|Publication number||US3656171 A|
|Publication date||Apr 11, 1972|
|Filing date||Dec 8, 1970|
|Priority date||Dec 8, 1970|
|Also published as||CA940192A, CA940192A1, DE2159819A1, DE2159819B2|
|Publication number||US 3656171 A, US 3656171A, US-A-3656171, US3656171 A, US3656171A|
|Inventors||Robertson John A|
|Original Assignee||Mead Corp|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (3), Referenced by (50), Classifications (10), Legal Events (2)|
|External Links: USPTO, USPTO Assignment, Espacenet|
United States Patent Robertson [451 Apr. 11, 1972 54] APPARATUS AND METHOD FOR 3,416,153 12/1968 Hertz et a1. ..346/75 SORTING PARTICLES AND JET PROP 3,596,275 7/1971 Sweet ..346/75 x RECORDING John A. Robertson, Chillicothe, Ohio Assignee: The Mead Corporation, Dayton, Ohio Filed: Dec. 8, 1970 Appl. No.: 96,083
U.S. Cl. ..346/l, 209/127 R, 239/15, 317/3, 346/75 Int. Cl. ..G01d 15/18 Field of Search ..346/1, 75, 140; 239/3, 15; 209/127 R, 127 C, 3; 178/6.6; 317/3 References Cited UNITED STATES PATENTS Fulwyer ..20 9/127 R X Primary Examiner-Joseph W. Hartary Attorney-John W. Donahue [5 7] ABSTRACT Apparatus and method for sorting a spaced progression of particles by selectively applying electrical charges and then subjecting the particle progression to the influence of an electrically conductive surface. Each charged particle in progression past the conductive surface induces thereon a sheet of electri-v cal charge and this sheet in turn causes lateral displacement of the inducing particle. There is further disclosure of jet drop recording apparatus employing sheets of self-induced electrical charge for sorting fluid marking drops into print and no-print trajectories.
20 Claims, 5 Drawing Figures PATENTEDAPRH I972 3,656,171
SHEET 1 or 2 PP/OP A PT IN VENTOR. JOHN A ROBERTSON BY Mn (JJDWAJML PATENTEDAPR n 1912 SHEET 2 BF 2 FIG. 4
JOHN A. ROBERTSON ATTORNEY APPARATUS AND METHOD FOR SORTING PARTICLES AND JET PROP RECORDING BACKGROUND OF THE INVENTION This invention relates generally to particle sorting apparatus of the type wherein the particles are projected through space in a spaced progression and are selectively displaced laterally in accordance with electric charges impressed thereon. Typical prior art devices of this type are shown in Fulwyler US. Pat. No. 3,380,584 and Sweet et al. US. Pat. No. 3,373,547; the former sorting particles in accordance with distinctive particle characteristics and the latter sorting in accordance with variations in a corresponding input intelligence signal. Both of these prior art devices work with liquid particles and both accomplish lateral displacement of the particle by creating a steady state electrical field. The lateral accelerating force in these systems is proportional to the magnitude of the applied field and to the magnitude of the charge impressed upon the particles.
In the above mentioned prior art devices it is necessary to isolate the particle (drop) forming region from the deflection field in order to avoid inducing spurious charges in the drops. This isolation may be provided by space along in a relatively large sorting device or by a separate guard electrode. As an alternative one may provide compensation in lieu of isolation. In either event the remedy becomes more difficult with decreasing size and with an increasing number of channels.
Another disadvantage of the prior art which is present in multiple channel configurations is that of crosstalk between channels. Consider for example a sorting device having two channels each of which operates in a maximum-charge/zerocharge binary mode. If a particle in one channel is supposed to be uncharged but actually receives say percent of a maximum charge because of crosstalk from the adjacent channel, then the spuriously charged particle will be deflected 10 percent of the full scale catch deflection. This is an error which could not be tolerated in a precision recording process.
