Patent Application
20120133708
The present invention relates to inkjet printing and in particular to pagewidth inkjet printers.
Various methods, systems and apparatus relating to the present invention are disclosed in the following US patents/patent applications filed by the applicant or assignee of the present invention:
The disclosures of these applications and patents are incorporated herein by reference.
Inkjet printing is a versatile and widely used form of print imaging. So called ‘drop-on-demand’ inkjet printing (as opposed to continuous inkjet printing) is the ejection of ink drops by forming vapor bubbles in a bubble forming liquid. This principle is generally described in U.S. Pat. No. 3,747,120 (Stemme). Each pixel in the printed image is derived ink drops ejected from one or more ink nozzles. Many different aspects and techniques for inkjet printing are described in detail in the above cross referenced documents.
Inkjet printers have a printhead with an array of nozzles though which ink is ejected onto a media substrate such as paper or film. Typical SOHO (Small Office, Home Office) inkjet printers or wide format inkjet printers have a scanning printhead. The printhead scans across the printed width of the media substrate and prints a swathe of the printed image with each traverse.
More recently, pagewidth printers have been developed to speed up the printing process. A pagewidth printhead remains stationary within the printer and has an array of nozzles that extends the entire printing width of the media substrate. Media substrate passes through the printer as the printhead prints the width of the media simultaneously. By not traversing the printhead across the media as it indexes through the printer, print speeds are significantly increased.
The gap between the nozzle array and the surface of the media substrate is referred to as the ‘print gap’ or the printhead to paper separation (PPS). This gap is typically less than 3 mm. However, the movement of the media substrate and the ejection of ink drops can generate vortices in the air flow through the print gap. Under certain conditions, the vortices in the air flow oscillate and skew the trajectories of the ejected ink drops. This produces visible artifacts in the printed image and degrades print quality. The artifacts appear as a series of irregular bands extending generally transverse to the media feed direction and are generally referred to as ‘tiger stripes’, ‘sand dunes’, ‘wood grain’ or ‘worms’.
Accordingly, the present invention provides an inkjet printer comprising:
a printhead with a nozzle array for ejecting droplets of ink onto a media substrate;
a media feed assembly for feeding media past the printhead in a media feed direction such that the nozzle array and the media substrate are separated by a print gap; and,
an air flow generation mechanism for generating air flow in the print gap opposite to the media feed direction.
The Applicants analysis of ‘tiger striping’ has found that generating air flow in the print gap counter to the air flow caused by media movement will remove or substantially reduce the oscillation of the vortices. Without the oscillation of the vortices, the printed image does not suffer from tiger stripes.
Preferably, the printhead is a pagewidth printhead and the nozzle array extends a printing width of the media substrate. Preferably, the air flow generation mechanism is operatively linked to the media feed assembly. Preferably, the air flow generation mechanism has a roller positioned adjacent the pagewidth printhead, the roller having an axis of rotation extending parallel to the printing width of the media substrate and perpendicular to the media feed direction. Preferably, the roller is part of the media feed assembly. Preferably, the print gap is more than 1 mm. Preferably, the print gap is between 1 mm and 2 mm.
Preferably, the pagewidth printhead is configured to eject droplets of ink with a volume less than 3 pico-liters. Preferably, the pagewidth printhead is configured to eject droplets of ink with a volume less than 2 pico-liters. Preferably, the pagewidth printhead is configured to eject droplets of ink with a volume between 1.0 pico-liters and 2.0 pico-liters.
Preferably, the media feed assembly feeds media past the pagewidth printhead at more than 0.15 msec. Preferably, the media feed assembly feeds media past the pagewidth printhead at more than 0.3 msec. Preferably, the media feed assembly feeds the media past the printhead at more than 0.5 msec.
Preferably, the pagewidth printhead has a series elongate printhead integrated circuits mounted end to end such that they extend the printing width of the media substrate, each of the printhead integrated circuits having a portion of the nozzle array. Preferably, the nozzle array has nozzles arranged in rows extending the printing width of the media substrate, and perpendicular to the media feed direction. Preferably, each of the printhead integrated circuits is configured to simultaneously eject at least three different colors of ink.
Preferably, the roller axis is less than 30 mm from the printhead integrated circuits. In a further preferred form, the roller has a diameter less than 10 mm.
Preferred embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings, in which:
Referring to
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The roller 20 should be relatively proximate the printhead ICs 9 to generate adequate air flow 21 in the print gap 16. The Applicant's testing has found that for roller diameters less than 10 mm, and media feed speeds of more than 0.15 m/sec, the spacing X from the roller axis to the printhead ICs 9 should be less than 30 mm. Furthermore, any sources of pressure loss between the printhead ICs 9 and the roller 20 should be avoided. Using a shroud or roller cover 19 ensures the air flow 21 is largely drawn from the print gap 16.
The size of the droplets 18 has a bearing on the amount of tiger striping in the printed image. Larger volume droplets, say more than 4 pico-liters, suffer less misdirection from oscillation of the vortices than smaller droplets and so result in less tiger striping. However, large drops result in large dots on the paper and this compromises spatial resolution and colour resolution. Drops of around 2 pl are required to decrease image “graininess” below the limit of resolution of the human eye. Applicant testing in this area has found that the present invention allows the droplet volume to be less than 3 pico-liters. More importantly from an image quality perspective, droplet volumes less than 2 pico-liters do not generate visible tiger striping. Applicant's development in this area has found droplet volumes between 1 pico-liter and 2 pico-liters are desirable for optimum print quality. Test prints with droplet volumes in this range are also free of tiger striping.
Although the vortices 14 and 15 and their oscillation 17 is reduced with smaller print gaps 16 and eliminated entirely by reducing the print gap 16 to <˜1 mm, this makes media handling more challenging. There are several compelling reasons to increase the print gap 16:
a) In typical double-sided/duplex printing, the paper is not printed on both sides simultaneously. During half-duplex printing (where the page is printed on one side and then passed under the same printhead a second time to print on the reverse side), the first side of the paper will be wet with ink, and the paper will no longer be flat. The term ‘cockle’ is often used to describe this. A larger print gap accommodates the cockle in the paper, without risk of the paper striking the printhead IC's 9.
b) Simplex (single-sided) or duplex printing of media substrate with an uneven surface (eg corrugated board or envelopes) also requires a larger print gap 16.
c) The ability to print on different thickness media is another common user expectation. Although this can be achieved through more sophisticated paper handling systems, a larger print gap will enable this with a less complex and lower cost media feed assembly 8. Indeed, regardless of different media thicknesses, increased print gaps potentially allow a cost reduction in the paper handling system through use of lower specification components and assembly.
Using the present invention, the print gap 16 can be greater than 1 mm while the additional air flow 21 suppresses oscillations in the upstream and down stream vortices 14 and 15. Testing has found that the invention permits a print gap 16 between 1 mm and 2 mm without visible tiger stripes in the resulting print.
The invention has been described herein by way of example only. Skilled workers in this field will readily appreciate that many variations and modifications are possible without departing from the spirit and scope of the broad inventive concept.
