This patent application is based on and claims priority pursuant to 35 U.S.C. ยง119(a) to Japanese Patent Application No. 2014-241362, filed on Nov. 28, 2014, in the Japan Patent Office, the entire disclosure of which is hereby incorporated by reference herein.
1. Technical Field
Embodiments of this invention relate to a sheet conveying device and an image forming apparatus employing the sheet conveying device.
2. Related Art
Hitherto, in image forming apparatuses such as printers, copiers, etc., since the sheet is sometimes skewed when conveyed from a sheet feeding unit, a known system corrects this skew of the sheet.
For example, a gate (i.e., a sheet skew corrector for correcting a skew of the sheet) is placed downstream of a pair of registration rollers in a sheet conveyance direction to open and close a paper sheet conveyance path for the paper sheet. When the paper sheet conveyance path is closed by the gate while the pair of registration rollers is separated from each other, the pair of conveyance rollers placed upstream of the pair of registration rollers in the paper sheet conveyance direction is driven to bring a leading end of the paper sheet in contact with the gate. Since the paper sheet is further conveyed for a predetermined period of time even after being brought into contact with the gate, the leading end of the paper sheet abuts against and is aligned with an abutment face of the gate, thereby making a right angle with the paper sheet conveyance direction. Subsequently, the pair of registration rollers contacts each other to sandwich the paper sheet to regulate movement of a leading end region of the paper sheet while keeping the leading end of the paper sheet contacting the gate. As a result, the skew of the paper sheet caused in the leading end region of the paper sheet between a portion thereof sandwiched by the pair of registration rollers and the leading end thereof is corrected.
At this moment, since a trailing end region of the paper sheet located upstream of the portion sandwiched by the pair of registration rollers is sometimes obliquely sandwiched by the pairs of conveyance rollers, the trailing end region of the paper sheet inclines to the leading end of the paper sheet thereby generating torsion in the paper sheet. In such a torsional condition, however, when the gate is opened the pair of conveyance rollers is at the same time separated, so that the trailing end of the paper sheet can make the right angle with the paper sheet conveyance direction as the portion sandwiched by the pair of registration rollers. Hence, the torsion of the paper sheet is thereby wholly eliminated therefrom. Thus, when the pair of registration rollers is driven at a prescribed time after that, the paper sheet is sent to a transfer section with the skew corrected.
Accordingly, one aspect of the present invention provides a novel sheet conveying device that includes: a sheet skew corrector to correct a skew of a leading end of a sheet inclining from a sheet conveyance direction; and a pair of registration rollers disposed upstream of the sheet skew corrector in the sheet conveyance direction. The pair of registration rollers freely contacts and separates from each other. The pair of registration rollers conveys the sheet downstream of the sheet skew corrector in the sheet conveyance direction when driven at a prescribed time. A pair of conveyance rollers is placed upstream of the pair of registration rollers in the sheet conveyance direction. The pair of conveyance rollers continuously sandwiches the sheet from when the sheet with the skew corrected by the sheet skew corrector is sandwiched by the pair of registration rollers to when a trailing end of the sheet passes between the pair of conveyance rollers.
Another aspect of the present invention provides a novel image forming apparatus that includes an image forming device to form an image on a sheet and the sheet conveying device to convey the sheet toward the image forming device. In the sheet conveying device, torsion of a paper sheet caused when a skew thereof is corrected is cancelled while inhibiting the paper sheet from returning to the sheet skew once again.
Yet another aspect of the present invention provides a novel method of correcting a skew of a sheet. The method includes the steps of: conveying a sheet inclining from a sheet conveyance direction downstream along a sheet conveyance path with a pair of conveyance rollers toward a pair of registration rollers in the sheet conveyance direction while sandwiching the sheet therebetween; separating a pair of registration rollers from each other to open a sheet conveyance path to allow the sheet conveyed by the pair of conveyance rollers to pass therethrough; and conveying a sheet though the pair of registration rollers separating from each other with a pair of bumping rollers disposed between the pair of conveyance rollers and the pair of registration rollers. The method further includes the steps of: bumping a leading end of the sheet with the pair of bumping rollers against a sheet skew corrector disposed downstream of the pair of registration rollers in the sheet conveyance direction; correcting a skew of the leading end with the sheet skew corrector by further conveying the sheet bumping against the sheet skew corrector downstream for a predetermined period of time; and sandwiching the sheet with the skew of the leading end corrected by bringing the pair of registration rollers in contact with each other to close the sheet conveyance path. The method further includes the steps of: separating the pair of bumping roller from each other to open the sheet conveyance path; retracting the sheet skew corrector from the sheet conveyance path to open the sheet conveyance path; and driving the pair of registration rollers sandwiching the sheet therebetween at a prescribed time. The method further includes the steps of conveying the sheet downstream of the sheet skew corrector in the sheet conveyance direction with the pair of registration rollers; and continuously sandwiching the sheet with the pair of conveyance rollers from when the step of sandwiching the sheet with the skew of the leading end corrected by bringing the pair of registration rollers in contact with each other to close the sheet conveyance path is executed until a trailing end of the sheet with the skew of the leading end corrected passes between the pair of conveyance rollers.
