This invention relates to cleaning ink-jet printing apparatus, particularly apparatus used for commercial printing.
Commercial printing may be done on multi-color continuous web printing presses. Paper rolls are unrolled along a paper path that includes separate stations for each color. An optional dryer may be placed after the final print station. The web is then slit into sheets and stacked.
In ink-jet printing, ink is ejected from a narrow orifice in the direction of a substrate. In one type of ink-jet printing, known as drop-on-demand printing, the ink is ejected in a series of droplets. The droplets may be produced and controlled using a piezoelectric ink-jet head which has a large number of orifices, each of which is separately controllable to selectively eject ink at desired locations, or pixels, of the image. For example, an ink-jet head may have 256 orifices that have spacing for a printing resolution of at least 100 pixels (dots) per inch (dpi) and sometimes far more than that. This dense array of orifices allows complex, highly accurate images to be produced. In high performance print heads, the nozzle openings typically have a diameter of 50 microns or less, e.g., around 25 microns, are separated at a pitch of 25-300 nozzles/inch, have a resolution of 100 to 3000 dpi or more, and provide drop sizes of about 1 to 70 picoliters (pl) or less. Drop ejection frequency is typically 10 kHz or more. A drop-on-demand piezoelectric print head is described in U.S. Pat. No. 4,825,227, the entire contents of which is incorporated herein by reference.
While such dense arrays of orifices produce complex, highly accurate images, image quality can deteriorate if one or more of the orifices become obstructed. For example, a partially obstructed orifice may alter the direction, size, or stability of the droplets. It is important to keep these apertures open and functional to avoid degradation of print quality. It is also important to clean the ink jets quickly without undue equipment down time. Moreover, since position of the ink jets relative to the paper is important, cleaning the heads should not unnecessarily dislocate the print-head module and should return it as close to its original position as possible.
In general, in a first aspect, the invention features an apparatus including a print bar for mounting a print head and a first pivot coupling to allow the print bar to pivot to or from a printing position.
Embodiments of the apparatus may include one or more of the following features and/or features of other aspects.
The apparatus may further include a cleaner in a cleaning position, wherein the pivot coupling allows the print bar to pivot (e.g., by about 90°) to a cleaning position in proximity to the cleaner. Additionally, the apparatus may include a second pivot coupling to allow the cleaner to pivot (e.g., by about 90°) between the cleaning position and an idle position. The print bar may be substantially non-parallel to the web when in the cleaning position (e.g., orthogonal to the web). The cleaner can use a vacuum to clean the print bar when the print bar and the cleaner are in their respective cleaning positions. The cleaner can use a cleaning fluid (e.g., a solvent) with or without a vacuum to clean the print bar when the print bar and the cleaner are in their respective cleaning positions. The cleaner can span the print bar.
The apparatus may include a print support to register the print bar relative to a web when the print bar is in the printing position. The print bar and the support can include mating features that couple when the print bar is in the printing position. Alternatively, or additionally, the print bar and the cleaner can include mating features that couple when the print bar is in the cleaning position. The print bar may be substantially parallel to the web when in the printing position.
In some embodiments, a print head mounted on the print bar jets ink substantially orthogonal to the web when the print bar is in the printing position.
In a further aspect, the invention features a single-pass, web-based print station including the apparatus.
In general, in another aspect, the invention features an apparatus for cleaning ink-jet heads mounted on a print bar. The apparatus includes a print bar pivotally fixed to a first support member to allow the print bar to pivot from a printing position to a cleaning position, and a cleaner adjustably coupled to a second support member to allow the cleaner to adjust from a cleaning position to an idle position, wherein the first support member is fixed relative to the second support member.
Embodiments of the apparatus may include one or more of the following features and/or features of other aspects.
The cleaner can be positioned to clean print heads mounted on the print bar when the print bar and the cleaner are each in their respective cleaning positions. The print bar and the cleaner can include mating features that couple when the print bar and the cleaning bar are each in their respective cleaning positions. The print bar and the first support member can include mating features that couple when the print bar is in the printing position.
The apparatus can further include a drive to pivot the print bar and a drive to adjust the cleaning bar. In addition, the apparatus can include a controller to control the print bar pivot drive and the cleaning bar adjustment drive. The controller can include a processor to: (a) activate the print bar pivot drive to pivot the print bar to the printing position and the cleaning bar adjustment drive to adjust the clear bar to the idle position; and (b) activate the print bar pivot drive to pivot the print bar to the cleaning position and the cleaning bar adjustment drive to adjust the clear bar to the cleaning position. The apparatus can include a limit sensor to stop pivoting the print bar to the printing position and to stop adjusting the cleaning bar to the idle position, and to activate the print bar pivot drive to pivot the print bar to the cleaning position and the cleaning bar adjustment drive to adjust the cleaning bar to the cleaning position.
