Field of the Invention
The present invention relates to a sheet feeding apparatus and to an image forming apparatus including the sheet feeding apparatus.
Description of the Related Art
A conventional image forming apparatus such as a printer, a copier, a facsimile includes a sheet feeding apparatus feeding a sheet to an image forming unit. The sheet feeding apparatus includes a pickup roller delivering the sheet stacked on a sheet supporting portion and a separating portion separating the sheet one by one in case the pickup roller delivers multiple sheets.
The separating portion includes a retard separating system in which a feed roller rotating in the same direction with a pickup roller and a retard roller in pressure contact with the feed roller with a predetermined pressure-contact force (nip pressure). It is noted that a drive of a certain torque (rotational torque), is applied to the retard roller in a direction reverse to a sheet conveyance direction (reverse direction) through a torque limiter, so that the retard roller can rotate in either direction of the sheet conveyance direction and the reverse direction.
The separating portion of the retard separating system prevents multiple feeding by rotating the retard roller in the reverse direction when two or more sheets enter a nip portion (separating nip portion), between the retard roller and the feed roller. The retard roller rotates following the feed roller when one sheet or no sheet enters the separating nip portion.
In order to improve stability in the sheet feeding operation, some sheet feeding apparatuses having the separating portion of the retard separating system are configured to switch the pickup roller between a separation state in which the pickup roller is separated from the sheet on the tray and an abutment state in which the pickup roller abuts with the sheet. In the case of a manual sheet feeding apparatus as an example of sheet feeding apparatus in particular, a user cannot set a sheet on a manual sheet feed tray in the abutment state. Therefore, it is necessary to switch the pickup roller to the separation state in setting the sheet.
Therefore, a conventional sheet feeding apparatus includes a lift mechanism lifting the pickup roller from an abutment position where the pickup roller is in contact with the sheet and to a separate position separated from the sheet. In setting the sheet, the pickup roller is moved to the separate state by the lift mechanism. As such a lift mechanism, U.S. Pat. No. 8,800,986 discloses a configuration using an idle gear interposed between the pickup roller and the feed roller. In this configuration, a corrugated washer is disposed between a holder liftably holding the pickup roller and the idle gear. Then, the holder turns by a frictional force generated by the corrugated washer when the idle gear rotates, and a pressing force pressing the pickup roller against the sheet is generated.
Japanese Patent Application Laid-open No. 2005-75479 also discloses another lift mechanism configured to lift a pickup roller through a cam rotated by a motor.
Here, since the contact pressure of the pickup roller against the sheet depends on the frictional force between the members in the lift mechanism described in U.S. Pat. No. 8,800,986, there is a possibility that the contact pressure is unstablized due to wear of frictional surfaces and to environmental conditions such as humidity.
In the case of the lift mechanism lifting the pickup roller by the cam driven by the motor and a cam follower actuated by the cam, it is possible to avoid such situation that the contact pressure of the pickup roller against the sheet fluctuates due to the friction and others. However, in the case of the lift mechanism using the cam and the cam follower, it has been difficult to dispose the cam and the cam follower in such a manner as to realize downsize of the apparatus. In the case of the manual sheet feeding apparatus, which is disposed in a narrow space in a side part of the image forming apparatus, in particular, the disposition of the cam and the cam follower is essential because the lift mechanism is also required to be downsized.
According to one aspect of a sheet feeding apparatus of the invention, the sheet feeding apparatus includes a sheet supporting portion, a rotary feed member, a rotary conveyance member, a rotary separation member, rotary conveyance member, a second shaft, a holding portion, a lifting portion, and a drive unit. The rotary feed member feeds a sheet supported on the sheet supporting portion and the rotary conveyance member conveys the sheet fed from the rotary feed member. The second shaft is configured to rotate the rotary separation member, which separates the sheet with the rotary conveyance member. The rotary feed member is held by the holding portion, which moves up and down. The lifting portion moves the holding portion to move the rotary feed member to a standby position above the sheet and an abutment position where the rotary feed member abuts with the sheet. The lifting portion includes a drive member driven by the drive unit and an actuation member driven by the drive member and turns the holding portion up and down. The actuation member is disposed on the second shaft.