A more complete appreciation of the present invention and many of the attendant advantages thereof will be more readily obtained as substantially the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
In the above-described conventional sheet conveying device, before the pair of conveyance rollers is separated, either the trailing end of the paper sheet or a surface of a trailing end region of the paper sheet sometimes contacts a guide plate, such as a bottom plate, a ceiling plate, a side plate, etc. As a result, friction is generated by a contact portion of the trailing end of the paper sheet and/or the surface of the trailing end region of the paper sheet contacting the guide plate. Hence, when the friction is great, the trailing end of the paper sheet cannot precisely make the right angle with the paper sheet conveyance direction even if the pair of conveyance rollers separates. In addition, restoring force generated in the paper sheet in such a situation is obliquely applied from the paper sheet conveyance direction to the portion sandwiched by the pair of registration rollers as well. As a result, when the gate is opened (i.e., retracted from the sheet conveyance path), the paper sheet sandwiched by the pair of registration rollers is directed obliquely. Accordingly, when the paper sheet is conveyed by the pair of registration rollers while keeping the skew, the paper sheet conveyed toward the transfer section is likely in the skew.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views thereof, and in particular to
For example, upon receiving an instruction signal for starting image forming operation from a control unit (200), the photoconductive drum 2Y starts rotating in a direction as shown by arrow B in
When the toner image formed on the photoconductive drum 2Y subsequently reaches the transfer unit 6Y acting as a primary transfer device, the Y toner image is primarily transferred onto the intermediate transfer belt 10 that is rotating in a direction as shown by arrow A in
After the image forming operation is executed in the image forming unit 1Y, similar image forming operation is sequentially executed in the image forming unit 1C. That is, a cyan color toner image (C toner image) is formed on the photoconductive drum 2C and is then primarily transferred onto the intermediate transfer belt 10 under influence of a high voltage applied to the transfer deice 6C (e.g., from a primary transfer high voltage power supply 212) as well.
At this moment, such primarily transfer operation of the C toner image borne on the photoconductive drum 2C onto the intermediate transfer belt 10 is executed in synchronism with the Y toner image, which is previously formed in the image forming unit 1Y, primarily transferred and borne on the intermediate transfer belt 10, and reaches the transfer unit 6C. With this, the Y and C toner images formed in the image forming units 1Y and 1C, respectively, overlap with each other at a prescribed position on the intermediate transfer belt 10, accordingly. Similarly, magenta and black toner images (M and K toner images) are formed on the remaining image forming units 1M and 1K, respectively, and are secondarily transferred and superimposed on the intermediate transfer belt 10 at the prescribed position similarly as well. Hence, a full-color image is ultimately formed on the intermediate transfer belt 10.
When the above-described full-color image reaches a paper sheet targeted transfer device 9 acting as a secondary transfer device, the paper sheet 8 conveyed from the paper sheet feeding unit installed in the printer 100 in a direction as shown by arrow C in
Here, a main unit controller 200 controls operation of each of the other units installed in the printer 100 and one or more devices included in each of the other units.
Now, the main unit controller 200 is described in detail with reference to
That is,
The paper sheet position detector 207 optically detects a leading end of the paper sheet 8 sent by a pair of separable registration rollers (14) after it starts rotating. The temperature humidity sensor 208 acquires environmental information of an interior of the printer 100. When a black and white image (i.e., a monochrome image) is formed, the intermediate transfer belt contacting and separating clutch 211 switches a track of the intermediate transfer belt 10 from a previous track to another track by separating the intermediate transfer belt 10 from the photoconductive drums 2 of respectively component colors of Y, M, C other than black included in the image forming units 1.
