This invention relates to cleaning debris from orifices in an ink jet printhead nozzle plate. In particular, this invention relates to cleaning a vertically oriented nozzle plate.
Many different types of digitally controlled printing systems of ink jet printing apparatus are presently being used. These ink jet printers use a variety of actuation mechanisms, a variety of marking materials, and a variety of recording media. For home applications, digital ink jet printing apparatus is often the printing system of choice because low hardware cost makes the printer widely affordable. Another application for digital ink jet printing uses large format printers. These large format printers are expected to provide low cost copies with an ever improving quality. Ink jet printing technology is the first choice in today's art. Thus, there is a need for improved ways to make digitally controlled graphic arts media, such as billboards, large displays, and home photos, for example, so that quality color images may be made at a high-speed and low cost, using standard or special paper.
Ink jet printing has become recognized as a prominent contender in the digitally controlled, electronic printing arena because of its non impact, low-noise characteristics, its use of papers from plain paper to specialized high gloss papers and its avoidance of toner transfers and fixing. Ink jet printing mechanisms can be categorized as either continuous ink jet or droplet on demand ink jet.
Continuous ink jet printing generally involves using electric charge to selectively direct a stream of ink droplets. On demand type ink jet printers selectively produce individual ink droplets at each of many ink jet orifices. A typical consumer type printer includes approximately 30 to 200 orifices on the nozzle plate. At every orifice, a pressurization actuator is used to produce the ink jet droplet. Typical on demand ink jet printers use one of two types of actuators to produce the ink jet droplet. The two types of actuators are heat and piezo materials. With a heat actuator, a heater at a convenient location heats ink and a quantity of the ink will phase change into a gaseous steam bubble and raise the internal ink pressure sufficiently for an ink droplet to be expelled to a suitable receiver. The piezo ink actuator incorporates a piezo material. Material is said to possess piezo electric properties if an electric charge is produced when a mechanical stress is applied. This is commonly referred to as the “generator effect.” The converse also holds true, in that an applied electric field will produce a mechanical stress in the material. This is commonly referred to as the “motor effect.”
Inks for high speed jet droplet printers have a number of special characteristics. Typically, water-based inks have been used because of their conductivity and viscosity range. For use in a jet droplet printer, preferred inks are electrically conductive, having a resistivity below about 5000 ohm-cm and preferably below about 500 ohm-cm. For good flow through small orifices, water-based inks generally have a viscosity in the range between about 1 to 15 centipoise at 25 degree C. Preferred inks additionally are stable over a long period of time, compatible with the materials comprising the nozzle plate and ink manifold, free of living organisms, and functional after printing. Preferred after printing characteristics are smear resistance after printing, fast drying on paper, and waterproof when dry. An ideal ink also incorporates a nondrying characteristic in the jet cavity so that the drying of ink in the cavity is hindered or slowed to such a degree that through occasional spitting of ink droplets the cavities can be kept open. The addition of glycol will facilitate the free flow of ink through the ink jet. Also it is of benefit if ink additives prevent the ink from sticking to the ink jet printhead surfaces.
Ink jet printing apparatus typically includes an ink jet printhead that is exposed to the various environments where ink jet printing is utilized. The orifices are exposed to all kinds of air borne particles. Particulate debris accumulates on the printhead surfaces, forming around the orifices. The ink may combine with such particulate debris to form an interference burr to block the orifice or cause through an altered surface wetting to inhibit a proper formation of the ink droplet. That particulate debris has to be cleaned from the orifice to restore proper droplet formation. This cleaning commonly is achieved by wiping, spraying, vacuum suction, and/or spitting of ink through the orifice. Wiping is the most common cleaning technique.
The present invention provides improved cleaning of a vertical nozzle plate of an ink jet printhead. The invention provides cleaning of an ink jet printing apparatus wherein the cleaning liquid can be effectively used to provide for improved cleaning with a minimum number of parts and operations. The present invention provides for non-contacting cleaning of particulate debris, thereby eliminating the need of traditional wiper blades or other mechanical contact methods.
In accordance with one aspect of the contactless cleaning of a vertical nozzle plate, the apparatus includes a reservoir for containing cleaning fluid, and a cleaning cavity adjacent the nozzle plate. An upper fluid outlet above the cleaning cavity directs fluid into the cleaning cavity, and the conduit conducts cleaning fluid from the reservoir to the upper fluid outlet. In particular implementation, the apparatus includes an agitator for agitating fluid in the cleaning cavity. The agitator is positioned a small distance from the nozzle plate, with the distance between the agitator and the nozzle plate defining the cleaning cavity. In a further particular implementation, the agitator is a roller having a substantially vertical rotation axis.
A method of cleaning a vertical nozzle plate for an ink jet printer includes cascading cleaning fluid along the nozzle plate, and agitating the cleaning fluid against the nozzle plate. In a particular implementation described, cascading the cleaning fluid along the nozzle plate includes positioning an agitator near the nozzle plate, and cascading cleaning fluid along the outer surface of the agitator. Agitating the cleaning fluid against the nozzle plate in this particular implementation includes moving the agitator relative to the nozzle plate, such as by rotating the agitator about a rotation axis that is substantially parallel to the nozzle plate.
The printhead is a vertical printhead (i.e., the nozzle plate 12 of the printhead is substantially vertical). In the embodiment illustrated, the nozzles 14 are arranged in a substantially vertical arrangement on the vertical nozzle plate.