According to another aspect of a sheet feeding apparatus of the invention, the sheet feeding apparatus includes a sheet supporting portion, a rotary feed member, a rotary conveyance member, a rotary separation member, rotary conveyance member, a second shaft, a holding portion, a cam shaft, a cam follower, and an abutment portion. The rotary feed member is held by the holding portion, which pivots up and down, and feeds the sheet. The rotary conveyance member is rotated by the first shaft and conveys the sheet fed from the rotary feed member. The second shaft is configured to rotate the rotary separation member to separate the sheet with the rotary conveyance member. The cam shaft is attached with a cam and rotates by being driven by a driving source. The cam follower is supported on the second shaft and turns independently from the second shaft along with a rotation of the cam. The abutment portion provided on the holding portion is abuttable with the cam follower. In response to a rotation of the cam, the cam follower turns the holding portion through the abutment portion to move the rotary feed member between a standby position above the sheet and an abutment position where the rotary feed member abuts with the sheet supported on the sheet supporting portion.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings. The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments, features, and aspects of the invention and, together with the description, serve to explain the principles of the invention.
An embodiment of the present invention will be described in detail below with reference to the drawings.
In
The image forming unit 201B is a four drum full-color type and includes a laser scanner 210 and four process cartridges 211 forming toner images of four colors of yellow (Y), magenta (M), cyan (C), and black (K). Here, each process cartridge 211 includes a photosensitive drum 212, an electric charger 213, a developer 214, and a cleaner not shown. The image forming unit 201B also includes an intermediate transfer unit 201C disposed above the process cartridges 211.
The intermediate transfer unit 201C includes an intermediate transfer belt 216 wrapped around a driving roller 216a and a tension roller 216b. The intermediate transfer unit 201C includes primary transfer rollers 219 provided inside a loop of the intermediate transfer belt 216 and in contact with the intermediate transfer belt 216 at positions respectively facing the photosensitive drums 212. Here, the intermediate transfer belt 216 is composed of a film member, is disposed so as to be in contact with the respective photosensitive drums 212, and is rotated in a direction of an arrow in
Then, each toner image having negative polarity on the photosensitive drum is sequentially superimposed and transferred onto the intermediate transfer belt 216 by a positive transfer bias applied to the intermediate transfer belt 216 through the primary transfer roller 219. Thereby, the color image is formed on the intermediate transfer belt 216. A secondary transfer roller 217 composing a secondary transfer portion transferring the color image formed on the intermediate transfer belt 216 is provided at a position facing the driving roller 216a in the intermediate transfer unit 201C.
Still further, a fixing unit 220 is disposed above the secondary transfer roller 217, and a reverse discharge unit 201D is disposed above (on an upper-left side in the
The sheet feeding apparatus 230 includes a sheet feed cassette 11 and a pickup roller 8 coming into contact with and an uppermost sheet among the sheets P stored in the sheet feed cassette 11 and rotating to deliver the uppermost sheet out of the sheet feed cassette 11. The manual sheet feeding apparatus 100 is configured to feed a large size sheet which cannot be stored in the sheet feed cassette 11, a sheet whose rigidity is high such as an envelope and a postcard, and a special sheet such as an OHP sheet and an embossed sheet, other than a plain sheet. The manual sheet feeding apparatus 100 includes a manual sheet feed tray 111 on which the sheet is set and a pickup roller 101 feeding the sheet on the manual sheet feed tray 111. The printer 201 also includes toner cartridges 215 replenishing toners to the developers 214 and a control portion 260, which controls an image forming operation of the printer body 201A and sheet feeding operations of the sheet feeding apparatus 230 and the manual sheet feeding apparatus 100.
Next, the image forming operation of the printer 201 will be described. When image information of a document is read by the image reading apparatus 202, the image information is processed and is then converted into electrical signals to be transmitted to the laser scanner 210 of the image forming unit 201B. In the image forming unit 201B, a surface of the photosensitive drum 212 is uniformly charged to the predetermined potential in the predetermined polarity by the charger 213. Then, the surface of the photosensitive drum 212 is sequentially exposed by a laser beam from the laser scanner 210.
