1. Field of the Invention
The present invention relates to a sheet stacking apparatus on which a sheet received from an image forming apparatus body is stacked, a sheet processing apparatus, and an image forming apparatus. More specifically, the present invention relates to a sheet stacking apparatus which has a lifting and lowering mechanism of a sheet stack tray.
2. Description of Related Art
In recent years, there has been increased the number of image forming apparatuses, such as a copying machine or a printer, which can be coupled to a sheet processing apparatus capable of selectively subjecting an image formed sheet to postprocessing such as stapling. Their sheet processing apparatus can lift and lower a sheet stack tray.
The tray is integrated with a driving member and is lifted and lowered by a pinion in the driving member and a rack provided in the apparatus. The tray is coupled to a belt and is lifted and lowered by a pulley (see Japanese Patent Application Laid-Open (JP-A) Nos. 2006-256732, and 2003-95527)
As described above, the lifting and lowering tray in the related art is of a rack & pinion type or a belt & pulley type for phase alignment of right and left rails as well as rails on both sides of a frame for supporting the load of the tray. The lifting and lowering tray need to be assembled and maintained while the installing posture of the apparatus in the used state is held. Since the operating procedure and the operating space are limited, there exist the following problems.
In the rack & pinion type described in JP-A No. 2006-256732, the tray which is integrated with the driving member is assembled to the rack extended in the lifting and lowering direction from above the apparatus in the used state. A space is required outside the lifting and lowering movement region (above or below the rack) during assembling.
Also in the belt & pinion type described in JP-A No. 2003-95527, the tray is assembled to a guide channels, extended in the lifting and lowering direction, which are formed in a front surface of a stacking wall from above the apparatus in the used state. The assembly properties and the maintenance properties are poor. Further, the member which couples the stack tray to the raising and lowering driving member is fixed to the belt. Phase alignment is necessary.
The present invention provides a lifting and lowering mechanism of a sheet stacking apparatus which is excellent in the assembly properties and the maintenance properties.
To achieve the above objects, a representative composition according to the present invention includes: a stacking portion on which a discharged sheet is stacked; a housing portion which can support the stacking portion so as to lift and lower the stacking portion; and a lifting and lowering mechanism which lifts and lowers the stacking portion. In the composition, the stacking portion has a connecting portion which connects the stacking portion to the housing portion, the connecting portion can connect the stacking portion to the housing portion in a direction crossing the lifting and lowering direction of the stacking portion.
The present invention has the above composition. The lifting and lowering mechanism of the sheet stacking apparatus of the present invention is connected detachably in the range of the sheet stacking and sheet takeout space in the used state. Other members around the lifting and lowering mechanism need not be detached. The lifting and lowering mechanism of the sheet stacking apparatus can be excellent in the assembly properties and the maintenance properties.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Exemplary embodiments carrying out the present invention will be described below in detail with reference to the drawings. The dimensions, materials, shapes, and relative arrangement of components described in the embodiments should be changed appropriately according to the composition of an apparatus to which the present invention is applied and various conditions. The scope of the present invention is not limited to the following embodiments.
The schematic composition of an image forming apparatus will be described.
As illustrated in
As illustrated in
The image forming process unit 9 which composes an image forming portion forms an image (toner image) by an electrophotographic system. Specifically, a photosensitive drum 10 as an image bearing member provided in the image forming process unit 9 is charged. A laser scanner 11 irradiates the photosensitive drum 10 with light to form an image. The image is developed using toner. The developed toner image is transferred onto the sheet S.
The sheet S on to which the toner image is transferred from the photosensitive drum 10 is conveyed to a fixing device 12. The image is then fixed to the sheet S by applying heat and pressure.
The image fixed sheet S is conveyed by a conveying path switching member 13 to either of a face-up conveying path 14 and a switchback conveying path 15 which reverses the leading and trailing ends of the sheet.
