Post-imaging operations for sheets of imaging media, such as from a printer, for instance, include aligning, stacking, and stapling sheets of media, for example.
In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific examples in which the disclosure may be practiced. It is to be understood that other examples may be utilized and structural or logical changes may be made without departing from the scope of the present disclosure. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present disclosure is defined by the appended claims. It is to be understood that features of the various examples described herein may be combined, in part or whole, with each other, unless specifically noted otherwise.
Upon discharge from an image forming apparatus, such as a printer, for example, media conveying systems may perform various post-imaging operations such as aligning, stacking, and stapling sheets of imaging media, for example. Aligning and stacking of sheets of media may be sometimes be referred to as “registration”, with media output systems sometimes being referred to as media registration systems.
In one example, media registration system 30 includes a translator 40 to rotate transport track 32 about a pivot 42 to a adjust a position of registration end 38 in a direction 35 lateral to transport direction 33 to provide registration or alignment of edges of sheets of media 34 in the lateral direction 35 at registration end 38 to form a media stack, such as for stapling operations, for example. In one example, lateral direction 35 is orthogonal to transport direction 33 (such as an x-direction in
In one example, translator 40 includes a driver 44 and a translation element 46 operatively coupled to transport track 32, where driver 44 drives translation element 46 to rotate transport track 32 about pivot 42. According to examples, driver 44 drives translation element 46 along a translation axis 48 extending in lateral direction 35 to rotate transport track 32 about pivot 42. In one example, driver 44 drives translation element 46 by a translation distance Xt to move registration end 38 of transport track 32 by a registration distance Xr in lateral direction 35.
According to examples, translation axis 48 is disposed at a location other than at registration end 38 of the transport track 32, such that translation axis 48 and registration end 38 are at different distances in transport direction 33 from pivot 42. In one example, as illustrated, translation axis 48 is at a first distance, y1, in transport direction 33 from pivot 42, and registration end 38 is at a second distance, y2, in transport direction 33 from pivot 42. With translation element 46 and registration end 38 at different distances in transport direction 33 from pivot 42, due to angular movement of transport track 32 when rotated about pivot 42, movement of translation element 46 by a translation distance, Xt, along translation axis 48 results in movement of registration end 38 by a registration distance Xr that is different from translation distance, Xt. In one example, translation distance, Xt, is proportional to registration distance, Xr, but is not a one-to-one relationship.
If not accounted for, the proportional relationship between Xt and Xr may result in misalignment between edges of sheets of media 34 in lateral direction 35 at registration end 38 of transport track 32, with the mismatch being greater the larger the difference between distances y1 and y2 and the greater the translation distance Xt. In one example, to compensate for such mismatch, in order to move registration end 38 of transport track 32 by a selected registration distance, Xr, driver 44 drives translation element 46 along translation axis 48 by a translation distance, Xt, equal to the selected registration distance, Xr, multiplied by an adjustment factor, Af (i.e., Xt=Af·Xr). In one example, adjustment factor, Af, is equal to a ratio of the first distance, y1, to the second distance, y2 (i.e., Af=y1/y2), such that Xt=(y1/y2)·Xr.
By driving translation element 46 along translation axis 48 by a translation distance, Xt, that is equal to product of the selected registration distance, Xr, and the adjustment factor, Af, translator 40 accounts for the mismatch in travel distances between Xt and Xr resulting from the angular motion of transport track 32 about pivot 42 so that media registration system 30 is able to accurately align edges of sheets of print media 34 in lateral direction 35.
In one example, media registration system 30 includes a y-registration element, such as y-registration elements 54a and 54b, at registration end 38. As described in greater detail below, y-registration elements 54a and 54b provide surfaces which contact a leading edges of sheets of imaging media so as to provide registration (i.e., alignment) in transport direction 33 of edges of sheets of imaging media 34, such as leading edges of the sheets of media 34, as they are transported along puller tracks 50a and 50b.
In one example, puller clamps 52a and 52b each include a nip to secure sheet of imaging media 34 thereto. In one example, each nip is formed by a pair of biased rollers (not illustrated). According to such example, as puller clamps 52a and 52b pull sheet 34 along tracks 50a and 50b, a leading edge of sheet 34 contacts and is registered in transport direction 33 by y-registration elements 54a and 54b. As the leading edge of sheet 34 contacts and is registered by y-registration elements 54a and 54b, sheet 34 in prevented from movement in transport direction 33. As puller clamps 52a and 52b continue to move along tracks 50a and 50b in transport direction 33, sheet 34 is “pushed” from the nips of puller clamps 52a and 52b by y-registration elements 54a and 54b. Upon release from puller clamps 52a and 52b, sheet 34 is maintained on a support surface below puller tracks 50a and 50b, such as an output tray (not illustrated), for example. In this regard, it is noted that, in one example, when transporting a sheet of imaging media 34, puller clamps 52a and 52b move in transport direction 33 along a lower portion of puller tracks 50a and 50b, and after releasing sheet 34 return to intake end 36 along an upper portion of puller tracks 50a and 50b in a direction opposite to transport direction 33.