SUMMARY OF THE INVENTION This invention overcomes the disadvantages of the prior art by eliminating the steady state deflection field and accomplishing particle deflection by a self-induced deflection field. Each charged particle sets up its own deflection field and is enabled to do so by an electrically conductive surface placed near the particle path. Depending upon the configuration and position of the conducting surface, there is set up thereon a sheet of electrical charge having a distribution which may be determined by using known field theory techniques. This sheet of induced charge is opposite in sign to that of the inducing charge and has an associated electrical field which attracts the charged particle toward the conductive surface. In this regard it is essential that the self-induced electrical field have a net resultant lateral component along the base non-perturbed particle path. The consequence of this requirement is a corollary requirement that the configuration of all conducting surface area influencing the charged particles have no plane of symmetry passing through the base particle path. In other words, if the conductive surface is a plane parallel to the base path, there may be no similar plane equidistant on the other side of the base path; otherwise there will be a cancellation effect and no net resultant induced deflecting field. Similarly, if the conductive surface is a cylinder, it may have its axis parallel to the base particle path but not colinear therewith.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic representation of a single channel particle sorting apparatus which charges liquid particles on a binary basis and employs self-induced electrical fields to segregate charged particles from uncharged particles.
FIG. 2 is a diagrammatic illustration of the distribution of actual and image charges induced in a conductive wall due to the presence of a nearby charged particle.
FIG. 3 is a schematic illustration of a typical prior art fluid drop recording apparatus.
FIG. 4 is a schematic representation, partially in section, of a printing head using a common conductive surface for self-induced deflection of a linear array of charged drops.
FIG. 5 is a schematic representation of a particle sorting apparatus employing self-induced deflection for fluid particles generated in a circular array.
DESCRIPTION OF PREFERRED EMBODIMENTS The preferred embodiment of the present invention is shown schematically in FIG. 1 wherein a conductive fluid 1 flows through an orifice 2 in an electrically conductive plate 3 forming a filament 4 and thereafter breaks up into drops 5, 5a; some of which 5a are caught by catcher 6. The fluid is forced through orifice 2 under pressure and is stimulated to break up into uniformly sized and regularly spaced drops by a constant frequency oscillating transducer (not shown) in communication with the orifice assembly or fluid supply. An electrically conductive charge strip 7 is positioned adjacent filament 4 and is connected to one side of a source of electric potential 8. The other side of source 8 is connected to plate 3 for control of the potential of filament 4. Alternatively, in the case where the orifice plate 3 may be non-conductive, source 8 may communicate directly with fluid 1. In either event source 8 produces a potential difference between strip 7 and filament 4 in response to a control signal applied to input terminals 9. As is well known in the art, this potential difference causes electrical charges to appear on filament 4, and some of this charge is carried away by the drops when they separate. Drops 5a carry such a charge and follow a curved trajectory 10 as shown. Drops 5 are uncharged due to a zero magnitude signal having been present at input terminals 9 at the respective instants when those drops separated from filament 4. Drops 5 follow a straight trajectory 1l.
Drops 5a are deflected to follow trajectory 10 by self-induced attraction to conductive deflection strip 12. Normally strip 12 will be grounded and mounted on an insulated wall 13. A vacuum source (not shown) is connected to porous plate 14 and draws off drops 5a as they are caught by catcher 6.
As is subsequently explained, the attractive force operating on any drop 5a is inversely proportional to the square of the distance between the drop and strip 12. Therefore, it is desirable to position strip 12 very close to filament 4. At the same time, however, it is desirable that trajectory l0 curve back far enough to guarantee a clean catch for drops 5a. This means that the lower portion of strip 12 ought to be positioned relatively far away from trajectory 11. These somewhat conflicting requirements can both be satisfied by angling or tilting strip 12 back away from the drop stream as illustrated in FIG. 1. Typically, the tilt angle may be about 2.5". Associated with this tilt angle would be a drop mass of about 6.2 X 10 kg., a drop diameter of about 23 microns, a drop velocity of about 9 meters per sec, a deflection strip length of about 1.25 mm, and a total distance of about 2.5 mm from the orifice plate to the catcher. The distance between filament 4 and charge strip 7 would be about 25 microns and the potential difference about 200 volts. This in turn will produce a drop charge of about 10' coul. and a drop deflection of about 56 microns or about 2.5 drop diameters. Thus, it is seen that this invention finds utility primarily in very small devices.
The operation of the deflection strip is best understood by reference to FIG. 2 wherein a charged drop 15 is falling past a conductive wall 16. Drop 15 is assumed to carry a negative charge which distributes itself about the drop surface as at 17. In general the negative charge distribution will be somewhat more dense on the side of the drop facing wall 16.
