Liquid electrophotographic (LEP) printing uses a special kind of ink to form images on paper and other print media. An LEP printing process involves placing an electrostatic pattern of the desired printed image on a photoconductor and developing the image by presenting a thin layer of LEP ink to the charged photoconductor. Charged particles in the ink adhere to the pattern of the desired image on the photoconductor. The ink image is transferred from the photoconductor to an intermediate transfer member and then to the print media as the print media passes through a nip between an intermediate transfer member and an impression cylinder.
The same part numbers designate the same or similar parts throughout the figures. The figures are not necessarily to scale.
In LEP printing, as in many other printing processes, it is desirable to accurately align the paper or other print media to the printing unit to produce good quality images. Sheet media may be aligned for printing by driving the leading edge of the sheet into a blocker until the sheet buckles. The blocker is oriented across the media path in the desired alignment. Any misalignment across the leading edge of the sheet, commonly referred to as “skew”, is removed as the sheet is driven into the blocker. That is to say, the sheet is “deskewed” by driving it into the blocker. Buckling signals that the sheet has engaged the blocker across the full width of the leading edge for proper alignment. The blocker is them removed from the media path so the sheet can proceed to the printing unit.
Buckle deskew can damage the print media. It has been discovered that shaping the print media leading into the blocker helps reduce the risk of damage during deskew. In one example, a sheet media alignment system includes a guide defining a curved media path and a blocker to block the curved media path at the downstream part of the guide. A drive roller upstream from the curved media path drives a media sheet into the guide along the curved media path and into the blocker. The drive roller is spaced from the upstream part of the guide a distance sufficient to enable the sheet to buckle between the drive roller and the guide as the sheet is driven into the blocker. The leading part of the sheet, which conforms to the curve of the guide, is better able to absorb the shock of hitting the blocker and withstand the driving forces applied until the sheet buckles. Although the exact mechanism for increased toughness is not certain, it is believed the curved shape and the constraints of the guide together stiffen the sheet laterally across the media path to better resist wrinkling and increase the resilience of the sheet lengthwise along the media path to better absorb the shock of impact. The increased toughness of the shaped sheet lowers the risk of damage and expands the degree of skew that can be safely corrected. For example, testing indicates that 40 mm of skew can be corrected in paper sheets as light as 45 gsm using the new technique compared to 4 mm for a straight sheet.
This and other examples described below and shown in the figures illustrate but do not limit the scope of the patent, which is defined in the Claims following this Description.
As used in this document “and/or” means one or more of the connected things and “side” means the top or bottom of a sheet when referring to a media sheet.
The group of drive rollers 24 is spaced from the upstream part of guide 12 a distance sufficient to enable sheet 20 to buckle between rollers 24 and guide 12 as leading edge 18 is driven into blocker 16, as shown in
The desired spacing may vary depending on the stiffness of the media sheets and the characteristics of the curved media path. For 45 gsm-90 gsm paper, for example, testing indicates a circular media path with a central angle θ of at least 45° and a radius R less than 200 mm should be adequate to achieve sufficient strength in each sheet 20 to absorb the shock of hitting the blocker and withstand the driving forces without damaging the sheet. (Radius R is called out in
The liquid ink image is transferred from photoconductor 34 to an intermediate transfer member (ITM) 42 and then from ITM 42 to a media sheet 20 as it passes between ITM 42 and an impression cylinder 44. For some LEP printing processes, the images for each color plane are applied sequentially to a sheet 20 that goes around and around on cylinder 44 until all of the color plane images are transferred to the sheet. A lamp or other suitable discharging device 46 removes residual charge from photoconductor 34 and ink residue is removed at a cleaning station 48 in preparation for developing the next ink image.
Printer 30 also includes a media transport system 50 that includes a sheet alignment system 12 and a rotary sheet transfer mechanism 52 to transfer sheets from alignment system 12 to impression cylinder 44. In this example, transfer mechanism 52 is configured with a gripper 54 at the end of an arm 56. Alignment system 12 includes a drive roller 24 that rotates against an idler roller 58 to apply a driving force to sheet 20, and a guide 12 that defines a curved media path 14. The end of rotary arm 56 forms the blocker 16 in sheet alignment system 12. In this example, guide 12 is configured as a channel to constrain both the top side 22 and bottom side 60 of sheet 20 along path 14. Although the height of the media path through a channel 12 may vary depending on the thickness of media sheet 20, a channel 2 m to 6 mm will pass paper sheets up to 600 gsm with sufficient constraint to enable the desired deskew without additional risk of damage to the sheet.
The examples shown in the figures and described above illustrate but do not limit the patent, which is defined in the following Claims.
“A”, “an” and “the” used in the claims means at least one.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/059551 | 4/21/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/192671 | 10/25/2018 | WO | A |
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Number | Date | Country | |
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20200247632 A1 | Aug 2020 | US |