Now, an exemplary characteristic feature of a sheet conveying device as one embodiment of the present invention is described herein below.
That is,
The sheet conveying device 300 is configured to convey multiple sheets of various sizes of a different length in the paper sheet conveyance direction. Hence, to convey the minimum size of a paper sheet, the pair of first separable conveyance rollers 15, the pair of second separable conveyance rollers 16, and the pair of third inseparable conveyance rollers 17 each placed upstream of the pair of separable registration rollers 14 is positioned at prescribed intervals shorter than the length of the paper sheet of the minimum size in the paper sheet conveyance direction. Further, to convey multiple sheets respectively having different sizes longer than the minimum size, these pairs of conveyance rollers 15 to 17 are correspondingly placed at prescribed various positions to be able to sandwich trailing end regions of paper sheets of the different sizes therebetween, respectively.
In such a paper sheet conveying path having the multiple pairs of conveyance rollers 15 to 17, to eliminate the earlier described conventional problem in that the paper sheet returns to the skew again when the skew of the trailing end region of the paper sheet is corrected by opening all of the multiple pairs of conveyance rollers as caused in the conventional configuration, at least one of these pairs of conveyance rollers 15 to 17 can sandwich the paper sheet therebetween to the contrary. Here, to correct skews of paper sheets of all sizes by excessively feeding for a predetermined period of time and bumping leading ends of the respective paper sheets against the gate 13, at least the pair of conveyance rollers for the paper sheet having the minimum size can sandwich the paper sheets of all sizes. However, since a distance between the pair of conveyance rollers for the paper sheet of the minimum size and the pair of registration rollers is short, restoring force generated in the paper sheet due to torsion of the paper sheet grows. As a result, the paper sheet sandwiched by the pair of separable registration rollers 14 is likely directed obliquely due to influence of strong restoring force generated in the paper sheet. Under such a condition, when the paper sheet is conveyed by the pair of registration rollers driven by a prescribed driving source, the paper sheet may be conveyed to the transfer section (i.e., the transfer device 9) with its skew.
In the sheet conveying device 300, the paper sheet is guided by a guide plate, such as a bottom plate, a ceiling plate, a side plate, etc., along the paper sheet conveyance path. Hence, when the skew of a leading end region of the paper sheet is corrected by the gate 13, the trailing end region of the paper sheet sometimes contacts the guide plate. In such a situation, if frictional force caused by contact resistance of a contact point between the paper sheet and the guide plate is weak enough, the skew of the trailing end region of the paper sheet is equivalently corrected as the portion of the paper sheet sandwiched by the pair of separable registration rollers 14 by releasing the trailing end region of the paper sheet from restriction of the multiple pairs of conveyance rollers as in the conventional system. By contrast, however, if the frictional force caused by the contact resistance is relatively great, the restoring force of the paper sheet caused by the torsion thereof is increased in accordance with rigidity of the paper sheet, and is strongly applied to the portion of the paper sheet sandwiched by the pair of separable registration rollers 14. As a result, the paper sheet sandwiched by the pair of separable registration rollers 14 is likely directed obliquely, and the paper sheet may be conveyed to the transfer section keeping the skew as the pair of separable registration rollers 14 rotates under such a condition.
Especially, when a long paper sheet having a long size in the paper sheet conveyance direction is utilized, a paper sheet portion located on the trailing end side of the portion sandwiched by the pair of separable registration rollers 14 is relatively long. Accordingly, either an area of the paper sheet that contacts the guide plate via an area surface thereof or the number of contact sections increases on the trailing end side of the paper sheet. As a result, since frictional force caused by contact resistance increases and restoring force caused by torsion of the long paper sheet is strongly applied to the portion of the paper sheet sandwiched by the pair of separable registration rollers 14, the long paper sheet is more likely conveyed in the horizontal rotated state toward the transfer section. Otherwise, even if the paper sheet on the trailing end side of the paper sheet is released from the above-described restriction as in the conventional system, the paper sheet remains contacting with the guide plate and accordingly the skew of the long paper sheet on the trailing end side thereof cannot be corrected. That is, when the pair of separable registration rollers 14 rotates under such a condition, the paper sheet 8 is conveyed toward the transfer section with its increasing skew. Here, according to below described various embodiments of the present invention, various operations are executed in a sheet conveying device to eliminate the above-described problems therefrom.