It is well known that when an electrical wall is placed near a conductive surface, there is induced on that surface a distributed charge of opposite sign. Thus positive charges 18 are distributed along the surface of wall 16 as shown, with the charge density greatest in the area nearest drop 15. Lines 19 represent the electric field set up between drop surface charges 17 and wall surface charges 18. This field intersects the wall surface everywhere at right angles. The wall 16, being a conductor, is a volume of constant potential, and therefore there is no electrical field within the wall interior. The total electric field as illustrated in FIG. 2 is the sum of the applied field of the charges 17 and the induced field of the charges 18.
This invention depends for its operation upon the force exerted against drop 15 by the induced field of charges 18. This force can be calculated by assuming charges 17 to be concentrated at a point within drop 15 and summing the incremental forces exerted against this concentrated charge by the distributed charges on each elemental area of the surface of wall 16. Unfortunately the resulting surface integral cannot be solved without knowledge of the distribution of charges 18. In the general case (including conducting walls of various shapes) this distribution can be determined only by solving a very involved boundary value problem. It can be shown, however, that distributed charges 18 may be replaced (for mathematical purposes) by image charges 21 arranged around the surface of an image drop 20. See for instance a discussion on the theory of images in the book Electromagnetic Theory by J. A. Stratton, McGraw-Hill Book Company, Inc., 1941 at Sec. 3.18. Making this replacement and applying Coulombs law to the resulting charge configuration, one finds the force on drop 15 to be given approximately by the equation:
F=( l/41re,,) (Q /(2d) where Q is the total charge on drop 15, e is'the permittivity of air and dis the distance from drop to the surface of wall 16.
The operation of this invention is to be contrasted to the operation of a prior art system as illustrated in FIG. 3. There a supply of conductive fluid 22 is forced under pressure through a nozzle 23 to form a filament 24. Vibrator 25 stimulates filament 24 to break up into uniform regularly spaced drops 26 ,26a which are either caught by catcher 27 or deposited on receiving member 28. Drops 26 are uncharged while drops 26a are charged due to an appropriately timed potential difference applied between charge tunnel 29 and filament 24. The required potential difference is produced by source 30 under control of a signal applied at terminals 31.
The force which the illustrated prior art system requires to sort charged drops 26a from uncharged drops 26 is provided by a pair of deflection plates 32. Fixed potential source 33 is connected to create a potential difference between plates 32 and this in turn produces a force exerting electric deflection field. Comparing this with the present invention, it will be appreciated that each charged drop 26a will see an oppositely charged image drop in each plate 32 which may or may not provide a non-negligible self-induced deflecting force, depending upon the distance from the drop to the plate. Such a force would be in addition to the force exerted by the steady state deflection field. However, any such self-induced deflection force is balanced out, at least initially, by a similar force attracting the drop to the other plate. This cancellation of selfinduced deflection forces will occur in any case wherein the configuration of electrically conductive surfaces influencing the drops is symmetrical with respect to the base or nondiverted particle path. In the practice of the instant invention the electrically conductive surface means has a non-symmetrical configuration with respect to the initial or non-diverted particle path, and there is no cancellation of the self-induced deflection forces. Thus a particle sorting device made in accordance with the present invention requires no steady state electrical field for deflection of the charged particles.
A printing head 34 embodying the present invention is illustrated in schematic cut-away form in FIG. 4. This embodiment has a row of orifices 43 in an orifice plate 35 bonded to the under side of an ink supply manifold 36. Bonded to the lower side of the orifice plate are insulative support blocks 37 and 38. A catching blade 40 is bonded to a porous plate 39, and the porous plate in turn is bonded to support block 37. A series of charge strips 41 are arranged to charge the ink filaments which issue from orifices 43, and a common conductive deflection plate 42 enables self-induced deflection of all charged drops. The required pressure source, vacuum source,
stimulation transducer, and electrical potential source are all connected as previously described.
The drawing of FIG. 4 is not to scale as the distance from each orifice 43 to its associated charge strip 41 is in actuality much less than the distance between adjacent orifices. Typically the orifice-to-orifice distance may be about 0.1 mm while the orifice-to-charge strip distance may be about 0.025 mm. Associated with these dimensions may be an orifice diameter of about 0.013 mm and a charge strip width of about 0.05 mm. Other system parameters may be as mentioned above in the discussion for the single channel illustrated in FIG. 1. Deflection plate 42 and charge strips 41 may be easily fabricated by well known printed circuit techniques. Head 34 may be used in combination with three similar heads to provide solid printing coverage. In such a combination the heads are arranged in a staggered fashion and time coordinated in the manner described in pending US. Pat. application Ser. No. 768,790, now US. Pat. No. 3,560,641. Such an arrangement will provide a highly precise printing capability with the orifices located only about a quarter centimeter away from the paper.
