Media may have a tendency to curl. This may complicate a proper output or stacking of printed media.
For the purpose of illustration, certain examples constructed in accordance with this disclosure will now be described with reference to the accompanying drawings, in which:
In the following detailed description, reference is made to the accompanying drawings. The examples in the description and drawings should be considered illustrative and are not intended as limiting to the specific example or element described. Multiple examples of printers or media output guide assemblies can be derived from the following description and drawings through modification, combination or variation of the different elements.
The imaging arrangement 4 can be an electrophotographic or inkjet imaging arrangement. Examples of the imaging material are liquid or dry toner or ink. In one example the imaging arrangement 4 includes a receiving bay fixed to the printer 1 to receive an exchangeable cartridge that holds the imaging material. In other examples the imaging arrangement 4 includes a printhead assembly that is fixed to the printer 1, wherein the printhead assembly can be a scanning or a page wide array printhead assembly.
In one example the printer 1 includes a media output tray 7. The media output tray 7 includes a media support surface 8 to support the media 3 or media stack.
The printer 1 includes a media output guide assembly 5 to curve the media 3 downstream of the print zone 2. A media output direction M runs from right to left in
In a further example explanation, just after the print zone 2 the recently deposited imaging material may be wet, cooling down, drying, curing, fusing or undergoing some kind of temperature or state change. As a result thereof the media 3 may tend to curl. In again further examples certain media types, such as for example relatively thin paper or short grained paper, are extra sensitive to curl, especially in combination with the imaging material being wet, cooling down, drying, curing, fusing or undergoing some kind of temperature or state change. Intentionally curving the media 3 at output may help in these and other example situations. For example, curving the media 3 after the print zone 2 can inhibit curling of the media 3 over a direction perpendicular to the media output direction M. For example, the curving of the media 3 after the print zone 2 may stiffen the media 3 at output.
In the example of
In the example illustration, the first guide 10 contacts a first face of the printed media, while the second guide 111 contacts the opposite face of the printed media 103. The second guide 111 presses into the media 103 to bow the middle portion 103B towards the media support surface 108, while the first guides 110 hold the side portions 103C away from the media stack surface 108 so that the U-shaped cross section is formed. The point where the second guide 111 is to engage the media 3 is closer to the media support surface 108 than the point where the first guide 110 is to engage the media 3. As illustrated, in operation, the U-shape in the media 103 may span between the first guides 110 and its width Uw may span more than half of a width W of a print zone and/or media output tray support surface. In a further example the distance GD between the inner second guides 111 is more than half of the width W of the print zone and/or media output tray support surface. For example the formed “belly” of the U-shaped media is relatively wide.
In other examples the media output guide assembly 105 may include other numbers of guides 110, 111, such as for example only one second guide 111 to push the middle portion 103C towards the media support surface 108.
The media output guide assembly 205 includes two top guides 211 to engage a top face of printed media. In an example the top face is the image face of the printed media. In case of duplex printing the image face is the face that is being printed, and/or the face with the most recently printed image. In one example the top guide 211 includes a low friction element to roll or slide over the image face during printing. For example the top guide 211 includes low friction wheel 216 such as a star wheel to roll over the image face during printing.
The media output guide assembly 205 includes two bottom guides 210 to engage a bottom face of printed media. The bottom guides 210 are arranged next to the top guides 211 on the outside of the top guides 211. In an example the bottom face is the face of the media that is not being printed, or, in case of duplex printing, the face that was first printed. For example, in case of duplex printing the image on the bottom face may have already cooled down, cured, dried, fused, etc., so that there is less risk that the bottom guides 210 engage wetted imaging material. In one example the bottom guides 210 include a slide element such as a ski-like structure so that during media output the bottom face of the media slides over the bottom guide 210.
The guides 210, 211 are arranged in pairs 212 wherein each pair 212 contains a bottom guide 210 and a top guide 211. The distance between a bottom guide 210 and a top guide 211 within a pair 212 is smaller than the distance between the pairs 212. The top guides 211 are disposed on the inside so that the distance between the top guides 211 is smaller than the distance between the bottom guides 212. Consequently, in this example, the distance between the pairs 212 is determined by the distance between the top guides 211.
A point of the top guides 211 that is to engage the media is lower than a point of the bottom guides 210 that is to engage the media. This is perhaps best viewable in
In one example that is perhaps best understood with reference to
In an example the retractable top guide 211 includes a retractable arm 221. In a further example, the arm 221 includes a rack 223 that is engaged by a pinion 225 or gear that in turn is drivable by a motor 227 (
For example, the arm 221 is retractable and extendable over a straight line L over its own longitudinal axis. For example the top guide 211 includes a pivoting arm 231 to support and guide the retractable arm 221 during retraction and extension of the top guide 211. One end of the pivoting arm 231 pivots with respect to the retractable arm 221 and another end is mounted to a printer part in a pivoting manner and has a fixed location. In an example, the pivoting arm 231 is telescopic. For example the arm 221 is to retract substantially upwards and extend substantially downwards.
In an example the retractable bottom guide 210 also includes a retractable arm 222. In a further example, the bottom arm 222 includes a rack 224 that is engaged by a pinion 226 or gear that in turn is drivable by a motor 228. For example, further transmission elements 230 are to transmit motor axle rotation to the pinion 226 and, finally, to the bottom guide arm 222. The further transmission elements may include gears and axles. Both two bottom guides 222 may be drivable by the same motor 228 through said transmission elements 230.
For example, the bottom arm 222 is retractable and extendable over a straight line Lb over its own longitudinal axis. For example the bottom arm 22 is extendable away from the print zone and retractable towards and partly under the print zone.
The printer 201 includes a drive circuit 240 to instruct the drive of the bottom and top guide 210, 211. In the discussed example such guide drive includes motors 227, 228. For example the guide drive includes open loop DC motors. For example, the drive circuit 240 is to instruct the guide drive to extend and retract the guides 210, 211. For example the drive circuit 240 is to instruct the guide drive to extend and retract the guides 210, 211 before a trailing media edge passes and/or before the media is ejected. For example the drive circuit 240 is to instruct the media output rollers 215 to eject the media just after the guides 210, 211 are ejected.
In this example the media has a grain direction perpendicular to the media advance direction during printing. Therefore the fibers may offer relatively little resistance to curling and the short grained media may have a relatively strong tendency to curl at ejection, especially when the image has not fully dried, cured, fused or cooled down. In one example the method includes, while the image has not fully dried, cured, fused or cooled down, curving a middle portion of the media downwards so that a transverse cross section of the media includes a U shape (block 420). In one example this allows the short grain media to be stiffened and may prevent curling. The method includes a disengagement of the media by guides before a trailing edge has passed these guides (block 430). The method includes ejecting the media after the guides have disengaged the media (block 440).
While in this description directional indications including “bottom”, “top”, “downwards”, and “upwards” are used, these can be interpreted as relative. For example the examples mentioned with respect to
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2013/052523 | 7/29/2013 | WO | 00 |