The sheet which has been conveyed to the switchback conveying path 15 is conveyed by a switchback conveying roller 16 until the trailing end of the sheet passes through a reverse switching member 17. The sheet is reversed and conveyed by the switchback conveying roller 16 such that its trailing end in turn becomes its leading end. The reversed sheet is switched by the reverse switching member 17 and is then conveyed to a face-down conveying path 18.
The face-up conveying path 14 and the face-down conveying path 18 are joined just before a discharge roller 19. Both the sheet guided to the face-up conveying path 14 and the sheet guided from the switchback conveying path 15 to the face-down conveying path 18 are discharged from the image forming apparatus body 2 by the discharge roller 19.
As illustrated in
The scanner portion 21 has a movable optical carriage 27 and reads the described information of the original. In the scanner portion 21, the described information of the original set on the original base plate glass 26 is scanned horizontally and read by the optical carriage 27, and is then photoelectrically converted by a CCD 28.
The ADF 22 separates and feeds a plurality of originals stacked on an original stack tray 23 one by one by a feeding roller 24. The ADF 22 then passes each of the originals through an original reading position 25 of the optical carriage 27 stopped in the scanner portion 21. During the passing, the optical carriage 27 reads the described information of the original which is being conveyed.
(Sheet Processing Apparatus)
The sheet processing apparatus 1 (the sheet stacking apparatus) of this embodiment will be described with reference to
A position where the user faces an operation displaying device (not illustrated) to perform various inputs/settings to the image forming apparatus body 2 is called the front side of the image forming apparatus, and the rear side of the apparatus is called the rear side.
In
When the stapling process is selected, the sheet received from the image forming apparatus body 2 is temporarily stacked on an intermediate stacking portion 34. A conveying guide 38 is provided in the upper portion of the intermediate stacking portion 34.
The sheet stacked on the intermediate stacking portion 34 is aligned by an aligning roller 36 in the sheet conveying direction. The aligning roller 36 can be moved up and down relative to the stacking surface of the intermediate stacking portion 34. The lowered aligning roller 36 is abutted onto the surface of the sheet on the intermediate stacking portion 34. The lowered aligning roller 36 is then moved so as to abut the trailing end of the sheet onto an aligning reference wall 37 for alignment. The lifted aligning roller 36 is retracted to a position which is not troublesome when the sheet is conveyed into the intermediate stacking portion 34.
The sheet stacked on the intermediate stacking portion 34 is aligned in the sheet width direction by an aligning member 500. The aligned sheet is stapled by a stapler 54 (sheet processing portion) located on the front side of the apparatus.
As illustrated in
A stacking height detection flag 39 is provided on the downstream side of the upper discharge roller 32 and the lower discharge roller 33. The stacking height detection flag 39 detects that the topmost sheet surface height of the sheets stacked on the first stack tray 35 has reached a predetermined height. A central processing unit (CPU), not illustrated, judges that the sheets are stacked at full height based on a detecting signal indicating that the top most sheet surface height has reached the predetermined height. The upper discharge roller 32 can be retracted from the lower discharge roller 33 to a position indicated by the dashed line in
In addition to the first stack tray 35 described above, the sheet processing apparatus 1 has at least a second stacking portion on which the received sheet is stacked. In
Referring now to
As illustrated in
(Tray Lifting and Lowering Mechanism)
The tray lifting and lowering mechanism (lifting and lowering mechanism) will be described.
As illustrated in
The tray coupling member 100 is installed in a housing portion (a housing front frame 114, a housing rear frame 115, and a housing center frame 119). The XZ load supporting rail (rail member) 102 as a guide member is provided in the housing front frame 114 or the housing rear frame 115 of the housing portion so as to be extended along the lifting and lowering direction. The XZ load supporting rail 102 has opposing guide surfaces in the YZ plane.
As illustrated in
The tray coupling member 100 is installed on the opposite side of the first stack tray 35 so as to interpose the stacking wall 109 therebetween. A front arm portion 110 and a rear arm portion 111 of the tray coupling member 100 pass through the elongated holes 112 and 113 on the front and rear sides of the apparatus of the stacking wall 109 to protrude from the face portion of the stacking wall 109. The front arm portion 110 and the rear arm portion 111 are then connected to the first stack tray 35. A stacking portion (the first stack tray 35, the stacking wall 109, and the tray coupling member 100) is thus composed.