The print bar can include mating features that engage mating features on the cleaner or first support.
In general, in a further aspect, the invention features a method of cleaning print heads mounted on a print bar, where the print bar is pivotally fixed to a first support member to allow the print bar to pivot from a printing position to a cleaning position. The method includes: (a) providing a cleaning bar adjustably coupled to a second support member to allow the cleaning bar to adjust from a cleaning position to an idle position, the print bar being positioned such that, when the print bar and the cleaning bar are each in their respective cleaning positions, the cleaning bar is positioned to clean print heads mounted on the print bar; (b) pivoting the print bar from the printing position to the cleaning position; (c) adjusting the cleaning bar from the idle position to the cleaning position; and (d) cleaning print heads mounted on the print bar.
The method may be implemented using the aforementioned apparatus.
Embodiments may include one or more -of the following advantages. Print head cleaning can be accomplished quickly and easily without disassembly of the printing system. The printing heads can be carried on a single moveable print bar which avoids realignment of the heads relative to one another after cleaning. The print bar motion is achieved by a pivoting coupling which permits highly accurate, reproducible realignment of the print bar with the substrate path after cleaning, and does not require movement of the paper path to access the face of the print heads. The cleaning apparatus can also be moved into a cleaning position by pivoting motion. Cleaning can be accomplished in a small physical space.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols indicate like elements.
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In a printing position, the print bar 24 is arranged above the web path to provide proper alignment and a uniform stand-off distance between the print heads 30 and the web 14. In typical arrangement, the stand off distance between the web path and the print bar is between about 0.5 and one millimeter. The print heads 30 can be of various types, including drop on demand ink-jet print heads with arrays of small, finely spaced nozzle openings. Piezoelectric ink-jet print heads are described-in Hoisington U.S. Pat. No. 5,265,315, Fishbeck et al. U.S. Pat. No. 4,825,227 and Hine U.S. Pat. No. 4,937,598, the entire contents each of which is hereby incorporated by reference. Other types of print heads can be used with the print bar, such as, for example, thermal ink jet print heads in which heating of ink is used to effect ejection. Continuous ink-jet heads, that rely on deflection of a continuous stream of ink drops can also be used.
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Print bar base 26 includes a drive 91 (e.g., a stepper motor) that pivots print bar 24 between the printing position and the cleaning position. A controller 99 (e.g., including an electronic processor) controls the operation of print bar base drive 91. Cleaner base 46 also includes a drive 92, which adjusts cleaning bar 44 between its cleaning position and idle position. Controller 99 similarly controls the operation of cleaner base drive 92. Controller 99 is also in communication with limit sensors 90 and 95 (e.g., optical sensors or electrical contact sensors), which are attached to print supports 28 and cleaner base 46, respectively. Limit sensor 90 detects when print bar 24 is in the printing position and sends a signal to controller 99, causing the controller to disengage the print bar base drive. Similarly, limit sensor 95 detects when the cleaner bar is in the cleaning position or idle position and causes the controller to disengage the cleaning bar drive. In the present embodiment, sensors 90 and 95 are attached to the print supports and cleaner base, respectively, however, in general, the limit sensors can be positioned at any location from which they can detect an appropriate print bar or cleaning bar position. Additional sensors can be included. For example, an additional sensor may be positioned to detect when print bar 24 is in the cleaning position.
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In embodiments, other cleaning arrangements can be used. For example, the cleaning bar need not extend the full width of the print bar. Instead, the cleaning bar can be indexed across the print bar. The cleaning bar can be moved into a cleaning position using assemblies other from pivoting arrangements. For example, the cleaning bar may be slid in a plane parallel to its plane or translated traverse to its plane into proximity of the printing bar after the printing bar has been pivoted from the printing condition. The cleaning can be accomplished by apparatus other than cleaning bar. For example, a vacuum hose could be translated across the face of the print bar to sequentially vacuum portions of the print bar. A wiper could be used to wipe debris from the face of the print bar.
In embodiments, other pivoting arrangements or orientations can be used. The axis of rotation of the pivot could be parallel to the web path. For example, the print bar could be coupled to a support at the edge of the web path or in the middle of the web path. The print bar and/or the cleaning bar may not be planar. For example, the print bar could have a curvature or receptacles that otherwise align printheads to follow a web path that has curvature. The cleaning bar can have a curvature complementary to the print bar curvature.
While particularly beneficial for a large-scale, single-pass web based print stations as illustrated in
Still further embodiments are in the following claims.
Number | Date | Country | Kind |
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PCT/US04/18712 | Jun 2004 | WO | international |
Number | Date | Country | |
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Parent | 10458822 | Jun 2003 | US |
Child | 10982746 | Nov 2004 | US |