The present embodiments relate generally to electroformed orifice plates for high density ink jet printers.
Many different techniques and combinations of materials have been used for making small diameter nozzles for ink jet printers. Punching, laser drilling, molding, and machining have been reported as methods for making ink jet nozzles. One of the most useful and economical methods for making small holes, especially where hundreds of jets in an array are required, is by electroforming around or over small dielectric cylinders, or posts, formed of photo-imaged resist polymer. This geometry is described in numerous patents related to methods for making orifice plates, such as Kenworthy U.S. Pat. No. 4,184,925; Cloutier U.S. Pat. No. 4,528,577; and Sexton U.S. Pat. No. 4,971,665.
A need exists for smooth over plated nozzles at very close spacing for high density arrays (i.e., greater than 300 jets/inch). The problem is that the electroplating grows in thickness at nearly the same rate that the electroplating grows laterally over the dielectric post. If the posts are necessarily very small in diameter because of the close spacing, the resultant thickness of nickel is very small. For example, at jet density of 600 dpi and an orifice diameter of 0.0006 inch, the plating thickness is practically limited to 0.0005 inch thickness when plating over 0.0016 inch diameter posts. Foils at this thickness are fragile and subject to distortion during handling and use.
The present invention meets this need and provides a high density array by this method.
Embodied herein is a method for fabricating an orifice plate with a high density array of nozzles. The method begins by disposing a photoresist layer on a glass with a metalized layer forming a photomask blank and then patterning the photomask blank with one or more openings in the photoresist layer forming a patterned photomask blank. One or more second openings are formed by the first openings into the photoresist layer, thereby forming an etched blank. The photoresist layer is removed from the etched blank forming a patterned structure.
The method continues by applying a second photoresist layer to the patterned structure forming a mandrel. The mandrel is patterned to form one or more rings over each second opening. Each ring has an outer diameter larger than the diameter of the second opening and an inner diameter smaller than the diameter of the second opening forming a patterned mandrel. The patterned mandrel is plated with a metal to form an orifice plate. The orifice plate is separated from the patterned mandrel forming an orifice plate with a high density array of nozzles.
The present embodiments are advantageous over the prior art because the methods provide an array resistant to mechanical distortion.
In the detailed description of the preferred embodiments presented below, reference is made to the accompanying drawings, in which:
The present embodiments are detailed below with reference to the listed Figures.
Before explaining the present embodiments in detail, it is to be understood that the embodiments are not limited to the particular descriptions and that it can be practiced or carried out in various ways.
The present embodiments relate to a novel nozzle structure that permits close spacing of electroformed nozzles made with a thin layer of metal. By over-plating a dielectric ring, the corresponding fabricated high density arrays, of up to 600 nozzles per inch, for orifices are structurally stronger and more uniform than the nozzle structures in the current art. The methods enable the printing to occur at higher operating frequencies.
Uniform nozzle structures provide a benefit of maintaining ink jets that print in a straight line.
The embodied annular ring nozzle designs and methods herein overcomes the fragility issue that occur in the prior art by providing high aspect nozzles with the preferred smooth transition for jet stability.
The embodied methods produce a nozzle shape with an increased length for the ink jets emanating from the nozzles. The increased length is because the ring structure provides greater control over small diameter nozzles. The recess formed at the exit of the nozzles help to control the meniscus diameter of the jet coming from the nozzle, thereby creating straighter jets and, therefore, higher print quality.
An embodiment of a method for fabricating an orifice plate with a high density array of nozzles begins by disposing a first photoresist layer on a glass with a metalized layer, thereby forming a photomask blank. The first photoresist layer is typically phenol formaldehyde resin, such as Model 1813 Novolacâ„¢ resin from Shipley, of Marlboro, Mass. The first photoresist layer is added at a thickness from about 1 micrometer to about 5 micrometers. The glass on which the first photoresist layer is added is typically a soda lime glass. The metalized layer is conductive metal. Preferred examples of metals are chromium, molybdenum, titanium, tungsten, aluminum, alloys thereof, and combinations thereof.