The system as above described with reference to FIGS. 1 and 3 achieves an initial lateral drop acceleration of about 5,600 meters per sec. which is sufficient to displace the drops a distance of about 2.5 diameters (56 microns) during a vertical fall of only 1.25 mm. For particle sorting applications wherein vertical distances need not be so short, then the electrically conductive deflection surface may be vertically extended to a length of about 5 mm or so. In such a case the same 2.5 diameter drop deflection may be achieved with a lateral acceleration of only about 350 meters per sec. This reduction in the acceleration requirement enables reduction of the self-induced deflecting force by a factor of 16 and a 75 percent reduction of charging potential from 200 volts to 50 volts.
From the foregoing it is apparent that the total deflection of particles in an array built in accordance with the present invention is proportional to Q However, due to the presence of adjacent channels it is more accurate to state that the total particle deflection is proportional to (Q (3) where 8 is a crosstalk charge. In a typical closely packed array 5 may be 10 to 20 percent as large as Q. Now for an array adjusted to have the same sensitivity but built to have its particles sorted by prior art methods, the total deflection of a particle is proportional (with the same proportionality constant) to the factor Q (Q 8) where Q is the nominal maximum value for Q. For a particle sorting process where all nominally charged particles are caught and only the nominally uncharged particles are recorded, the only error of interest is that associated with zero values of Q. In such a case the present invention has a crosstalk error proportional only to 8 whereas the prior art sorting method produces an error proportional to Q 5. Thus this invention achieves a substantial reduction in crosstalk errors.
An alternative embodiment of this invention is shown in FIG. 5 wherein a group of orifices 45 are circularly arranged in an orifice plate 44 and discharge a set of fluid filaments 46 through a conductive cylindrical tunnel 47. Tunnel 47 is electrically insulated from plate 44 and a source of pulsed electrical potential (not shown) is connected therebetween. During periods of time when the input potential is zero all drops breaking off from the ends of filaments 46 are uncharged and follow straight trajectories passing through a circular aperture in base plate 49. However during periods of non zero potential (typically 200 volts) all newly forming drops are charged. 11- lustrated drops 48 were all formed during periods of non-zero charging potential. As these drops fall away from their filaments they induce sheets of electrical charge on the inside surface of tunnel 47. Since none of the filaments 46 is located along the axis of tunnel 47, each drop 48 sees an electrically conductive surface which is laterally non-symmetrical with respect to its initial trajectory. Accordingly each drop 48 is accelerated laterally outward toward the inner wall of tunnel 47, but it leaves the end of the tunnel before hitting the tunnel wall. Drops 48 maintain the lateral velocity which they achieve before leaving tunnel 47 and this lateral velocity carries them outward beyond upstanding lip 50 on base plate 49. Having thus been caught, they may be drawn off by a suitable source of vacuum.
It is interesting to note that in this embodiment a single conductive surface performs both the charging and deflection functions. As each drop forms it sees the electrical charging field set up between tunnel 47 and the parent filament 46. However, this field is largely confined to the upper end of tunnel 47, and the only really significant field which the drop sees for most of its journey down tunnel 47 is that which is self induced by the drop. It shouldbe clear that dual function operation is not peculiar to a cylindrically configured conductive surface. In the embodiment of FIG. 1, for instance, charging strip 7 could be extended to meet deflection strip 12 without affecting the operation of the single illustrated channel.
What is claimed is:
1. In a particle sorting apparatus comprising means for producing a progression of uniformly sized and regularly spaced particles, means for coding the progression of particles by selective impressment of a predetermined electrical charge on only some of said particles, and means for switching the charged particles into a diverted trajectory; the improvement wherein said last named means comprises electrically conductive surface means of laterally non-symmetrical configuration with respect to the initial trajectory of said particles.
2. The improvement of claim 1 further comprising means to catch the diverted particles and means to produce a visual trace of the non-diverted particles.
3. The improvement of claim 1 said electrically conductive surface being tilted in the direction of the diverted trajectory.
4. The improvement of claim 1 said electrically conductive surface means being configured and positioned to carry in response to an electrical charge impressed on a particle as aforesaid a sheet of induced electrical charge of sufficient magnitude to attract said particle away from its initial trajectory with a lateral acceleration of at least 350 meters per sec. per sec.
