The present invention relates to printers. In particular the present invention relates to an apparatus for adjusting the printhead-to-media spacing within a printer to allow for printing on thick media.
Inkjet printers operate by expelling droplets of ink onto the media from the printhead, which is the part of the printer that actually prints on a medium, and which generally has a two dimensional array of very small nozzles substantially parallel to the media. The printhead generally does not extend across the width of the printer; instead the printhead is generally mounted on a carriage, which slides sideways across the printer on a carriage rod and an anti-rotation rail (which prevents rotation of the carriage about the carriage rod) that extend across the width of the printer. Therefore, the printhead can print to the width of the media. The media is generally advanced perpendicularly to the dimension in which the printhead carrying carriage slides (i.e. advanced along the length of the media) so that substantially the whole of the media can be printed to.
When the printhead is printing to the media, the further the droplets expelled from the printhead must travel, the lower the resolution achieved in the resulting printout due to lateral movement of the droplets between the printhead and the media. However, if the printhead is brought too close to the media, any warping of the media when the droplets land and temporarily dampen the media could cause the media to come into contact with the printhead, which can lead to smudging of the printed media or even clogging of the printhead.
In order to optimise the so-called printhead-to-media spacing, the printhead must be sufficiently close to the medium that it will print to that medium without loss of resolution, and sufficiently far away from the media to avoid the media warping and touching the printhead. Therefore, there is generally an optimal printhead-to-media spacing for a printhead.
In a conventional inkjet printer, the printhead-to-media spacing is generally set so that the printing is optimised for plain paper as the medium to be printed on, as this is the most often used medium. However, if an envelope, or cardboard, is to be printed on, the extra thickness of the medium will make the printhead-to-media spacing too small, leading to problems outlined above. Additionally, if the printhead-to-media spacing is optimised for envelopes, cardboard or other such thick media then, when printing on thin media such as paper, the printhead-to-media spacing will be too large, leading to other associated problems mentioned above.
Briefly, the invention provides an apparatus for adjusting the printhead-to-media spacing in a printer having a printhead carrying carriage, which is rockable relative to an elongate carriage rod in the printer to effect a change in such spacing. The apparatus includes an anti-rotation rail having a primary axis. The anti-rotation rail is configured to have the printhead carrying carriage mounted thereon to be rotatable about the primary axis. A carriage guiding block is provided, configured to be mountable on the carriage rod and configured to have the printhead carrying carriage mounted thereon. An actuator is also provided, mounted on the carriage guiding block. The actuator is movable between a spacing position in which the actuator is arranged to provide a first predetermined separation between the carriage guiding block and the printhead carrying carriage, to provide a first printhead-to-media spacing value, and a retracted position in which the actuator is arranged to provide a second separation between the carriage guiding block and the carriage, to provide a second printhead-to-media spacing value.
Other aspects and advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
Embodiments of the invention will now be described, purely by way of example, with reference to the accompanying drawings, in which:
a shows a detail of an apparatus of an embodiment of the invention;
b shows a detail of the apparatus shown in
a shows part of the detail shown in
b shows the part of the detail shown in
An embodiment of the invention as shown in
Referring again to
Again referring to
As shown in
In an embodiment, the printhead carrying carriage 160 is arranged such that a printhead 140 carried by the printhead carrying carriage 160 is disposed on a first side of the elongate axis of the carriage rod 120, the first side being the side distal to the anti-rotation rail 130. In this way, where the printhead carrying carriage 160 rotates about the anti-rotation rail 130 when the printhead carrying carriage 160 to carriage rod 120 separation is adjusted, a printhead 140 mounted on the printhead carrying carriage 160 is on the opposite side of the carriage rod 120, when looking along the elongate axis of the rod 120, to the anti-rotation rail 130. Such arrangement makes the radius of the rotation of the printhead 140 about the anti-rotation rail 130 as large as possible.
In many cases, the printhead 140 is a two dimensional array of inkjets, and this two-dimensional array should be kept at substantially the same attitude, (in many cases parallel to the medium to be printed on), due to the optimal distance between each inkjet of the printhead 140 and the medium. The large radius makes the relative difference in radius between the inkjets closest to and furthest away from the carriage rod 120 small. The difference in inkjet to media separation between the different parts of the printhead 140 between different rotations of the printhead carrying carriage 160 is therefore reduced, and the printhead 140 is maintained close to parallel with the medium to be printed on, when in both the first and second positions. This maintenance of the printhead 140 close to parallel with the media reduces adverse effects of one part of the printhead 140 being too close to the medium, while another part of the printhead 140 is simultaneously too far away, during printing.
In the embodiments described herein, the actuator 170 is mounted on the carriage guiding block 150. However, it will be seen that an actuator could be mounted on printhead carrying carriage 160 itself instead of the carriage guiding block and work in the same manner.
