Self-assembling structures for electrostatic extraction of pigments from liquid inks for marking

A fabricated structure for use with an associated marking device is provided. In one form, the fabricated structure includes a self-lifting spring finger having a nib for marking.

BACKGROUND

The exemplary embodiments relate to a fabricated structure. It finds particular application in electrostatic extraction of pigments from a liquid ink for marking, and will be described with particular reference thereto. However, it is to be appreciated that the present exemplary embodiments are also amenable to other like applications.

Digital printing processes using liquid inks with suspended particles have been developed for high quality and high speed printing targeted in commercial and industrial markets. However, at this time, some print head fabrication schemes do not lend themselves to batch fabrication and excellent printing characteristics. A planar batch-fabricated process would be particularly beneficial. The technology demands well defined electrostatic field concentrators (tips) that can be precisely and uniformly positioned relative to each other. Preferably, tips would have internal structures and overall shapes to optimize capillary and electrostatic forces.

FIGS. 1A and 1Bschematically illustrate a known system100for pigment extraction from an electrically insulating liquid. A conducting nib or tip102extending slightly above the flowing liquid reservoir104is coated with liquid106by capillary forces. Positively charged pigment particles108(Illustrated inFIG. 1B) are suspended within the fluid. A positive pulse110applied to the nib102propels the pigment particles toward the ‘ground electrode’114which extracts the concentrated particles in a droplet from the nib or tip102.

In addition, other structures known as CLAW structures have found use in photo-lithographically patterned spring structures. U.S. Pat. No. 6,794,737 B2 to Fork et al., and U.S. Pat. No. 5,613,861 A to Smith et al., both disclose a stress-balancing layer formed over portions of a self-lifting spring finger that remain attached to an underlying substrate to counter internal stress. These structures are based on depositing and patterning metal layers with controlled vertical stress gradients. Upon release the metal strips curl up out of the plane of fabrication. Additional layers are formed by various methods such as sputtering, plating, etc. and combinations, thereof.

INCORPORATION BY REFERENCE

BRIEF DESCRIPTION

In accordance with one aspect of the exemplary embodiment, a planar fabricated structure for use with an associated marking device selected from a plurality of marking device types for making marks on an associated substrate is provided. The planar fabricated structure includes a substrate and a self-lifting spring finger. The self-lifting spring finger includes an unlifted anchor portion attached to the substrate. A release portion extends over the substrate and has a proximal end and a distal end. The distal end includes a tip operative to facilitate the emission of marking fluid. The release portion of the self-lifting spring finger lifts out of the plane when etched.

In accordance with another aspect, a planar fabricated structure for use with an associated marking device selected from a plurality of marking device types for making marks on an associated substrate is provided. The planar fabricated structure includes a substrate and a self-lifting spring finger. The self-lifting spring finger includes an unlifted anchor portion attached to the substrate. A release portion extends over the substrate and has a proximal end and a distal end. The distal end includes a tip operative to facilitate the emission of marking fluid. An electrically insulating tether strip is layered across the release portion. The release portion of the self-lifting spring finger lifts out of the plane when etched.

In accordance with another aspect, a planar fabricated structure for use with an associated marking device selected from a plurality of marking device types for making marks on an associated substrate is provided. The planar fabricated structure includes a substrate and a plurality of self-lifting spring fingers. The plurality of self-lifting spring fingers each includes an unlifted anchor portion attached to the substrate. A release portion extends over the substrate and has a proximal end and a distal end. The distal end includes a tip operative to facilitate the emission of marking fluid. The plurality of self-lifting spring fingers is arranged so that the tips are clustered. The release portion of the self-lifting spring finger lifts out of the plane when etched.

In accordance with another aspect, a planar fabricated structure for use with an associated marking device selected from a plurality of marking device types for making marks on an associated substrate is provided. The planar fabricated structure includes a substrate and a plurality of self-lifting spring fingers. The plurality of self-lifting spring fingers includes an unlifted anchor portion attached to the substrate. A release portion extends over the substrate and has a proximal end and a distal end. The distal end includes a tip operative to facilitate the emission of marking fluid. The planar fabricated structure further includes an electrically insulating tether strip layered across the release portion of each self-lifting spring finger. A plurality of tether strip rows and a plurality of tether strip columns form a tether net structure. The release portion of the self-lifting spring finger lifts out of the plane when etched.

One advantage of at least one embodiment is the reduction of metal required to sputter. This may reduce the cost of sputtering by reducing machine time material consumption, and downtime for preventative maintenance (flaking). Additionally, by enabling the utilization of thinner self-lifting spring, the emitter sharpness may be more controllable since it will be determined more by the lithography than by the undercut evolution.