5. Recording apparatus comprising particle sorting means and means to produce a visual record of particles sorted by said sorting means; said sorting means comprising:
1. means for projecting a series of particles in a spaced progression,
2. means for applying an electrical charge to selected particles in said progression, and
3. an electrically conductive surface positioned near the path of said progression and configured to enable nearby charged particles to induce thereon sheets of electrical surface charge of distribution and strength for displacing the inducing particles into laterally sorted trajectories.
6. Fluid drop marking apparatus comprising:
a. means for generating a stream of uniformly sized and regularly spaced fluid marking drops,
b. means for inducing various electrical charges on said marking drops in correspondence with variations in an input marking control signal,
c. an electrically conductive deflection surface adjacent the path of said stream, said surface being positioned and configured whereby the sheet of electrical charge induced thereon in response to a charge on a nearby marking drop produces a lateral deflection field for the inducing drop,
d. means for catching marking drops deflected laterally into a predetermined region by the action of said deflection field, and
e. means for supporting a mark receiving member in position for deposition thereon of marking drops not deflected into said predetermined region.
7. Apparatus according to claim 6 said means for generating a stream of uniformly sized and regularly spaced fluid marking drops comprising:
a. a nozzle for dispensing said stream of markingdrops,
b. means for supplying marking fluid to said nozzle under sufficient pressure to create a continuous fluid filament at the exit side of the nozzle, and
c. stimulation means for applying a constant frequency drop generating disturbance to said continuous fluid filament. thus urged 8. Apparatus according to claim 7 said electrically conductive surface being tilted away from the path of said stream in the direction of drop deflection.
9. Apparatus according to claim 7 said electrically conductive surface extending upwardly into the region where said fluid filament breaks up into drops, and said means for creatingan electrical field comprising means for establishing an electric potential difference between the conductive surface and the fluid filament.
10. Apparatus according to claim 9 said electrically conductive surface being a surface of revolution with its axis parallel to the path of said stream and offset therefrom.
11. Apparatus according to claim 7 said deflection surface being at the same electric potential as the fluid filament and said means for creating an electrical field comprising:
a. a charging electrode, and
b. means for establishing an electric potential difference between the charging electrode and the fluid filament.
12. Apparatus for fluid drop recording without a steady state deflection field comprising:
a. a plurality of like nozzles,
b. means for supplying marking fluid from a common fluid supply to said nozzles under sufficient pressure to create a plurality of parallel like continuous fluid filaments at the nozzle exits,
0. means for applying a constant frequency drop generating disturbance to all of said filaments and thereby producing a plurality of parallel streams of uniformly sized and regularly spaced marking drops,
d. means responsive to an input marking control signal for selective impressment of a predetermined electrical charge on some of said drops; all other drops being uncharged,
e. means for producing along the path of each charged drop a laterally deflecting self-induced electrical field,
f. means for catching all drops laterally deflected as aforesaid, and
g. means to produce a visible trace of the non-deflected drops.
13. Fluid drop marking apparatus according to claim 12 said means for producing a laterally deflecting self-induced electrical field for each charged drop comprising a common electrically conductive surface positioned near all of said streams and configured whereby the sheets of electrical charge induced thereon in response to the charges on nearby drops each produce a resultant lateral electrical field in the region of the sheet inducing drop.
14. Fluid drop marking apparatus according to claim 13 said nozzles being arranged along a straight line.
15. Fluid drop marking apparatus according to claim 14 the induced sheets of electrical charge each being of sufficient magnitude to attract the inducing particle away from its initial trajectory with a lateral acceleration in the order of about 5,600 meters per sec. per sec.
16. In a particle sorting process comprising the steps of:
l. projecting a series of particles in a spaced progression,
2. applying an electrical charge to selected particles in said progression, and
3. deflecting the charged particles laterally by the action of an electrical field;
the improvement wherein the charged particles are subjected to the influence of an electrically conductive surface for self generation of said electrical field.
17. Method of recording an image comprising the stepsof:
l. producing a bi-level control signal representative in time of the information content of an image to berecorded,
2. producing a progression of uniformly sized and regularly spaced particles of marking material,
3. applying an electrical charge of predetermined magnitude to all of said particles produced while said control signal is at one of its levels; all particles produced while the control signal is at the other of its levels being given no electrical charge,
4. directing all of said particles through a region of influence of an electrically conductive surface for deflection of charged particles by self induced deflection fields,
5. catching the particles deflected as aforesaid, and
6. moving a recording surface through the path of the uncharged and undeflected particles for deposition thereon of said uncharged particles.