The cleaning station includes a structure to permit cleaning fluid to cascade along the face of the nozzle plate 12. The structure includes an agitator to agitate the cleaning fluid as it cascades along the face of the nozzle plate. In the illustrated embodiment, this structure includes a substantially cylindrical cleaning roller 16 and an upper fluid outlet 18. The cleaning roller 16 has its outer surface spaced a small distance from the face of the nozzle plate 12 to form a cleaning cavity 20 between the surface of the roller 16 and the face of the orifice plate 12. The top end of the roller 16 is at or above the top of the nozzle plate 12, and the bottom end of the roller is at or below the bottom edge of the nozzle plate. The cleaning roller has a substantially vertical central axis, and a substantially vertical rotational axis. In the embodiment illustrated in
The cleaning roller 16 is formed of any material that is compatible with the cleaning solutions to be used in cleaning the printhead. Suitable materials that do not significantly deteriorate in the presence of many cleaning fluids include anodized aluminum, and certain hard rubbers and plastics.
The upper fluid outlet 18 directs fluid into the cleaning cavity 20 between the roller surface and the nozzle plate. A reservoir 22 stores cleaning fluid 24 for use by the cleaning apparatus. In the particular embodiment illustrated, the cleaning fluid reservoir 22 is located at the bottom of the roller 16. Many types of cleaning fluid can be used. For example, the cleaning fluid may be the same as a colorless ink base without the dye or pigment.
A cleaning fluid conduit 26 extends from the reservoir 22 to the upper fluid outlet 18 to supply cleaning fluid from the reservoir to the upper fluid outlet. In the embodiment illustrated, the agitator cleaning roller 16 is hollow, and the fluid conduit 26 is through the interior of the cleaning roller. In this embodiment, the upper fluid outlet 18 is an open upper end of the hollow roller 16. The bottom end of the roller is also open to receive cleaning fluid from the reservoir 22. Other arrangements for the reservoir, fluid conduit, and upper fluid outlet will also be apparent. For example, the reservoir may be located near the top of the cleaning structure. The fluid conduit may be separate from the cleaning roller. The upper fluid outlet 18 may also be directionally oriented (such as with a nozzle) to direct cleaning fluid specifically toward the cleaning cavity 20.
An impeller 28 propels or moves fluid from the reservoir 22 through the fluid conduit 26 to the upper fluid outlet 18 at the top of the roller. In the embodiment illustrated in
A filter 29 in the fluid conduit 26 prevents debris or other particles that may be in the cleaning fluid 24 from flowing out the upper fluid outlet.
The roller 16 agitates cleaning fluid 24 at the face of the nozzle plate 12 as the cleaning fluid cascades through the cleaning cavity 20. In one particular implementation, the roller 16 agitates the cleaning fluid by rotating about the roller's rotation axis. Such rotation aids in circulating the cleaning fluid across the face of the nozzle plate. As the cleaning fluid cascades along the outer surface of the cleaning roller 16, the cleaning fluid contacts the face of the nozzle plate 12. Rotation of the cleaning roller and capillary forces help the cleaning fluid fill the gap between the surface of the cleaning roller and the face of the nozzle plate. In addition, rotation of the cleaning roller induces turbulence into the cleaning fluid in the gap, which aids in cleaning the face of the nozzle plate, and also of cleaning the orifices 14 in the nozzle plate. Those skilled in the art will recognize many mechanisms are available for rotating the cleaning roller. For example, the cleaning roller may include a central axle 30. One end of the axle is attached to a pulley wheel 32, which is driven by a belt 34 from a drive pulley 36 attached to a motor 38. The cleaning roller 16 may also be driven directly from a motor. Alternatively, a motor may drive a pulley arrangement or a gear arrangement formed on or attached to the outer surface of the cleaning roller. Contactless driving arrangements, such as magnetic couplings, are also known.
Thus, the cleaning station causes only fluid to contact the face of the nozzle plate 12 to clean the face of the nozzle plate, so that hard and potentially damaging cleaning elements do not contact the face of the nozzle plate 12. Those skilled in the art will recognize that various modifications can be made to the structure described above. For example, other structures can be used to enhance the agitation of the cleaning fluid against the face of the nozzle plate 12. Referring to the embodiment illustrated in
In another arrangement, the outer surface of the cleaning roller 16 may be configured to enhance the agitation of the cleaning fluid against the face of the nozzle plate 12. Referring to
Referring again to
The agitator and/or rotation of the cleaning roller can be varied to match the optimum cleaning action for each particular ink.
Given the principles described above, those skilled in the art will recognize that various structures other than the embodiments specifically illustrated and described above are possible. Therefore, the scope of the present invention is defined by the following claims, and the above detailed description of particular implementations of the invention do not limit the scope of the invention as defined.
This application is based on a Provisional Patent Application No. 60/342,209, filed Dec. 26, 2001.
Number | Name | Date | Kind |
---|---|---|---|
4011157 | Pennebaker et al. | Mar 1977 | A |
5997127 | Fassler et al. | Dec 1999 | A |
6047715 | Mooney et al. | Apr 2000 | A |
6281909 | Fassler et al. | Aug 2001 | B1 |
6350007 | Meichle et al. | Feb 2002 | B1 |
6511155 | Fassler et al. | Jan 2003 | B1 |
6592201 | Sharma et al. | Jul 2003 | B2 |
6726304 | Fassler et al. | Apr 2004 | B2 |
20030121531 | Fassler et al. | Jul 2003 | A1 |
Number | Date | Country |
---|---|---|
0988978 | Mar 2000 | EP |
0992355 | Apr 2000 | EP |
Number | Date | Country | |
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20030121531 A1 | Jul 2003 | US |
Number | Date | Country | |
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60342209 | Dec 2001 | US |