The upper XZ load supporting roller 101a and the lower XZ load supporting roller 101b guided by the XZ load supporting rail 102 are held onto the front arm portion 110 of the tray coupling member 100. The upper XZ load supporting roller 101a and the lower XZ load supporting roller 101b guided by the XZ load supporting rail 102 are held onto the rear arm portion 111 of the tray coupling member 100.
The XZ load supporting rail 102 is fixed to the housing front frame 114 or the housing rear frame 115. The lower portion of the XZ load supporting rail 102 is closed by a portion of the housing front frame 114 or the housing rear frame 115. The XZ load supporting rail 102 is U-shaped. In the assembled state, the XZ load supporting rail 102 is engaged with the XZ load supporting roller 101 to suppress the rattling of the tray coupling member 100 in the XZ direction, thereby receiving the load. The housing center frame 119 is disposed between the housing front frame 114 and the housing rear frame 115.
Two YZ load supporting rollers 103 as a restricting portion are axially supported on the upper side of the back side of the tray coupling member 100. Two YZ load supporting rollers 103 as the restricting portion are axially supported on the lower side of the back side of the tray coupling member 100.
The YZ load supporting rail 104 which composes the restricting portion together with the YZ load supporting roller 103 is fixed to the base 116. In the assembled state, the YZ load supporting rollers 103 interpose the YZ load supporting rail 104 therebetween to suppress the rattling of the tray coupling member 100 in the YZ direction, thereby receiving the load.
The rotatable tray lifting and lowering lever 106 is axially rotatably supported by the fulcrum shaft 117 of the base 116. The lifting and lowering roller 107 is axially rotatably supported at the top end of the tray lifting and lowering lever 106.
A rectangular hole portion 118 is provided in the substantially center of the tray coupling member 100. In the assembled state, at first the lifting and lowering roller 107 stands by in a lower limit position of a rotating range. When the tray coupling member 100 is in an inclined state on the way to assemble, the lifting and lowering roller 107 is fitted into the hole portion 118 and the upper side of the hole portion 118 is lifted by the lifting and lowering roller 107 by an upward rotation of the lifting and lowering roller 107. The tray coupling member 100 is lifted and lowered.
A notch 120 is provided at the lower end of the XZ load supporting rail 102. The notch 120 is opened to the downstream side in the sheet discharge direction perpendicular to the lifting and lowering direction of the first stack tray 35. The notch 120 is of the size through which one of the XZ load supporting rollers 101 can pass, and is smaller than the pitch between the upper XZ load supporting roller 101a and the lower XZ load supporting roller 101b. When the lower portion of the rail is closed, the stacking portion can be detachably fitted into the notch 120 on the downstream side in the sheet discharge direction crossing the lifting and lowering direction of the stacking portion. The stacking portion and the lifting and lowering mechanism can be assembled in a direction crossing the lifting and lowering direction of the first stack tray 35 without changing the installing posture of the housing. The workability can be improved. Here, the installing posture of the housing coincides with the installing posture of the apparatus in the used state. The installing posture of the housing during assembling coincides with the installing posture of the apparatus in the used state. As in assembling, during maintenance, the stacking portion and the lifting and lowering mechanism can be assembled in a direction crossing the lifting and lowering direction of the first stack tray 35 without changing the installing posture of the apparatus in the used state.
In this embodiment, the notch 120 is opened to the downstream side in the sheet discharge direction. The present invention is not limited to this. When the stacking portion and the lifting and lowering mechanism are connected detachably during assembling and maintenance without changing the installing posture of the housing, the notch 120 may be opened in other directions such as a direction perpendicular to the sheet discharge direction.
As illustrated in
As illustrated in
In
When the top end of the first stack tray 35 is lifted by the user to apply a force which rotates the first stack tray 35 about the stacking wall 109, falling of the tray coupling member 100 out of the XZ load supporting rail 102 can be prevented.
