Reliable high performance drop generator for an inkjet printhead
First Claim
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1. An inkjet drop ejection system comprising:
- (a) a substantially rectangular substrate having a top surface and an opposing bottom surface, and having a first outer edge along a periphery of said substrate and a second outer edge along said opposite periphery of said substrate;
(b) a nozzle member having a plurality of ink orifices formed therein, said nozzle member being positioned to overlie said top surface of said substrate;
(c) first and second pluralities of ink ejection elements formed on said top surface of said substrate, each of said ink ejection elements comprising a firing element in a vaporization chamber and being located approximate to an associated one of said orifices for causing a portion of ink to be expelled from said associated orifice as said inkjet drop ejection system is moved along a scan direction, said first plurality of ink ejection elements arranged in a first array along said first outer edge and said second plurality of ink ejection elements arranged in a second array along said second outer edge, each said vaporization chamber and associated orifice being offset from adjacent vaporization chambers and orifices along a direction perpendicular to said scan direction;
(d) an ink reservoir for holding a quantity of ink;
(e) a fluid channel, communicating with said reservoir, leading to each of said orifices and said ink ejection elements, said fluid channel allowing ink to flow from said ink reservoir, around said first outer edge of said substrate and to said top edge of said substrate so as to be proximate to said orifices and said ink ejection elements;
(f) a separate inlet passage defined by a barrier layer for each vaporization chamber connecting said fluid channel with said vaporization chamber for allowing high frequency refill of said vaporization chamber;
(g) a group of said firing elements in adjacent relationship forming a primitive in which only one firing element in said primitive is activated at a time by a combination of a primitive select signal and a firing element address signal, said address signals associated with each firing element in a primitive being sequentially generated in time in a fixed sequence, the timing of the firing of offset firing elements in a said primitive by said sequence address signals being such that later-occurring address signals in said fixed sequence control the firing of offset firing elements that are located downstream from other firing elements in each of said first array and said second array with respect to said scan direction, the combination of the firing of one firing element in a primitive at a time and the firing of offset firing elements by later-occurring address signals in said fixed sequence thereby reducing cross-talk between vaporization chambers;
(h) circuit means for transmitting firing signals to said ink firing elements at a maximum frequency greater than 9 KHz; and
(i) said inkjet drop ejection system forming a part of a color set comprising at least one ink, said ink comprising at least one colorant in an aqueous vehicle.
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Abstract
An inkjet drop ejection system comprises a combination of printhead components and ink, mutually tuned to maximize operating characteristics of the printhead and print quality and dry time of the ink. Use of a short shelf (distance from ink source to ink firing element), on the order of 55 microns, provides a very high speed refill. However, it is a characteristic of high speed refill that it has a tendency for being over-damped. To provide the requisite damping, the ink should have a viscosity greater than about 2 cp. In this way, the ink and architecture work together to provide a tuned system that enables stable operation at high frequencies. One advantage of the combination of a pigment and a dispersant in the ink is the resultant higher viscosity provided. The high speed would be of little value if the ink did not have a fast enough rate of drying. This is accomplished by the addition of alcohols or alcohol(s) and surfactant(s) to the ink. Fast dry times are achieved with a combination of alcohols, such as iso-propyl alcohol with a 4 or 5 carbon alcohol or with iso-propyl alcohol plus surfactant(s). One preferred embodiment of a short shelf (90 to 130 microns), ink viscosity of about 3 cp, and surface tension of about 54 provides a high speed drop generator capable of operating at about 12 KHz. Reducing the shelf length to about 55 microns, in combination with rotating the substrate at an angle to the scan direction, permits maximum drop generator operation as high as about 20 KHz. As a consequence of employing pigment-based inks, high optical densities are realized, along with excellent permanence (no fade and better waterfastness), and good stability. The combination of preferred ink and pen architecture provides good drop generator stability.