Additionally, in the embodiments described herein, the printhead carrying carriage 160 is able to slide along the length of the carriage rod 120. However, the invention could also be applied in a printer in which the printhead carrying carriage did not slide along the carriage rod, and the printhead was available to print to the whole width (and/or length) of a medium placed in the printer without relative transverse movement of the two.
a shows a detail of a carriage unit 210 of an embodiment of the invention corresponding to that shown in
In an embodiment, the actuator 270 includes a cam rod 272 rotatably mounted on the carriage guiding block 250. The cam rod 272 has in the present embodiment, two excentric cams 274 mounted on it, each having a single lobe, or portion of greater radius, which are held against movement along the cam rod 272 by retainers 276.
b shows an embodiment corresponding to that of
The carriage guiding block 250 also has an enclosing region 254, which encloses the carriage rod 220 sufficiently to prevent the carriage guiding block 250 from being lifted off the carriage rod 220. Part of the enclosing region 254 abuts the carriage rod 220 to support the carriage guiding block 250 on the carriage rod 220, as described below.
Biasing members, in the form of springs 280 are also provided in this embodiment. One end of each spring 280 is mounted to the cam rod 272. The other end of each spring 280 is mounted on the printhead carrying carriage 260. The springs 280 bias the relative separation of the carriage guiding block 250 and printhead carrying carriage 260 to a minimum. When the actuator 270 is in the retracted position, this biasing pulls the carriage guiding block 250 upwards. The enclosing region is slightly non-circular, being stretched in the vertical direction. Therefore, the carriage rod 220 abuts the inside of the enclosing region 254 on a bearing 255 on a lower region of the inside of the enclosing region. The bearing 255 does not extend all the way along the enclosing region 254 along the carriage rod 220, but provides point contact at an end of the carriage guiding block 250. A second bearing, not shown, corresponding in position and function to the bearing 255, is provided at the other end of the carriage block 250. The bearings 255 are simply plastic bushes, designed to allow the carriage guiding block 250 to slide along.
When the actuator 270 is in the retracted position, as shown in
The bearings 256 are point bearings of the same type as bearing 255, and a corresponding pair of bearings is also provided at the other end of the carriage guiding block 250. Once the carriage guiding block 250 abuts the further bearings 256, further rotation of the actuator 270 causes separation of the carriage guiding block 250 and printhead carrying carriage 260. Once the actuator 270 is in the spacing position, the carriage guiding block 250 and printhead carrying carriage 260 are separated and the spring 280 is deformed by an amount Δ, as one end is connected to the printhead carrying carriage 260, and the other abuts the cam 272. In the present embodiment, the difference in radius of the lobe of the cam 274 to that of the rest of the cam 274 corresponds to the difference between the spacing position and retracted position.
a and 3b show one end of a carriage rod 320 and a carriage guiding block 350 of an embodiment corresponding to that shown in
When the locating bar 352 is inserted into the orifice, lateral movement between the carriage and carriage guiding block 350 (movement of the printhead carrying carriage relative to the locating bar 352 in any direction other than along the elongate axis) is substantially prevented. The only movement between the carriage guiding block 350 and printhead carrying carriage is therefore along the elongate axis of the locating bar 352. Therefore, when the printhead carrying carriage is mounted on the carriage guiding block 350, the relative separation of the carriage guiding block 350 and printhead carrying carriage can be altered by rotating cam rod 372 and causing the cam 374 to rotate as shown in
However, the printhead carrying carriage and carriage guiding block 350 are restrained from rotating relative to each other, and are restrained from moving relative to one another along the axis of the carriage rod 320. When the printhead carrying carriage is mounted on the anti-rotation rail 330, the carriage guiding block 350 cannot rotate about the printhead carrying carriage. Therefore, the carriage guiding block 350 cannot rotate about the carriage rod 320, and the carriage unit 310 is kept from rotating. Additionally, the carriage guiding block 350 and the printhead carrying carriage will move together along the carriage rod 320.
A cam rod 472 extends in a direction substantially parallel to the elongate direction of the enclosing region 454 and extends beyond the ends of the carriage guiding block 450. As can be seen in
Two springs 480 are provided, as described in relation to
A handle 490 is provided on one end of the cam rod 472. The handle 490 allows manual rotation of the cam rod 472, leading to manual engagement of the cams 474 to move the actuator 470 between the spacing and retracted positions, thereby to change the printhead-to-media spacing from a first to a second value, as described above.
The apparatus of the present invention has been described above purely by way of example, and modifications will present themselves to the person skilled in the art and are within the scope and spirit of the invention, which is not limited to the above example, but also resides in any individual features and any combinations thereof.