This description relates to ink jetting.
Ink jetting can be done using an ink jetting printhead that includes jetting assemblies. Ink is introduced into the ink jetting printhead and when activated, the jetting assemblies jet ink and form images on a substrate.
In one aspect, for jetting ink droplets on a substrate during relative motion of an apparatus and the substrate along a process direction, the apparatus includes first and second jetting assemblies each including an array of jets. The first and second jetting assemblies at least partially overlap in a direction perpendicular to the process direction so that some of the jets in the first jetting assembly align with some of the jets in the second jetting assembly along the process direction to form one or more pairs of aligned jets. The apparatus also includes a mechanism to enable, in at least one pair of the aligned jets, one jet to jet a first ink drop that has a size smaller than a size of an ink drop the jet would otherwise be required to jet to form a desired pixel on the substrate and the other jet to jet a second ink drop that has a size sufficient to form the desired pixel in combination with the first ink drop.
In another aspect, forming ink droplets on a substrate during relative motion of an ink jetting device and the substrate along a process direction, a method includes (a) causing a first jetting assembly of the ink jetting device to jet a first ink drop that has a size smaller than a size of an ink drop jet would otherwise be required to jet to form a desired pixel on the substrate; and (b) causing a second jetting assembly of the ink jetting device to jet a second ink drop that has a size sufficient to form the desired pixel in combination with the first ink drop.
Implementations may include one or more of the following features. The first and second jetting assemblies each comprises more than 100 jets. One or more jets in the first jetting assembly each aligns with a corresponding jet in the second jetting assembly along the process direction. Each jet in the first jetting assembly aligns with a corresponding jet in the second jetting assembly. Each jet in the first and second jetting assemblies is capable of jetting ink drops with more than one size. Each jet in the first and second jetting assemblies is capable of jetting ink drops with three different sizes. Each jet in the first and second jetting assemblies is capable of jetting ink drops with a drop size of 30 nano-grams, 50 nano-grams, or 80 nano-grams. The first ink drop and the second ink drop having a total drop size of about 50 nano-grams. The aligned jets in the first and second jetting assemblies are about 50 mm from each other along the process direction. The apparatus also includes first and second jetting assembly arrays each comprising one or more jetting assemblies, along the direction perpendicular to the process direction, the first array of jetting assemblies aligning with the first jetting assembly and the second array of jetting assemblies aligning with the second jetting assembly. Each jetting assembly in the first jetting assembly array overlaps at least partially with at least one of the jetting assemblies in the second jetting assembly array along the direction perpendicular to the process direction. Each jetting assembly in the first jetting assembly array overlaps at least partially with two jetting assemblies in the second jetting assembly array along the direction perpendicular to the process direction. Each jetting assembly includes more than one jet each aligning with a corresponding jet in a corresponding overlapping jetting assembly. The first and second arrays of jetting assemblies have a width of about 25 mm to about 1 m along the direction perpendicular to the process direction.
Implementations may also include one or more of the following features. The step (a) includes jetting a first ink drop having a drop size half of the size of the drop that is required to print the desired pixel on the substrate. The step (a) includes jetting a first ink drop having a drop size a third of the size of the drop that is required to print the desired pixel on the substrate. The first ink drop and the second ink drop to have a total drop size of about 50 nano-grams.
These and other aspects and features can be expressed as methods, apparatus, systems, means for performing a function, and in other ways.
Other features and advantages will be apparent from the following detailed description, and from the claims.
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The front and back surfaces of the cavity plate 20 are covered by a dimensionally matching polymer film 26 and a stiffener plate 28, respectively, and ink pumping chambers are formed by the cavities 24. Similar to the cavity 22 on the cavity plate 20, the stiffener plate 28 also includes a cavity 30 so that when assembled and in use, ink is filled from the ink passage formed by the cavity 16 through the top ends 32 into the pumping chambers formed by the cavities 24. The stiffener plate 28 also includes a row of openings 31. When assembled, the dimensions and relative location of the openings 31 match those of the jetting ends 36 on the cavity plate and those of the openings 33 on the surface 18 of the body 4 so that when ink is pumped in the pumping chamber and reaches the jetting ends 36, it passes the openings 31 in the stiffener plate 28 and the corresponding openings 33 on the body 4 and flows into the ink jetting passages 40 in the body 4, where it is jetted from the openings 39 (
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In some embodiments, an orifice plate (not shown) containing orifices can be attached to the bottom 46 of the body 4. Each orifice in contact with the bottom 46 of the body 4 aligns with an opening 39 and the orifices can be arranged, for example, in one or two rows corresponding to the number of rows in which the openings 39 are arranged. The orifices are connected to channels that are built within the orifice plate, which have another end connected to openings aligned in a single row in another surface of the orifice plate. Ink is jetted out to the substrate beneath the orifice plate through the single row of openings. Each pumping chamber, its corresponding ink jetting passage 38, opening 39 and orifice together form an ink jet 44 (not shown).