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Citations
44 Claims
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1. An inkjet drop ejection system comprising:
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(a) a substantially rectangular substrate having a top surface and an opposing bottom surface, and having a first outer edge along a periphery of said substrate and a second outer edge along said opposite periphery of said substrate; (b) a nozzle member having a plurality of ink orifices formed therein, said nozzle member being positioned to overlie said top surface of said substrate; (c) first and second pluralities of ink ejection elements formed on said top surface of said substrate, each of said ink ejection elements comprising a firing element in a vaporization chamber and being located approximate to an associated one of said orifices for causing a portion of ink to be expelled from said associated orifice as said inkjet drop ejection system is moved along a scan direction, said first plurality of ink ejection elements arranged in a first array along said first outer edge and said second plurality of ink ejection elements arranged in a second array along said second outer edge, each said vaporization chamber and associated orifice being offset from adjacent vaporization chambers and orifices along a direction perpendicular to said scan direction; (d) an ink reservoir for holding a quantity of ink; (e) a fluid channel, communicating with said reservoir, leading to each of said orifices and said ink ejection elements, said fluid channel allowing ink to flow from said ink reservoir, around said first outer edge of said substrate and to said top edge of said substrate so as to be proximate to said orifices and said ink ejection elements; (f) a separate inlet passage defined by a barrier layer for each vaporization chamber connecting said fluid channel with said vaporization chamber for allowing high frequency refill of said vaporization chamber; (g) a group of said firing elements in adjacent relationship forming a primitive in which only one firing element in said primitive is activated at a time by a combination of a primitive select signal and a firing element address signal, said address signals associated with each firing element in a primitive being sequentially generated in time in a fixed sequence, the timing of the firing of offset firing elements in a said primitive by said sequence address signals being such that later-occurring address signals in said fixed sequence control the firing of offset firing elements that are located downstream from other firing elements in each of said first array and said second array with respect to said scan direction, the combination of the firing of one firing element in a primitive at a time and the firing of offset firing elements by later-occurring address signals in said fixed sequence thereby reducing cross-talk between vaporization chambers; (h) circuit means for transmitting firing signals to said ink firing elements at a maximum frequency greater than 9 KHz; and (i) said inkjet drop ejection system forming a part of a color set comprising at least one ink, said ink comprising at least one colorant in an aqueous vehicle. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44)
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Specification
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Current AssigneeHewlett-Packard Development Company, L.P. (HP Inc.)
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Original AssigneeHewlett-Packard Company (HP Inc.)
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InventorsStoffel, John L., Childers, Winthrop D., Webb, Steven L., Steinfield, Steven W., Prasad, Keshava A., Donovan, David H., Courian, Kenneth J., Sader, Richard A., Keefe, Brian J., Moritz, Jules G. III
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Primary Examiner(s)Fuller, Benjamin R.
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Assistant Examiner(s)Brooke, Michael S.
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Application NumberUS09/090,968Time in Patent Office453 DaysField of Search347/63, 347/65, 347/1, 347/11, 347/12, 347/13, 347/57US Class Current347/63CPC Class CodesB41J 2/04511 for electrostatic discharge...B41J 2/04541 Specific driving circuitB41J 2/04543 Block drivingB41J 2/04546 MultiplexingB41J 2/0458 controlling heads based on ...B41J 2/04581 controlling heads based on ...B41J 2/14024 Assembling head partsB41J 2/1404 Geometrical characteristicsB41J 2/14072 Electrical connections, e.g...B41J 2/14129 Layer structureB41J 2/14145 Structure of the manifoldB41J 2/14201 Structure of print heads wi...B41J 2/1433 Structure of nozzle platesB41J 2/1603 of the front shooter typeB41J 2/1623 bonding and adhesionB41J 2/1625 electroformingB41J 2/1628 dry etchingB41J 2/1631 photolithographyB41J 2/1634 laser machiningB41J 2/1643 thin film formation by platingView All