Thereby, electrostatic latent images, each corresponding to a monochromatic image of yellow, magenta, cyan, and black, are sequentially formed on the photosensitive drums 212 of the process cartridges 211. After that, the electrostatic latent images are developed and visualized by the respective color toners. Then, the respective color toner images on the photosensitive drums 212 are sequentially superimposed and transferred onto the intermediate transfer belt 216 by the primary transfer bias applied to the primary transfer rollers 219. Thus, the toner image is formed on the intermediate transfer belt 216.
In parallel with the image forming operation, the sheet P stored in the sheet feed cassette 11 is delivered by the pickup roller 8, i.e., a rotary feed member, provided in the sheet feeding apparatus 230. The delivered sheet P is separated one by one by a separating portion composed of a feed roller 9, i.e., a rotary conveyance member, and a retard roller 10, i.e., a rotary separation member, in pressure contact with the feed roller 9. The sheet P is then conveyed to a registration roller pair 240 to correct a skew of the sheet P. In a case of manually feeding a sheet, the sheet P set on the manual sheet feed tray 111 is delivered and conveyed by a pickup roller 101, i.e., a rotary feed member, toward the registration roller pair 240.
After correcting the skew, the sheet P is conveyed by the registration roller pair 240 to the secondary transfer portion where the toner images are collectively transferred onto the sheet P by the secondary transfer bias applied to the secondary transfer roller 217. The sheet P onto which the toner images have been transferred is conveyed to the fixing unit 220 to undergo heat and pressure in the fixing unit 220. Thereby, the respective color toners melt and blend with each other and are fixed as a color image on the sheet P.
After that, the sheet P onto which the image has been fixed is discharged to a sheet discharge space S by a first sheet discharge roller pair 225a and a second sheet discharge roller pair 225b provided downstream of the fixing unit 220 and is stacked on a stacking portion 223 projecting on a bottom surface of the discharge space S. In the case of forming images on both surfaces of the sheet P, the sheet P is conveyed to the re-conveying path R by a reversing roller pair 222 and is conveyed again to the image forming unit 201B.
As shown in
The pickup roller 101 is rotatably supported by a sheet feed holder 135 through a pickup roller shaft 101A. The sheet feed holder 135 is a holding portion supporting the rotary feed member and is supported by the feed roller shaft 134 so as to pivot up and down. The pickup roller 101 is rotatable in synchronism with the feed roller 102 because driving force of the feed roller shaft 134 is transmitted to the pickup roller 101 through a driving gear train 116. The pickup roller 101, the pickup roller shaft 101A, the driving gear train 116, the sheet feed holder 135, and others compose a lift unit 1061.
The retard roller 103, i.e., the rotary separation member, is attached to a supporting shaft 133. The supporting shaft 133 is supported by a holding portion not shown so as to be able to move in parallel with the vertical direction in
As shown in
As shown in
Still further, as shown in
As shown in
A cam follower 131, i.e., an actuation member, is turnably attached to the driving shaft 118 composing the separation roller shaft 133a. The cam follower 131 is disposed such that an upper end thereof comes into contact with the convex portion 136 of the sheet feed holder 135. The cam follower 131 is supported on the driving shaft 118 and is turnable independently from the driving shaft 118 around an axial line of the driving shaft 118 while being restricted movement in an axial direction. Provided under the cam follower 131 is a cam 132, i.e., a drive member. As shown in
As shown in
It is possible to efficiently dispose the manual sheet feeding apparatus 100 in a narrow area of one side surface of the printer body 201A by disposing the respective shafts 134, 118 and 132 in the vertical direction as described above. That is, it is possible to minimize a range in a lateral direction occupied by the manual sheet feeding apparatus 100 in a front view of the printer body 201A by disposing the cam 132, the cam follower 131, and the respective shafts 134, 118, and 132a like the present embodiment. This arrangement makes it possible to suppress the size of the printer body 201A from being increased and to construct the printer body 201A in compact in the width direction.
