and the arm ends. The guide 402 is a member having an elliptic guide hole 402a. The clamps 401A and 401B have cylindrical guide members 415A and 415B that pass through the guide hole 402a of the guide 402 and are freely fit into the long channels 405a and 405b, respectively. The clamps 401A and 401E operate by allowing the guide members 415A and 415B to move along the long channels 405a and 405b of the link 405 and the guide hole 402a of the guide 402 when the link 405 rotates with the center of rotation 404 as the fulcrum by the rotational drive of a driving source such as a stepping motor (not illustrated). The guide 402, link 405, and driving source of the clamp unit 400 are arranged at positions that do not interfere with sheet conveying. The other pair of clamps 401A and 401B (the clamp 401 in the lower side of
As described above, according to the sheet post-processing apparatus in the embodiment, a sheet that is conveyed by the first conveying unit and post-processed by the first post-processing unit is moved by the holding unit and the moving unit, and a second conveying unit is provided, which conveys the sheet post-processed by the second post-processing unit in a conveying direction orthogonal to the conveying direction conveyed from the image forming unit, where the second conveying unit conveys the sheet conveyed from the image forming apparatus with its one of the short edge and long edge being at the head and post-processed by the first or second post-processing unit to the stacking unit with the other one of the short edge and long edge of the sheet at the head, thereby allowing a plurality of post-processing functions to be arranged in a space-saving manner, switching the sheet conveying direction smoothly, and allowing processing on sheets without degrading productivity by eliminating redundant operation.
Although the embodiment of the present invention has been described above, the present invention is not limited thereto, and various alternations and applications are possible. As far as those alternations and applications are provided with the constituents of the present invention, they are included within the scope of the present invention.
For example, in the sheet post-processing apparatus 200 of the above-described embodiment, the sheet P having a short edge and long edge (for example, an A4 sheet) is received from the image forming unit 100 through SEF, the conveying direction of the sheet P after the post-processing is switched to the orthogonal direction (the arrow B) by the discharging rollers 209 with respect to the conveying direction A from the image forming unit 100, and the sheet P is conveyed to the discharge tray 210 through LEF. In place thereof, the sheet P may be received from the image forming unit 100 through LEF, and after being post-processed, conveyed to the discharge tray 210 through SEF.
According to the embodiments, it is possible to allow a plurality of post-processing units to be arranged in a space-saving manner, switch the sheet conveying direction smoothly, and allow processing on sheets without degrading productivity by eliminating redundant operation.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2012-057257 | Mar 2012 | JP | national |
2012-253025 | Nov 2012 | JP | national |