As illustrated in
As illustrated in
As illustrated in
When the tray lifting and lowering lever 106 is rotated, the sensor light-shielding portion 140 light shields the upper limit detecting sensor 141 and the lower limit detecting sensor 142 to control rotation.
A gear 143 provided on the tray lifting and lowering lever 106 and the gears 144, 145, 146, 147, 148, and 149 sequentially coupled thereto are disposed on the tray lifting and lowering lever 106. The motor 150 is also disposed. The tray lifting and lowering lever 106 is rotated by these driving members, the upper and lower limit detecting sensor information, and the central processing unit (CPU), not illustrated.
As illustrated in
The upper limit detecting sensor 141 and the lower limit detecting sensor 142 are attached to the outer surface of the lifting and lowering driving box 160. The lifting and lowering driving box 160, the tray lifting and lowering lever 106, and the fulcrum shaft 117 are attached to the base 116. The gear 143 on the tray lifting and lowering lever and the gear 144 coupled thereto are coupled through a notch provided in the base 116. The base 116 to which the members are attached can be attached to the housing center frame 119 on the downstream side in the sheet discharge direction crossing the lifting and lowering direction of the first stack tray 35 (on the rear side in the drawing).
According to the above composition, the phase alignment during the assembling of the rack & pinion type and the belt & pinion type becomes unnecessary. The stacking portion is connected detachably to the housing portion and the lifting and lowering mechanism on the downstream side in the sheet discharge direction crossing the lifting and lowering direction of the first stack tray 35. In the state that the stacking portion is not attached, the lifting and lowering mechanism is connected detachably to the housing portion on the downstream side in the sheet discharge direction. The lifting and lowering mechanism of the sheet processing apparatus is connected detachably within the sheet stacking and sheet takeout space. The lifting and lowering mechanism of the sheet processing apparatus can be excellent in the assembly properties and the maintenance properties.
As illustrated in
In
The fulcrum shaft 117 of the tray lifting and lowering lever 106 is located on the R side from the center CT. The lifting and lowering roller 107 which is abutted onto and lifts the tray coupling member 100 is located on the L side from the center CT. The tray coupling member 100 receives the rotational force clockwise from the tray lifting and lowering lever 106 on the L side from the center CT to receive the force tilting the tray coupling member 100 in the direction indicated by the arrow A.
As illustrated in
A pair of rotating members (YZ load supporting rollers 103a and 103b) are opposite so as to interpose the YZ load supporting rail 104 therebetween. A pair of rotating members (YZ load supporting rollers 103c and 103d) are opposite so as to interpose the YZ load supporting rail 104 therebetween. The plurality of pairs of the YZ load supporting rollers 103 are provided along the lifting and lowering direction of the first stack tray 35.
As illustrated in
The sheet processing apparatus moves the sheet to the R side to staple it. The R side including the weight of the staple becomes heavy to receive the force in the direction indicated by the arrow A illustrated in
As described above, according to this embodiment, the tray is supported only by the rollers and the rails so as to be lifted and lowered. No expensive parts such as a belt are used, which reduces the cost. In the assembled state, the roller of the lifting and lowering lever has only to engage the tray supporting members. The phase alignment in the related art is unnecessary. This brings about excellent assembly properties of the tray to the apparatus body.
A second embodiment will be described using the drawings.
As illustrated in
In the first embodiment, the XZ load supporting rail 102 is disposed in the housing portion. In this embodiment, the XZ load supporting rail 202 is formed integrally with the base 116 which composes the lifting and lowering mechanism along the lifting and lowering direction of the first stack tray 35. The driving members (gears 144 to 149 and a motor 150), the members (the base 116 and the lifting and lowering driving box 160) which support the driving members, and the rail member can form a unit. All the members related to the lifting and lowering function are connected detachably as a unit to the housing portion.
As described above, the XZ load supporting rail 202 may be provided in one position. A part or all of the XZ supporting rail may be formed by a part of the housing frame or the base 116 in the lifting and lowering mechanism. The XZ load supporting roller 101 which composes the connecting portion which supports the XZ load may be a sliding member, not a rolling member such as a roller. The driving member may be of the rack & pinion type or the belt & pulley type.