18. Method according to claim 17 said step of producing a progression of uniformly sized and regularly spaced particles of marking material comprising the further steps of:
l. producing a filament of fluid marking material, and
2. generating said particles by applying a constant frequency disturbance to said filament.
19. Method according to claim 18 said step of applying an electrical charge to said particles comprising the step of establishing an electric field of predetermined strength in the region of the tip of said filament when the control signal is at its first mentioned level.
20. Method according to claim 19 said self-induced deflection fields being of strength for initial lateral acceleration of the inducing drops in the order of about 5,600 meters per sec. per sec.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US3380584 *||Jun 4, 1965||Apr 30, 1968||Atomic Energy Commission Usa||Particle separator|
|US3416153 *||Oct 6, 1966||Dec 10, 1968||Hertz||Ink jet recorder|
|US3596275 *||Mar 25, 1964||Jul 27, 1971||Richard G Sweet||Fluid droplet recorder|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US3709432 *||May 19, 1971||Jan 9, 1973||Mead Corp||Method and apparatus for aerodynamic switching|
|US3776461 *||Oct 4, 1971||Dec 4, 1973||Casio Computer Co Ltd||Nozzle device for ink jet printing equipments|
|US3871004 *||Jun 26, 1974||Mar 11, 1975||Olympia Werke Ag||Ink drop writing head|
|US3905550 *||Jun 6, 1974||Sep 16, 1975||Sota Inc De||Avoidance of spattering in the supply of conductive liquids to charged reservoirs|
|US3941312 *||Feb 28, 1975||Mar 2, 1976||Research and Development Laboratories of Ohno Company Limited||Ink jet nozzle for use in a recording unit|
|US3958959 *||Aug 5, 1974||May 25, 1976||Trw Inc.||Method of removing particles and fluids from a gas stream by charged droplets|
|US4068241 *||Nov 30, 1976||Jan 10, 1978||Hitachi, Ltd.||Ink-jet recording device with alternate small and large drops|
|US4223321 *||Apr 30, 1979||Sep 16, 1980||The Mead Corporation||Planar-faced electrode for ink jet printer and method of manufacture|
|US4250510 *||Sep 4, 1979||Feb 10, 1981||The Mead Corporation||Fluid jet device|
|US4255777 *||Nov 21, 1977||Mar 10, 1981||Exxon Research & Engineering Co.||Electrostatic atomizing device|
|US4291340 *||Sep 12, 1979||Sep 22, 1981||The Mead Corporation||Jet drop copier with multiplex ability|
|US4324117 *||Jun 11, 1980||Apr 13, 1982||The Mead Corporation||Jet device for application of liquid dye to a fabric web|
|US4347935 *||May 16, 1979||Sep 7, 1982||The United States Of America As Represented By The United States Department Of Energy||Method and apparatus for electrostatically sorting biological cells|
|US4350986 *||Sep 7, 1977||Sep 21, 1982||Hitachi, Ltd.||Ink jet printer|
|US4368475 *||Apr 24, 1981||Jan 11, 1983||The Mead Corporation||Jet drop copier|
|US4419674 *||Feb 12, 1982||Dec 6, 1983||Mead Corporation||Wire wound flat-faced charge plate|
|US4523202 *||Feb 3, 1982||Jun 11, 1985||Burlington Industries, Inc.||Random droplet liquid jet apparatus and process|
|US4550323 *||Jun 7, 1983||Oct 29, 1985||Burlington Industries, Inc.||Elongated fluid jet printing apparatus|
|US4560991 *||Jan 31, 1985||Dec 24, 1985||Eastman Kodak Company||Electroformed charge electrode structure for ink jet printers|
|US4621268 *||Feb 5, 1985||Nov 4, 1986||Keeling Michael R||Fluid application method and apparatus|
|US4629119 *||Jan 26, 1984||Dec 16, 1986||Nordson Corporation||Electrostatic isolation apparatus and method|
|US4636808 *||Sep 9, 1985||Jan 13, 1987||Eastman Kodak Company||Continuous ink jet printer|
|US4644369 *||May 9, 1985||Feb 17, 1987||Burlington Industries, Inc.||Random artificially perturbed liquid jet applicator apparatus and method|