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The resolution at which the printhead 2 prints depends, for example, on the size and density of the pumping chambers in the jetting assemblies 6 and 8. In the example shown in the figures, the jetting assemblies 6 and 8 each has more than 50, 64, 100, 128, 256, 500, or 512 elongated parallel pumping chambers each having a length of about 5 mm, width of about 200 microns. The maximum width the printhead 2 can print is about 20 mm to about 100 mm. Information about the ink jetting printhead is also provided in U.S. Ser. No. ______, filed ______ (Attorney Docket No. 09991-259001).
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The multiple printheads 2 are staggered in associated rows, for example, rows 47 and 49, with their long dimensions 1 aligned across the substrate 41, for example, perpendicular to the process direction y to cover the substrate width W1C ranging from less than 25 mm to 1 meter or more. Each printhead 2 in one of the rows 47 and 49 overlaps with at least one, for example, two, printhead 2 in the other row in stitching zones 48. Each stitching zone 48 includes about 1 to about 4 jets 44, or even more, for example, 16 jets 44 of each printhead 2, in which each jet 44 of one printhead 2, for example, jet 44a, aligns with a corresponding jet 44 of an overlapping printhead 2, for example, jet 44b, along the process direction y.
In some embodiments, each pixel, for example, pixel 54 of the image 43 is printed by a single jet 44 of the printheads 2 that is capable of jetting ink drops with one desired uniform size. For example, one type of printhead 2 is capable of jetting ink drops each having a mass of about 30 nano-grams, another type of printhead 2 capable of jetting ink drops each having a mass of about 50 nano-grams, or still another type of printhead 2 capable of jetting ink drops each having a mass of about 80 nano-grams. In particular, ink is jetted only from one of the overlapping jets, for example, either jet 44a or jet 44b, to print each pixel of the image 43 that is on the part of the substrate 40 passing beneath the stitching zones 48 along the process direction y. The selection of which one of the two aligned jets 44 can be random or regular, for example, taking turns, configured, for example, by the controller 50.
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Printing with ink drops from one of the two aligned jets in each of the stitching zones 48 smoothes the seam between portions of images printed by different printheads across the substrate 41 and reduces or masks the undesired low quality printing, for example, streaks or image artifacts, caused by the possible misalignment of the printheads 2 in neighboring arrays both along and perpendicular to the process direction y, by the possible differences in properties between different printheads, which ideally would be identical, or by crooked or missing jets on one or more printheads.
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In the example shown in the figures, the two aligned jets 44, in particular, a and b of printhead 2a and 2b of
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Each of the stitching zones 68 and 70 contains jets 44 from overlapping printheads aligned in the process direction y. One of the stitching zones 68 and 70 can include a number of, for example, 0, 1, 2, and up to about half of the total number of jets 44, each aligned with a corresponding jet of one overlapping printhead and the other one of the stitching zones 68 and 70 of the same printhead includes the rest of the jets 44 aligned with corresponding jets of another overlapping printhead.
The printheads 2c and 2h each contains a dangling zone 72, in which the jets 44 do not have corresponding aligned jets in the process direction y. The total number of jets 44 in each dangling zone 72 is dependent on the total number of aligned jets in each stitching zones 70. In some embodiments, when the stitching zone 70 contains zero aligned jets 44, each printhead in the row 54 fully overlaps with a corresponding printhead in the row 56 and dangling zone 72 does not exist.
In some implementations, more or less than six printheads 2a-2f can be used in the way described above, depending on the width W3 of a substrate 60 the printer 58 is required to cover to print an image 44 on the substrate 60. The printer 58 can be configured so that when each jet 44 is capable of jetting ink drops with only one desired uniform property, each pixel, e.g., pixel 64, 66, 68, or 70, of the image 62 is printed with ink jetted from only one of the two aligned jets 44 along the process direction y. When each jet 44 is capable of jetting ink drops with two or more properties, each pixel of the image 62 is printed cooperatively with ink jetted from both aligned jets 44 along the process direction y. The extensive overlapping of printheads in the printer 58 allows a large number of jets 44 in the printer to have an aligned corresponding jet along the process direction y to further reduce the possible poor image quality caused by malfunctioning, for example, crooked or weak, jets of one of the printheads and blur the quality difference of portions of the image 62 printed from different printheads.
Other embodiments are also within the scope of the following claims.
For example, the printers 45 and 48 each can include more coupled printhead rows like printhead rows 47 and 49 and printhead rows 54 and 56, stacked along the process direction y. Each pair of rows can print a different color than the other pairs. In each of the printers 45 and 48, each printhead 2 can have its long dimensions 1 form an angle different than 90 degrees with the process direction y. Printheads other than that described in
When there is little or no jetting in the printer 45 or 48, ink recirculation can be done by letting ink flow slowly in one of the two ink inlets 12 and 14 of each printhead 2 through the ink passage 16 and out the other one of the ink inlets 12 and 14.
It should be understood that reference to ink as the printing fluid was for illustrative purposes only, and referring to components within the jetting assemblies described above with the adjective “ink” was also illustrative. The jetting assemblies can be used to dispense or deposit various printing fluids other than ink onto a substrate. The fluids can include non-image forming fluids. For example, three-dimensional model pastes can be selectively deposited to build models. Biological samples can be deposited on an analysis array.