Another advantage of at least one embodiment is that tips can be patterned to optimize capillary and electrostatic forces.

Another advantage of at least one embodiment is that fabrication is planar and batch produced for low cost, high precision, and integrity with electronics.

Another advantage of at least one embodiment is that the three dimensional structure is self-assembling.

Another advantage of at least one embodiment is that tether nets can support aperture plates

Another advantage of at least one embodiment is that vertical emitters can be fabricated with varied height.

Another advantage of at least one embodiment is that mechanically stable emitters with sharp ends may be batch processed.

Still further advantages of the present disclosure will become apparent to those of ordinary skill in the art upon reading and understanding the following detailed description of the preferred embodiments.

DETAILED DESCRIPTION

According to the presently described embodiments, planar, batch fabricated structures use precisely patterned, self-assembling features to position electrostatic ink nibs or tips for use in suitable marking devices or systems. In one form, a system uses single or multi-layers with controlled vertical stress gradients to create three-dimensional structures upon release from the substrate. Various assemblies are proposed which allow inexpensive, highly integrated, highly functional digital marking systems to be fabricated.

In an exemplary embodiment,FIGS. 2A,2B,3A, and3B illustrate a fabricated structure which enables cost effective and precise fabrication of nib or tip arrays and their integration with ancillary fluid handling structures as well as drive electronics. A basic notion, in at least one form, is the use of CLAW-like self-assembling elements to provide the nibs or tips. A nib or tip is part of the CLAW-like structure which comes into near or actual contact with a marking surface to deposit agglomerated positively charged pigment particles.

In this regard,FIGS. 2A and 2Bshow a fabricated structure in an unrelaxed state which, upon release, transforms into a relaxed three-dimensional configuration shown inFIGS. 3A and 3B. It should be appreciated that in at least one form, the release of the structure of the presently described embodiment into a relaxed state occurs during etching/fabrication.

As shown inFIGS. 2A and 2B, a self-lifting spring finger200for use with an associated marking device is shown within a fabricated structure201. It should be appreciated that the fabricated structure201may be used in conjunction with any suitable associated marking device operative for facilitating the emission of marking fluid. The fabricated structure201generally includes a substrate206and a release layer212, and one or more layers which comprise the self-lifting spring finger200, which includes the unlifted anchor portion208attached to the substrate206via a support pad210. The fabricated structure further includes the release portion202extending over the release layer212and substrate206. Upon sacrificial etching of at least part of the release layer212the released finger relaxes the internal stresses to form the desired three dimensional structures. In one embodiment, the self-lifting spring finger comprises a metal with a built-in stress gradient which, upon release, will be perpendicular to the substrate. (The stress nearest the substrate is compressive and the stress near the top surface is tensile so that upon release the finger relaxes by bending up and away from the substrate.) The release portion202has a proximal end212at the edge of the unlifted anchor portion208and substrate206and a distal end202T. As illustrated inFIG. 2B, the fabricated structure further includes an anchor pad214on the anchor portion208of the self-lifting spring finger200. In a second case the self-lifting spring finger200comprises a non built-in stress gradient metal and an overlayer portion comprising a built-in stress gradient.

With regard toFIG. 3A, the self-lifting spring finger200is shown in a relaxed state after release. The tip202T extends out of the page as shown. The tip202T is shaped accordingly to enhance capillary definition of agglomerated positively charged pigment particles allowing for emission of ink or marking fluid in, for example, a device for electrostatic extraction of pigmented ink for marking.

With regard toFIG. 3B, a cross-sectional view ofFIG. 3Ais illustrated. The fabricated structure201for use with an associated marking device shows the release portion202of self-lifting spring finger200in a relaxed state after release.

In another embodiment,FIGS. 4A and 4Billustrate self-lifting spring fingers400a-cwith tethered tips within a structure401. It should be appreciated that the fabricated structure401may be used in conjunction with any suitable associated marking device operative for facilitating the emission of marking fluid. As shown inFIG. 4A, the self-lifting spring fingers400a-cfor use with an associated marking device are shown. The self-lifting spring fingers400a-cgenerally includes release portions402a-c. The release portions402a-cfurther include distal ends404a-c. The distal ends404a-cform a set of tips402Ta-Tc. An electrically insulating tether strip416is layered across and bonded to fingers400a-cnear the distal ends404a-cof the release portion402a-c. Also shown are anchor portions408a-c.