|US4698642 *||Jun 10, 1985||Oct 6, 1987||Burlington Industries, Inc.||Non-artifically perturbed (NAP) liquid jet printing|
|US4854506 *||Dec 21, 1987||Aug 8, 1989||Imperial Chemical Industries Plc||Electrostatic spraying|
|US5021803 *||Sep 27, 1989||Jun 4, 1991||Imperial Chemical Industries Plc||Ink jet parallel cusp producing slot or edge configured nozzle system|
|US5086973 *||Apr 11, 1990||Feb 11, 1992||Terronics Development Corp.||Nozzle modulators|
|US5332154 *||Feb 28, 1992||Jul 26, 1994||Lundy And Associates||Shoot-up electrostatic nozzle and method|
|US7533965||Mar 6, 2006||May 19, 2009||Eastman Kodak Company||Apparatus and method for electrostatically charging fluid drops|
|US8585189||Jun 22, 2012||Nov 19, 2013||Eastman Kodak Company||Controlling drop charge using drop merging during printing|
|US8641175||Jun 22, 2012||Feb 4, 2014||Eastman Kodak Company||Variable drop volume continuous liquid jet printing|
|US8646882||Mar 20, 2012||Feb 11, 2014||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|US8646883||Mar 20, 2012||Feb 11, 2014||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|US8651632||Mar 20, 2012||Feb 18, 2014||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|US8651633||Mar 20, 2012||Feb 18, 2014||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|US8696094||Jul 9, 2012||Apr 15, 2014||Eastman Kodak Company||Printing with merged drops using electrostatic deflection|
|US20060197803 *||Mar 6, 2006||Sep 7, 2006||Steiner Thomas W||Apparatus and method for electrostatically charging fluid drops|
|US20140168322 *||May 25, 2012||Jun 19, 2014||Markem-Imaje||Binary continuous ink jet printer|
|USRE30479 *||May 17, 1978||Jan 13, 1981||Trw Inc.||Method of removing particles and fluids from a gas stream by charged droplets|
|CN103302971A *||Mar 12, 2012||Sep 18, 2013||张爱明||Continuous inkjet sprayer|
|DE2756805A1 *||Dec 20, 1977||Jul 6, 1978||Mead Corp||Schaltungsanordnung fuer einen tintenstrahldrucker|
|DE2850116A1 *||Nov 18, 1978||Jun 7, 1979||Exxon Research Engineering Co||Elektrostatische aufladungs- und zerstaeubungsvorrichtung und verfahren zur elektrostatischen aufladung eines nicht leitenden mediums|
|EP0024955A1 *||Sep 4, 1980||Mar 11, 1981||The Mead Corporation||Fluid jet devices and method of depositing fluid drops|
|EP0196074A2 *||Feb 4, 1982||Oct 1, 1986||Burlington Industries, Inc.||Random droplet liquid jet apparatus and process|
|WO1987001335A1 *||Aug 29, 1986||Mar 12, 1987||Eastman Kodak Company||Print head for continuous ink jet printer|
|WO2012162082A1||May 17, 2012||Nov 29, 2012||Eastman Kodak Company||Liquid ejection system including drop velocity modulation|
|WO2012162354A1||May 23, 2012||Nov 29, 2012||Eastman Kodak Company||Liquid ejection using drop charge and mass|
|WO2013142233A1||Mar 14, 2013||Sep 26, 2013||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|WO2013142451A1||Mar 19, 2013||Sep 26, 2013||Eastman Kodak Company||Drop placement error reduction in electrostatic printer|
|WO2013191959A1||Jun 11, 2013||Dec 27, 2013||Eastman Kodak Company||Variable drop volume continuous liquid jet printing|
|U.S. Classification||347/76, 347/1, 239/690, 209/3, 209/127.1, 361/226|
|Cooperative Classification||B41J2/105, B41J2/185|
|Mar 19, 1984||AS02||Assignment of assignor's interest|
Owner name: EASTMAN KODAK COMPANY A NJ CORP.
Effective date: 19831206
Owner name: MEAD CORPORATION THE A CORP. OF OH
|Mar 19, 1984||AS||Assignment|
Owner name: EASTMAN KODAK COMPANY A NJ CORP.
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:MEAD CORPORATION THE A CORP. OF OH;REEL/FRAME:004237/0482
Effective date: 19831206