In response to a rotation of the cam shaft 132a by being driven by a drive unit described later, the cam 132 rotates to turn the cam follower 131. As shown in
In response to a start of a sheet feeding operation, the drive unit described later is driven, and the cam 132 rotates in a direction indicated by an arrow R9 in
After that, in response to the rotation of the cam 132 in the direction of the arrow R9 in
It is noted that the sheet feed motor 127 may be installed in the door 221. However, if the sheet feed motor 127 is installed in the door 221, serviceability is worsened because a bundle of wires becomes complicated by providing the electric component on the door 221 side and it becomes cumbersome in replacing the manual sheet feeding unit due a failure of a component and others for example. Still further, as the weight of the door 221 increases, operability in opening/closing the door 221 is worsened. Therefore, the sheet feed motor 127 is installed in the printer body 201A to lighten and to improve serviceability of the door 221 in the present embodiment.
Still further, the rocking gear 126 rotated by the sheet feed motor 127 is made to rock such that the rocking gear 126 can be securely meshed with the stepped gear 125 provided in the door 221. That is, according to the present embodiment, the rocking gear 126 is meshed firmly with the stepped gear 125 by configuring the gear driven by the sheet feed motor 127 as the rocking gear. It is noted that the rocking gear 126 is rotatably held by a holder 126b. The holder 126b is urged in a direction of meshing the rocking gear 126 with the stepped gear 125 by the pressing spring 140.
In the sheet feeding operation, the rotation of the rollers conveying the sheet is essential in conveying the sheet. For instance, if a meshing part of the rocking gear 126 and the stepped gear 125 causes tripping, feeding failure of the sheet occurs and the sheet feeding operation does not finish. Meanwhile, the rotation of the cam 132, i.e., the lifting operation of the pickup roller 101, is less influential to the sheet feeding operation even if tripping occurs.
Therefore, as shown in
The rotation direction of the sheet feed motor 127 in feeding the sheet as described above is the normal direction. Meanwhile, the sheet feed motor 127 is rotated in the reverse direction in lifting the pickup roller 101. Then, as shown in
Meanwhile, the stepped gear 125 provided on the unit side is meshed with the conveyance drive gear 121 as shown in
Here, as shown in
The first one-way clutch 138a is configured to transmit a rotation of the conveyance drive gear 121 (in a direction indicated by an arrow in
The second one-way clutch 138b is configured to transmit a rotation in one direction of the separation drive stepped gear 122 (in a direction indicated by an arrow in
The third one-way clutch 139 is configured to transmit a rotation of the cam driving gear 123 to the cam shaft 132a when the conveyance drive gear 121 and the separation drive stepped gear 122 rotate in a direction indicated by arrows in
Thus, provided with the one-way clutches 138a, 138b, and 139 as described above, the feed roller shaft 134 and the supporting shaft 133 is rotated by the operations of the first and second one-way clutches 138a and 138b when the sheet feed motor 127 rotates in the normal direction, thereby the pickup roller 101, the feed roller 102, and the retard roller 103 being rotated. At this time, because the cam driving gear 123 idles by the third one-way clutch 139, the cam 132 does not rotate.
Still further, in response to the reverse rotation of the sheet feed motor 127, the conveyance drive gear 121 and the separation drive stepped gear 122 idle due to the first and second one-way clutches 138a and 138b, and the pickup roller 101, the feed roller 102, and the retard roller 103 do not rotate. Meanwhile, the cam driving gear 123 rotates due to the third one-way clutch 139, so that the cam 132 rotates and along with that, the sheet feed holder 135 is lifted through the cam follower 131. Thus, according to the present embodiment, it is possible to conduct the sheet feeding operation and the lifting operation of the pickup roller 101 by the normal and reverse rotations of the sheet feed motor 127.
Next, a control operation made by the control portion 260 will be described. Until when the sheet feeding operation is started, the pickup roller 101 is made to stand by at the standby position separated from the sheet P on the manual sheet feed tray 111 as shown in
Thereby, the cam 132 rotates and the cam follower 131 turns in the direction indicated by the arrow R8 from the state shown in
Next, the control portion 260 rotates the sheet feed motor 127 in a normal direction. Thereby, the pickup roller 101, the feed roller 102, and the retard roller 103 rotate and feed the sheet one by one. Here, a time during which the sheet feed motor 127 is rotated in a normal direction is set based on the size of the sheet to be fed, which size is detected by the drawing sensor S10. Then, the set time elapses and the feed of the sheet ends, the control portion 260 rotates the sheet feed motor 127 in the reverse direction to move the pickup roller 101 to the standby position.