In at least one form, the shape of the tips402Ta-Tc, which can be formed photo-lithographically, or by other suitable techniques, are uniform from tip to tip. The respective height of the tips402Ta-Tc can be controlled across the entire substrate to be at least within +/−5 microns of one another, e.g. within +/−3 microns, or +/−2 microns. The height is selected to keep field concentrations at the tips constant.

The relative distance between tips402Ta-Tc are also configured to be uniform. The deviation for the relative positions between the tips, such as402Ta-Tc, may be no more than +/−10 microns, and e.g. less than about +/−7 microns, or +/−5 microns. According to the presently described embodiments, the way to effectively lock the tip-tip distances is to provide a tether strip416between tips.

With regard toFIG. 4B, a cross-sectional view of fabricated structure401which includes self-lifting spring finger400ais illustrated. It is to be appreciated that self-lifting spring fingers400band400cmay be similarly illustrated.

The fabricated structure401for use with an associated marking device shows the self-lifting spring finger400ain an unrelaxed state with the electrically insulating tether strip416layered across and bonded to finger409near the distal end404aof the release portion402a.

In another embodiment,FIGS. 5A and 5Bcollectively illustrate a fabricated structure501with clustered tips. It should be appreciated that the fabricated structure501may be used in conjunction with any suitable associated marking device operative for facilitating the emission of marking fluid. With regard toFIG. 5A, self-lifting spring fingers500a-dare shown within a structure501. The self-lifting spring fingers500a-dinclude a plurality of release portions502a-darranged perpendicularly to each other forming clustered tips502Ta-Td.

With regard toFIG. 5B, a cross-sectional view of fabricated structures501which include self-lifting spring fingers500a,500b, and500cis illustrated. The fabricated structure501for use with an associated marking device shows self-lifting spring fingers500a-cin a relaxed state. It is to be appreciated that a fabricated structure501would include self-lifting spring finger500dbut is not similarly illustrated for ease of reference.

It is desirable in some forms to have multiple tips, such as,502Ta-Td clustered to form a single capillary structure. The individual tips502Ta-Td cluster can be addressed individually to enable some drop steering or digital gray level ejection.

With regard toFIG. 5B, the clustered tips may form approximately a 90° bend satisfying the following Equation 1:
D=L(1−2/π),
wherein, D is the distance between adjacent distal ends, for example,504bof the release portion502band504cof the release portion502c. L, as illustrated inFIG. 5A, is the distance between the tip502Td of spring finger500dand the proximal end of spring finger500d, that is, at the release end of the anchor. The formula is precise only when the distance between tips inFIG. 5Ais negligible compared with the finger length L, that is where L is very nearly equal to the distance from the anchor to the midpoint of the unreleased cluster.

In another embodiment,FIGS. 6A and 6Billustrate a fabricated structure with a tether net and supported aperture plate (not shown inFIG. 6A). Tethering of two-dimensional arrays of tips can be implemented as shown inFIGS. 6A and 6B. With regard toFIG. 6A, self-lifting spring fingers600a-fand600g-lare shown within a structure601. The self-lifting spring fingers600a-fand600g-lare provided with a plurality of tether strip rows618and a plurality of tether strip columns616, respectively to form a tether net structure. Not shown are sacrificial spacer pads between the two sets of tethers. Before spring release the sacrificial spacer pads are etched away leaving the two sets of tethers free to move independently of each other.

With regard toFIG. 6B, a partial cross sectional view of fabricated structure601which includes self-lifting spring fingers600a, and600dis provided. It should be appreciated that the fabricated structure601may be used in conjunction with any suitable associated marking device operative for facilitating the emission of marking fluid. It is also to be appreciated that fabricated structure601may also include self-lifting spring fingers600b-cand600e-land could be similarly illustrated. The fabricated structure601includes electrically insulated tether strips616,618layered across release portions600aand600d. A connection point620of tether strips is also known.

The fabricated structure further includes, for example, an aperture plate625a(which may take a variety of forms to accommodate the structure and operation of the marking device) sitting on the tether net structure or at least on the higher set of tethers if they do not end as being co-planar. The fabricated structure further includes a structure for a supporting aperture plate625b(which also may vary in configuration). For ease of illustration, the operative plate and supporting structure are not shown inFIG. 6A. The tethers can contact each other when tips are relaxed to form an interlocking structure either mechanically or by bonding of tethers at cross points.

It should be appreciated that the spring fingers and associated structures take substantially the same form and operate in substantially the same manner (except where noted) in all of the embodiments described inFIGS. 2A-8.