In one example, translation element 46 is operatively coupled to puller tracks 50a and 50b and is driven along translation axis 48 to respectively rotate puller tracks 50a and 50b about corresponding pivots 42a and 42b so as to provide alignment of sheets of imaging media 34 in lateral direction 35 at registration end 38. In one example, driver 44 may be a motor 45 (e.g., a DC brushed motor) and translation element 46 may implemented as a rack and pinion system, having a rack 47 operatively coupled to puller tracks 50a and 50b, and a pinion 49 driven by motor 45 to drive the rack 47 back and forth along translation axis 48 to respectively rotate puller tracks 50a and 50b about pivots 42a and 42b. It is noted that in other examples, translator 40 may be implemented using other types of actuating systems, including linear actuators, for example.
In one example, translator 40 (which may also sometimes be referred to as an x-registration system) further includes a controller 56 and a sensor 58. As described in greater detail below, according to examples, as puller clamps 52a and 52b pull sheets of imaging media 34 along puller tracks 50a and 50b, sensor 58 measures a position of sheets of imaging media 34 in lateral direction 35. Based on the measured lateral position and employing the adjustment factor, Af, described above, for each sheet of imaging media 34, controller 56, via motor 45 (e.g., a DC brushed motor) and translation element 46 (e.g., rack and pinion gears 47/49), rotates puller tracks 50a and 50b about pivots 42a and 42b to register edges of sheets of imaging media 34 in lateral direction 35.
In one example, as illustrated, translator 40 moves puller tracks 50a and 50b at registration end 38 over a range of registration distances Xr in the positive x-direction, where such range extends from a home position, where Xr is zero (such as along the y-axis, for example), to a maximum registration distance Xr in the positive x-direction (which is determined by a maximum translation distance, Xt, of translation element 46). It is noted that puller tracks 50a and 50b are illustrated as being at the home position in
With reference to
In one example, as illustrated, after measuring the lateral position of rear edge 62 of sheet 34-1, translator 40 rotates puller tracks 50a and 50b about corresponding pivot points 42a and 42b by moving translation element 46 by a translation distance Xt1 (as illustrated by the dashed lines) so that the rear edge 62 is shifted in the positive x-direction by a selected offset distance, Xoff, when the first sheet of imaging media 34-1 reaches y-registration elements 54a and 54b at registration end 38 and is released from puller clamps 52a and 52b. According to one example, in view of the above, the translation distance of translation element 46 for the first sheet of the print job, Xt1, is equal to a product of the adjustment factor, Af, and the selected offset distance, Xoff (i.e., Xt1=Af·Xoff). In one example, pivot points 42a and 42b are positioned on a same axis lateral to transport direction 33, such as along the x-axis as illustrated by
With reference to
With reference to
In this fashion, the lateral edges of all sheets of imaging media 34 of the print job are aligned (registered) at a distance of X1+Xoff from the y-axis (reference position). Additionally, the leading edges 60 of all sheets 34 of the print job are aligned in the y-direction by y-alignment features 54a and 54b. With all sheets of the print job aligned in both the x- and y-directions, additional operations can be performed, such as stapling, for example.
At 104, with reference to
In one example, at 106, method 100 further includes measuring a position of a rear edge of the first sheet in the lateral direction from a reference with the transport track at the home position prior to driving the translation element along the translation axis, such as measuring a rear edge 62 of sheet 34-1, as illustrated by the distance X1 in
At 108, for each subsequent sheet of the series, method 100 includes measuring a position of a rear edge of the subsequent sheet from the reference, such as measuring the distance Xn to the rear edge 62 of sheet 34-n, as illustrated by
At 110, for each subsequent sheet, method 100 includes driving the translation element 46 operatively coupled to the transport track by a translation distance, Xt, along the translation axis 48 to rotate the transport track about the pivot and move the registration end in the lateral direction from the home position, the translation distance equal to a product of the ratio of the first distance to the second distance and a sum of the offset distance and a difference between the measured positions of the first sheet and the subsequent sheet in the lateral direction, i.e., Xt=(y1/y2)·(Xoff+(X1−Xn), so as to align the rear edges of all sheets of the series of imaging media sheets align in the lateral direction at the registration end, such as illustrated by
Although specific examples have been illustrated and described herein, a variety of alternate and/or equivalent implementations may be substituted for the specific examples shown and described without departing from the scope of the present disclosure. This application is intended to cover any adaptations or variations of the specific examples discussed herein. Therefore, it is intended that this disclosure be limited only by the claims and the equivalents thereof.
Number | Name | Date | Kind |
---|---|---|---|
4244461 | Fischer | Jan 1981 | A |
6851250 | Whitby | Feb 2005 | B2 |
7472905 | Inoue | Jan 2009 | B2 |
8454012 | Obuchi et al. | Jun 2013 | B2 |
8817277 | Matsushima | Aug 2014 | B2 |
8882106 | Maenishi et al. | Nov 2014 | B2 |
8944432 | Karikusa | Feb 2015 | B2 |
9809408 | Maenishi et al. | Nov 2017 | B2 |
20050035536 | Suga | Feb 2005 | A1 |
20180265318 | Langhuber | Sep 2018 | A1 |
Number | Date | Country |
---|---|---|
2017099731 | Jun 2017 | WO |
Number | Date | Country | |
---|---|---|---|
20200130974 A1 | Apr 2020 | US |