In the above composition, the stacking portion is connected detachably to the discharge portion and the lifting and lowering mechanism on the downstream side in the sheet discharge direction. The stacking portion can be assembled in a direction crossing the lifting and lowering direction of the first stack tray 35 without changing the installing posture of the lifting and lowering mechanism. This results in improvement of workability.
A third embodiment will be described with reference to the drawing.
As illustrated in
A recessed space is provided between the image forming apparatus body 2 and the image reading portion 3 which include the image forming portion. The image formed sheet S is discharged into the recessed space (sheet discharge space). The composition of the image forming apparatus body 2 and the image reading portion 3 illustrated in
In the internal discharge type image forming apparatus, regardless of the existence of the image forming apparatus body and the image reading portion on the upper and lower sides of the sheet stacking space, the stacking portion and the lifting and lowering mechanism in the present invention can be detached without being lifted and lowered to the outside of the sheet stacking range. As in the example illustrated in
In the above, regarding the embodiment, description has been made of structure the sheet stacking apparatus is incorporated into the sheet processing apparatus. The sheet stacking apparatus according to the present invention structured so as to be incorporated into the image forming apparatus body is also applicable.
Referring now to
As illustrated in
In
In
In
According to this embodiment, the rack gear which composes the tray lifting and lowering mechanism can be folded. As in the rotating type lifting and lowering lever of the above embodiment, an inexpensive lifting and lowering mechanism can be arranged on the opposite side of the stack tray so as to interpose the stacking wall 109 therebetween while securing the sufficient amount of lifting and lowering.
Referring now to
As illustrated in
A driving gear 305 is rotated forwardly and reversely by the driving force from the driving source. When the tray coupling member 100 is moved upward, the driving gear 305 is rotated clockwise. When the tray coupling member 100 is moved downward, the driving gear 305 is rotated counterclockwise. The driving gear 305 is engaged with a gear 306. The gear 306 is engaged with the fan-type gear 303. The gear 306 is engaged with a gear 307. The gear 307 is engaged with the fan-type gear 304. The driving gear 305 is rotated clockwise. Both the lever members 300 and 301 are rotated so as to move the tray coupling member 100 upward and are rotated counterclockwise. Both the lever members 300 and 301 are rotated so as to move the tray coupling member 100 downward.
The lever members 300 and 301 provided symmetrically with respect to the center in the width direction are rotated symmetrically about the fulcrum shafts 303a and 304a forwardly and reversely. The shafts 300a and 301a are moved in the slit 308 while restricting the rattling in a direction crossing the lifting and lowering direction of the first stack tray 35. The XZ load supporting rail 102 as the rail member and the XZ load supporting roller 101 as the rotating member guide the tray coupling member 100. The tray coupling member 100 is moved in the up and down directions so as not to be tilted. Both the lever members 300 and 301 function as the restricting unit to move the tray coupling member 100.
As described above, according to this embodiment, the laterally long slit 308 provided in the tray coupling member 100 and the two symmetric lever members 300 and 301 are engaged in two positions. While the tray coupling member 100 is lifted and lowered, the rotational force in the YZ direction is received to restrict the rattling. As in the above embodiments, the lifting and lowering mechanism is arranged on the rear side of the stacking surface to suppress the tilting of the first stack tray 35. By this, the second rotating member and the second rail member as the restricting portion of the above form become unnecessary. Furthermore, a more inexpensive lifting and lowering mechanism can be realized.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2007-316924, filed Dec. 7, 2007, No. 2008-032545, filed Feb. 14, 2008, No. 2008-289458, filed Nov. 12, 2008 which are hereby incorporated by reference in their entirety.
Number | Date | Country | Kind |
---|---|---|---|
2007-316924 | Dec 2007 | JP | national |
2008-032545 | Feb 2008 | JP | national |
2008-289458 | Nov 2008 | JP | national |