Similar structures can be made on small scale using silicon micro-fabrication processes. The preferred embodiment uses glass, plastic, printed circuit board or co-fired ceramic substrates and large area photo-lithographic or soft-lithographic processes, and combinations thereof.

In another embodiment,FIG. 7illustrates a shaped tip for self-lifting spring finger700. The self-lifting spring finger as previously described above inFIGS. 1-6may include a shaped tip. The self-lifting spring finger700generally includes a shaped tip702Ta that can be positively charged so that tip702TaP located at the distal end of a release portion of the self-lifting spring finger700holds and can emit agglomerated positively charged pigment particles730. The shapes of the tip may include convex shapes such as a circle, triangle, square, rectangle, parallelogram, trapezoid, rhombus, octagon, pentagon, and hexagon, and combinations thereof, as well as re-entrant structures as exemplified by fountain pen nibs or tips. The tip202T is shaped accordingly to enhance capillary definition of agglomerated positively charged pigment particles allowing for emission of ink or marking fluid in, for example, a device for electrostatic extraction of pigmented ink for marking. The fabricated structures as previously described above may be precisely patterned and self-assembling.

In another embodiment, clawjet fingers having a more vertical orientation at the tip may be preferred over more circular fingers at 90 degrees as has been described thus far. The concept is simple and can be implemented without added mask count.

During the sputtering, one applies a balancing counter-moment load layer over the stress-gradient layer. This allows later creation of an end portion of the spring with very large radius. The base segment will bend tightly. At metal definition, all layers are etched down to the release layer. At the release stage, release window photo resist defines the spring base and additional resist over the end segment protects the end from a separate etch bath that removes the counter-moment material from the base-segment prior to release etch. The base-segment is designed to bend to 90 degrees, whereupon the end-segment extends vertically to a designed height.

With respect toFIGS. 8A and 8B, an alternative method may include using a non-stressed layer to define the self-lifting spring finger300within the fabricated structure301. The fabricated structure301would further include layer350. The layer350may comprise at least one of a stressed metal or a second material (with built-in uniform stress) which acts like a bimetallic strip, patterned to overlie the self-lifting spring finger300at a position to provide the bending torque where it is needed.

This idea permits adjacent tips with varied height without varied angle. For example, one could make structures that can tune the drop size over a wider range by adjusting the potentials on the adjacent varied-height emitters. The concept may work with single segment beams, however, the angle and height will both vary with varied finger length.

In this regard,FIG. 9illustrates a structure for a finger with a vertical terminating segment. The fabricated structures as previously described may include a counter moment layer processed onto the end of the spring to create a vertical segment. The vertical terminating segment800generally includes a release layer802, an insulating layer804, a self-lifting spring806, a counter moment layer808, an open window mask810, an end window mask812, and a tip mask814.

If one requires a strong rigid shaft that is structurally reinforced with thick plated metal, terminated by a lithography-limited sharp tip, this can be done without added mask count (e.g., still two levels). This can potentially make an excellent field concentrating structure that can withstand considerable amounts of fluid flow.

Long springs that bend to 90 degrees or more tend to become floppy, but plating can stiffen the structure. To avoid blunting the emitter section one would like to plate everywhere except the tip. Recent developments show how to adhere stress metal to plastic. It is proposed here to create a lifting cantilever that takes along a bottom layer of flexible insulator such as polyimide. The first metal mask is used to define both the metal and the bottom insulator down to the release layer as shown inFIG. 9. At release window definition, a terminating cap of insulating resist is placed over the tip. The cap lifts with the finger. The entire structure is then batch-plated. Plated metal goes only onto the top and sides of the base segment of the spring. The resist is then stripped, leaving behind a structure with strong, rigid emitters with sharp tips. The bottom insulator can also be stripped from the springs at this point if it interferes with the operation of the device.

While the fabricated structure(s) have been described in terms for use with any suitable associated marking device, it is also contemplated that the structure(s) may find use in forming the known system100as illustrated inFIGS. 1A and 1B. That is, the fabricated structure(s) may be suitable for use in improving current technology using high quality and high speed printing. The fabrication schemes may allow batch fabrication and excellent printing characteristics. The planar batch-fabricated process may be beneficial since current technology requires well defined electrostatic field concentrators (tips) that can be precisely and uniformly positioned relative to each other. The fabricated structure may include tips having internal structures and overall shapes to optimize capillary and electrostatic forces. In this regard, the structures of the presently described embodiments can be used to provide suitably and/or selectively positioned nibs or tips so that ink or pigment particles can be extracted according to various known techniques.