In the case of a consecutive sheet feeding, the control portion 260 repeats ON (normal rotation) and OFF of the sheet feed motor 127 to repeat the rotation and stop of the pickup roller 101, the feed roller 102, and the retard roller 103. A distance (inter-sheets) between a preceding sheet and a succeeding sheet to be consecutively fed is set by an OFF time of the sheet feed motor 127.
Here, it takes a long time and the inter-sheet distance is prolonged if the pickup roller 101 is lifted every time when one sheet is delivered. Then, according to the present embodiment, the lifting operation of the pickup roller 101 is not carried out and the pickup roller 101 is kept in contact with the sheet in consecutively feeding the sheets. Then, the pickup roller 101 is lifted to the standby position as soon as the job ends.
It is possible to minimize the inter-sheet distance and to increase productivity as the image forming apparatus just by repeating the rotation and stoppage of the sheet feed motor 127 without lifting the pickup roller 101 as described above. It is noted that if the sheet feed motor 127 is switched to OFF, both the pickup roller 101 and the feed roller 102 stop, thus losing power for delivering the sheet. Therefore, timing for turning OFF the sheet feed motor 127 must be set after when a front edge of the delivered sheet arrives at the drawing roller 104.
Here, the cam follower 131 is disposed turnably around the driving shaft 118 (the second shaft 133a) as shown in
Note that while it is also possible to directly push up the sheet feed holder 135 by a cam without interposing the cam follower 131, the cam should be disposed so as to avoid the driving shaft 118 if a movable range in lifting the sheet feed holder 135 is taken into account. In this case, a cam shaft must be disposed in a vicinity of an upstream in the sheet feeding direction of the driving shaft 118. As a result, the length in the sheet feeding direction of the manual sheet feeding apparatus 100 is prolonged, thus increasing the sizes of the manual sheet feeding apparatus 100 and of the printer body.
As described above, the cam follower 131 is turnably disposed around the supporting shaft 133 in the present embodiment. This arrangement makes it possible to prevent the cam follower 131 from interfering with the supporting shaft 133. As a result, it is possible to lift the pickup roller at a low cost without increasing the size of the sheet feeding apparatus configured to be able to lift the pickup roller and to drive the pickup roller and others by one motor.
It is noted that while the case of feeding the sheet and of lifting the pickup roller by bidirectional rotation of the motor has been shown in the present embodiment, it is also possible to arrange such that the feed of the sheet and the lift of the pickup roller are made by rotating the motor in one direction (only the normal rotation). In this case, because rotations of the pickup roller, the feed roller, and the retard roller and the rotation of the cam must be made at different timings, it is necessary to provide a mechanism such as a clutch for transmitting and disconnecting the drive in the respective driving systems. It is also possible to arrange such that the feed roller, the retard roller and the cam are rotationally driven by different driving sources.
Still further, while the sheet feeding apparatus is configured such that the rotation from the sheet feed motor 127 is transmitted to the retard roller 103 in the direction opposite to the sheet feeding direction, the sheet feeding apparatus may be configured such that no rotation is transmitted to the retard roller 103. That is, while the separation roller shaft 133a composed of the supporting shaft 133 and the driving shaft 118 and the torque limiter 105 are configured in the same manner with the present embodiment, the driving shaft 118 is fixed to the sheet feed frame so as not to rotate. Thereby, when a plurality of sheets enters the nip portion between the feed roller 102 and the retard roller 103, the sheets are delivered by being separated one by one by stopping the retard roller 103 to restrict the sheet under the uppermost sheet from moving.
Still further, while the case when the present invention is applied to the manual sheet feeding apparatus, i.e., one example of the sheet feeding apparatus, has been described in the present embodiment, the present invention is applicable to a sheet feeding apparatus feeding a sheet stacked in a cassette. Still further, while the case in which the present invention is applied to the electrophotographic type image forming apparatus has been described in the present embodiment described above, the present invention is also applicable to an inkjet type image forming apparatus. Still further, while the rotary feed member, the rotary conveyance member, the rotary separation member have been exemplified by using the rollers in the present embodiment described above, a belt-like rotary member may be also used other than the rollers.
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. 2015-095891, filed on May 8, 2015, which is hereby incorporated by reference herein in its entirety.
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