One or more openings are patterned into the first photoresist layer located on the photomask blank. Typically, the density of openings patterned onto the photomask blank ranges from one opening per inch to about 600 openings per inch. Each opening has a first diameter ranging from about 10 micrometers to about 50 micrometers.
The method continues by etching through the first openings into the first photoresist layer to form one or more second openings in the metalized layer, thereby forming an etched blank. The diameter of the second opening is substantially equivalent to the diameter of the first openings. The second openings can be etched using either dry chemical etching or wet chemical etching.
The first photoresist layer is removed from the etched blank, thereby forming a patterned structure. The first openings are removed when the first photoresist layer is removed. The first photoresist layer can be removed by dissolving, plasma ashing, laser ablation, and combinations thereof. If the first photoresist layer is removed by dissolving, a solvent, such as acetone, methylethylketone, methylene chloride, or cyclopentanone, is typically used.
A second photoresist layer is added to the patterned structure, thereby forming a mandrel. The second photoresist layer is preferably an epoxy, such as Model SU8 available from Microchem in Newton Mass. The second photoresist layer is added at a thickness ranging from about 10 micrometer to about 50 micrometers. The second photoresist layer is preferably added at a thickness greater than the first photoresist layer.
The method continues by patterning the mandrel forming at least one ring over each second opening. Each formed ring comprises an outer diameter larger than the diameter of the second opening and an inner diameter smaller than the diameter of the second opening. The rings can be formed in numerous shapes, such as circular, ellipsoid, and polygons. The rings are preferably formed so that all of the rings have the same shape. The rings can be patterned onto the mandrel using a radiation source to cure the second photoresist layer through a photomask or by projecting a pattern onto the second photoresist layer.
The mandrel with the patterned rings is plated with a metal to form an orifice plate. Examples of usable metals to plate the mandrel include nickel, gold, copper, alloys thereof, and combinations thereof.
The method ends by separating the orifice plate from the patterned mandrel. The formed orifice plate comprises a high density array of nozzles. The orifice plate is typically removed from the mandrel by peeling, thermal shock, or other mechanical separation.
An example of embodied method entails the formation of a ring shaped precursor or mandrel, upon which the electroformed annular nozzle is plated. Formation of the mandrel involves first imaging and etching an opening in a chromium photomask blank, such as provided by the Hoya Company, Japan. In this example, a chrome blank with the etched openings is stripped of the photoresist layer and, then, recoated with positive or negative resist layer. The coating of positive or negative resist layers is done using a thickness from about 10 micrometer to 50 micrometers. A photomask with ring shaped images is then aligned precisely over the etched openings in the chromium layer. The rings are imaged using ultraviolet light exposure and developed in a suitable solution. The resultant rings are then plated with a metal. The formed orifice plate is then removed from the mandrel and the second photoresist layer is removed with acetone. The second photo resist layer can remain in the structure and a usable orifice plate can still be produced.
The embodied orifice plate formed from a plated patterned mandrel has a high density array of nozzles. The orifice plate includes a metalized layer. The metalized layer has one or more openings. The orifice plate includes a ring of dielectric material disposed internally in the metalized layer. Each ring has an outer diameter larger than the diameter of each opening and an inner diameter not larger than the diameter of each opening.
With reference to the figures,
Tests have shown that the embodied methods can produce jet arrays at 600 jets per inch; the jets tested straight to +/−1 milliradian. Testing demonstrated that the jets were uniform and stable.
The long length-to-diameter ratio (aspect ratio) of the nozzles formed by the annular plating process provides better jet stability than are obtained with known methods of making orifice plates with nozzles by plating over posts. In addition, the velocity variation of the resultant jets is much lower than with simple straight wall nozzle structures made by known electroplating.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Number | Name | Date | Kind |
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4184925 | Kenworthy | Jan 1980 | A |
4528577 | Cloutier et al. | Jul 1985 | A |
4971665 | Sexton | Nov 1990 | A |
6022752 | Hirsh et al. | Feb 2000 | A |
6586112 | Te | Jul 2003 | B1 |
Number | Date | Country |
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4-142940 | May 1992 | JP |
2005014292 | Feb 2005 | WO |
Number | Date | Country | |
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20060203036 A1 | Sep 2006 | US |