A printer is used to print a target pattern onto a media sheet, such as a paper sheet, transparency sheet, and so forth. A printed media sheet can be output from the printer to an output tray or other receiving structure for user pickup.
Some examples are described with respect to the following figures:
A printer has an output port through which a printed media sheet (e.g. a paper sheet, a transparency sheet, etc.) is output. With some printers, the output port can be provided at the front side of the printer to allow for convenient pickup of the printed media sheet by a user. In other examples, the output port of a printer can be provided at other locations of the printer.
Some printers are used in production environments that generate a relatively large number of printed media sheets. It may be desirable to provide the printed media sheets to a media stacker, where the printed media sheets can be held. Holding the printed media sheets in the media stacker allows for a printing operation to proceed without involving manual handling of each printed media sheet by a user as the printed media sheet is output from a printer. A media stacker has the ability to collect printed media sheets from the printer and to stack a certain quantity of the printed media sheets. At some point, a user can collect the stack of media sheets together, such that the user does not have to handle each media sheet individually as the media sheets are being printed.
In some examples, media stackers can have relatively large footprints. For example, a media stacker can be attached to the front side of the printer where the output port is located. Thus, in addition to the existing footprint of the printer, the footprint of the media stacker is added to the overall system that includes the printer and the external media stacker. An external media stacker that adds to the footprint of the printer can consume valuable real estate space of an enterprise, particularly in situations where the enterprise uses multiple printers in a defined amount of space. Also, in some examples, a media stacker may be located at a location that makes user tasks more difficult (such as loading new media sheets or a new media roll, performing a scan with a scanner at the printer, accessing an internal portion of the printer to address a media sheet jam, and so forth). In such examples, the media stacker may have to be removed or taken apart to allow the user to perform the foregoing user tasks, which is time-consuming and inconvenient.
In accordance with some implementations, a media stacker is provided that can be arranged to fit within a footprint of a printer. A “footprint” of a printer refers to an area projected onto a ground surface that is occupied by the printer. A media stacker that fits within the footprint of the printer refers to a media stacker whose size does not extend beyond the footprint once the media stacker is attached to the printer for use with the printer. In other implementations, a media stacker can extend beyond a footprint of a printer, but the portion of the media stacker that extends beyond the printer's footprint occupies less than some predefined amount (e.g. less than 10%, less than 20%, or less than some other percentage) of the printer's footprint. Although reference is made to a media stacker used with a printer in the discussion herein, it is noted that a media stacker according to some implementations can be used with other types of systems that can output media sheets
As depicted in
The media stacker 104 is attached to the printer 102 using an attachment mechanism 112 (e.g. a latch or other type of attachment mechanism). A cross-sectional view of the media stacker 104 is shown in
A media support tray 206 (for holding printed media sheets) extends into the drawer 202. The media tray 206 has a curved front portion 208 at a side of the media tray 206 that first receives a printed media sheet. The curved portion 208 is curved downwardly in the view of
The upper guide structure 210 is provided above and opposes the media tray 206. The guide structure 210 has a curved front portion 212 that is curved in a direction that is opposite the curvature of the curved portion 206. The combination of the curved portions 206 and 212 define a receptacle into which a media sheet 211 can be guided for entry into the inner chamber 204 of the drawer 202.
The media stacker 104 includes a moving element 214 that is used to engage the media sheet 211 as the media sheet 211 is output from the printer 102 (
In some implementations, the moving element 214 is a D-shape roller, which is a rotatable structure that has a circular portion 216 and a planar (or non-circular) portion 218. The circular portion 216 has an outer profile that generally follows the profile of a circle. The planar portion 218 has a generally planar surface. In other implementations, rather than a planar portion, the D-shape roller 214 can have a portion with a different non-circular shape. Generally, the D-shape roller 214 is able to engage the media sheet 211 using the circular portion 216, but is disengaged from the media sheet 211 when the planar portion 218 faces the media sheet 211.
In examples according to
In other examples, instead of using three idle rollers 220, 222, and 223 along a particular axis as shown in
The rollers 220, 222, and 214 (223) are provided through corresponding openings 224, 226, and 228 in the guide structure 210. As a media sheet is guided by the D-shape roller 214 into the drawer 202, the media sheet 210 is first engaged by the idle roller 222, and then later by the idle roller 220 as the media sheet 210 is further slid into the drawer 202, until the media sheet 210 reaches its target position inside the drawer 202.
The media tray 206 is biased towards the rollers 220, 222, and 214 (223). The biasing can be provided by tray springs 230, which are attached to the lower support housing portion 203 and extend vertically upwardly towards the media tray 206. Initially, when no media sheets are received in the drawer 202, the media tray 206 is biased by the springs 230 to its uppermost position. However, as media sheets are received into the drawer 202, as shown in
As the leading edge 404 of the circular portion 216 of the D-shape roller 214 engages the new media sheet 402, further clockwise rotation of the D-shape roller 214 causes the new media sheet 402 to be guided further into the drawer 202, as shown in
At this point, when the new media sheet 402 has reached its target position (the leading edge of the new media sheet 402 engaged to the stop 213), the D-shape roller 214 has rotated to a position that the circular portion 216 is no longer engaged to the new media sheet 402, since the planar portion 218 of the D-shape roller 214 now faces the new media sheet 402.
The idle rollers 220, 222, and 223 move freely while the media sheet 402 is moving. In addition, provision of the idle rollers 220, 222, and 223 can avoid buckling of the moving media sheet 402 and the stack 250 of media sheets due to compression forces generated by the D-shape roller 214 as the D-shape roller 214 pushes the new media sheet 402 into the drawer 202.
In the foregoing description, numerous details are set forth to provide an understanding of the subject disclosed herein. However, implementations may be practiced without some or all of these details. Other implementations may include modifications and variations from the details discussed above. It is intended that the appended claims cover such modifications and variations.
This is a continuation of U.S. application Ser. No. 14/373,222, filed Jul. 18, 2014, which is a national stage application under 35 U.S.C. § 371 of PCT/US2012/022624, filed Jan. 26, 2012, which are both hereby incorporated by reference in their entirety.
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Number | Date | Country | |
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20160340142 A1 | Nov 2016 | US |
Number | Date | Country | |
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Parent | 14373222 | US | |
Child | 15228252 | US |