Now, correcting a skew of a paper sheet in the sheet conveying device according to one embodiment of the present invention is herein below described with reference to
Subsequently, as shown in
In view of this, as shown in
Subsequently, as shown in
That is, as shown in
Now, a preferable degree of the length L1 of the paper sheet conveyance path is herein below described with reference to
In view of this, about 350 mm and about 500 mm are used as the length L1 of the paper sheet conveyance path extended from the gate 13 to the pair of third inseparable conveyance rollers 17 to test whether or not the paper sheet returns to the skew once again. Here, the full length of the paper sheet 8 used in the experiment is about 700 mm in the longitudinal direction. As shown as a testing result in
Now, an exemplary modification of the sheet conveying device of this embodiment of the present invention is described herein below with reference to
As in the above described various embodiments, since the leading end of the paper sheet 8 is butted against the gate 13 as a corrector of correcting the skew of the paper sheet 8 and the paper sheet 8 is continuously conveyed for a predetermined period of time, the leading end of the paper sheet 8 can be aligned with the abutment face of the gate 13 thereby making a right angle with the paper sheet conveyance direction. However, the present invention is not limited to the above-described correcting system of correcting the skew of the paper sheet 8 by using the gate 13, and includes another system of correcting the skew of the paper sheet 8 by bumping a lateral end (i.e., a widthwise end) of the paper sheet against a side fence 500 as shown in
The above-described various embodiments are just few examples of the present invention and can respectively provide unique advantages as described herein below.
According to one aspect of the present invention, since the paper sheet is continuously sandwiched by the pair of conveyance rollers for a prescribed period, restoring force generated in the paper sheet in an oblique direction to the paper sheet conveyance direction is inhibited from traveling downstream of the portion of the paper sheet sandwiched by the pair of conveyance rollers even if frictional force is generated when either a surface of the paper sheet on the trailing end region of a portion sandwiched by the pair of conveyance rollers or the trailing end of the paper sheet contacts a guide plate, such as a bottom plate, a ceiling plate, a side plate, etc. At the same time, a conventional problem in that the leading end of the paper enters the skew once again when the restoring force is applied to the portion of the paper sheet sandwiched by the pair of registration rollers can be either suppressed or reduced. Further, when it passes through the portion sandwiched by the pair of conveyance rollers, the trailing end of the paper becomes free providing a free end, and the skew of the trailing end side of the paper is similarly corrected as the portion of the paper sheet sandwiched by the pair of the registration rollers. That is, according to one aspect of the present invention, a sheet conveying device includes a sheet skew corrector to correct a skew of a leading end of a sheet inclining from a sheet conveyance direction and a pair of registration rollers disposed upstream of the sheet skew corrector in the sheet conveyance direction. The pair of registration rollers freely contacts and separates from each other. The pair of registration rollers conveys the sheet downstream of the sheet skew corrector in the sheet conveyance direction when driven at a prescribed time. A pair of conveyance rollers is placed upstream of the pair of registration rollers in the sheet conveyance direction. The pair of conveyance rollers continuously sandwiches the sheet from when the sheet with the skew corrected by the sheet skew corrector is sandwiched by the pair of registration rollers to when a trailing end of the sheet passes between the pair of conveyance rollers.
According to another aspect of the present invention, the number of pairs of conveyance rollers having the separating mechanism can be more effectively minimized while reducing the cost of the sheet conveying device even if the long paper is utilized when compared with a conventional system that increasingly employs the number of pairs of conveyance rollers having the separating mechanism as a paper sheet size used in the system increases in a longitudinal direction. That is, in the above-described sheet conveying device, the pair of conveyance rollers is not connected to a separating mechanism that separates the pair of conveyance rollers from each other.
According to yet another aspect of the present invention, since it is found through an experiment that a leading end of a sheet with the skew corrected does not enter the skew once again if the pair of conveyance rollers is placed at a prescribed position on a sheet conveyance path separated from the sheet skew corrector by a sheet length of about 350 mm or more in a sheet conveyance direction, the pair of conveyance rollers of this embodiment of the present invention is placed at the position on a sheet conveyance path separated from the sheet skew corrector by the paper sheet length of about 350 mm or more in a sheet conveyance direction. With this, even if a portion of the paper sheet downstream of the pair of conveyance rollers contact a guide plate, a conventional problem, in which restoring force is caused by friction generated in the contact area in the oblique direction is applied to a portion of the paper sheet sandwiched by the pair of registration rollers and the leading end of the paper sheet accordingly enters a skew once again, can be either suppressed or reduced. That is, when compared with a situation in which the pair of conveyance rollers is placed at a prescribed position on a sheet conveyance path separated from the sheet skew corrector by a length less about 350 mm in a sheet conveyance direction, since an area of the paper sheet having the torsion thereon is wider, the restoring force of the paper sheet caused by the torsion thereof is widely distributed and the restoring force applied from the contact portion to the portion of the paper sheet sandwiched by the pair of registration rollers becomes weak. Hence, the paper sheet with the skew corrected can avoid returning to the sheet skew once again even if torsion occurs in the paper sheet during the sheet skew correction. That is, in the above-described sheet conveying device, the pair of conveyance rollers is placed at a prescribed position on a sheet conveyance path separated from the sheet skew corrector by a length of about 350 mm or more.
According to yet another aspect of the present invention, since a distance between the pair of conveyance rollers that sandwiches a trailing end region of the paper sheet and the pair of registration rollers is a relatively long, torsional area of the paper sheet increases, and accordingly the restoring force of the paper sheet caused by the torsion therein is widely distributed. As a result, the restoring force applied to the portion of the paper sheet sandwiched by the pair of registration rollers becomes weak, and accordingly the paper sheet with the skew corrected can avoid returning to the sheet skew once again. That is, in the above-described sheet conveying device, the distance on the sheet conveyance path between the pair of conveyance rollers and the sheet skew corrector ranges from about 470 mm to about 530 mm when a length of the sheet in the sheet conveyance direction is about 700 mm.
According to yet another aspect of the present invention, since a contact resistance caused when the paper sheet passes through a curved conveyance path is reduced, and restoring force of the paper sheet caused by the torsion of the paper sheet becomes relatively small, the paper sheet can avoid returning to the sheet skew once again. That is, in the above-described sheet conveying device, the pair of conveyance rollers is placed on a curved sheet conveyance path, the curved sheet conveyance path having a radius of curvature of about 80 mm or more.
According to yet another aspect of the present invention, since the paper sheet conveyance path is linear, contact resistance applied to the paper sheet during passing through the paper sheet conveyance path is almost neglected. As a result, the paper sheet can avoid returning to the sheet skew once again. That is, in the above-described sheet conveying device, the radius of curvature of the curved sheet conveyance path is infinity.
According to yet another aspect of the present invention, the portion of the paper sheet sandwiched by the pair of registration rollers is not directed obliquely and accordingly the paper sheet does not return to the sheet skew back again thereby resolving the conventional problem, and accordingly the paper sheet is not sent to the transfer unit in the skew. Hence, an image created by an image forming device is borne in an appropriate position in a sheet. That is, an image forming apparatus includes an image forming device to form an image on a sheet and the above-described sheet conveying device to convey the sheet toward the image forming device.
According to yet another aspect of the present invention, the paper sheet fed from a preprocessing machine is conveyed while inhibiting the paper sheet from returning to the sheet skew once again. Hence, an image created by an image forming device is borne in an appropriate position on a sheet again. That is, the image forming apparatus further includes a preprocessing unit 400 detachably attached to the image forming apparatus and having a pair of preprocess sheet conveyance rollers. The pair of preprocess sheet conveyance rollers continuously sandwiches a sheet conveyed from the preprocessing machine at least from when the skew of the sheet is corrected by the sheet skew corrector and the pair of registration rollers sandwiches the sheet therebetween to when a trailing end of the sheet passes between the pair of preprocess sheet conveyance rollers.
Numerous additional modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the present invention may be executed otherwise than as specifically described herein. For example, the sheet conveying device is not limited to the above-described various embodiments and modifications and may be altered as appropriate. Also, the image forming apparatus is not limited to the above-described various embodiments and modifications and may be altered as appropriate. Further, the method of correcting a skew of a sheet is not limited to the above-described various embodiments and may be altered as appropriate. For example, a step of the method of forming an image can be altered as appropriate.
Number | Date | Country | Kind |
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2014-241362 | Nov 2014 | JP | national |