United States Patent [1 1 Szymber et a1.
[ 1 Dec. 30, 1975 [75] Inventors: Oleg Szymber, Elk Grove; Anatoli Brushenko, Elmhurst, both of I11.
[73] Assignee: GAF Corporation, New York, N.Y.
[22] Filed: Sept. 5, 1974 [21] Appl. No.: 503,266
[52] US. Cl. 118/637; l18/DIG. 23; 355/10; 427/16 [51] Int. Cl. G03G 15/10 [58] Field of Search 118/637, DIG. 23; 117/37 LE; 355/3 P, 10,427/15, 16
[56] References Cited UNITED STATES PATENTS 3,162,104 12/1964 Medley 355/10 3,196,832 7/1965 Zin ll8/D1G. 23 3,203,395 8/1965 Liller Il8/DIG. 23 3,377,988 4/1968 Zawiski 118/DIG. 23 3,507,252 4/1970 Leedom 118/637 3,547,076 12/1970 Saklikar 1l8/DIG. 23 3,557,752 1/1971 Hakanson 118/637 3,608,523 9/1971 Jeffrey et a1. 118/637 3,651,782 3/1972 MacDonald, Jr. 118/637 3,753,393 8/1973 Niesen et a1. 118/D1G. 23
3,791,345 2/1974 McCutcheon l18/DIG. 23
Primary Examiner-Mervin Stein Assistant Examiner-Douglas Salser Attorney, Agent, or Firm- Walter C. Kehm; Arthur Dresner [57] ABSTRACT An apparatus for the development of latent electrostatic images on dielectric sheeting includes a developing electrode surface for receiving the sheeting. In accordance with this invention, toner fluid is circulated across the electrode surface, typically in a generally unidirectional flowing stream. The sheeting is supported by the stream of toner fluid, whereby the sheeting is spaced from the developing electrode surface in automatic, uniform manner by the stream of toner fluid, for improved toning development of latent electrostatic images. In another aspect of this invention, toner fluid is supplied to flow in a stream across the developing electrode surface through several fluid inlets, including at least one central fluid inlet, and several spaced toner fluid outlets are also provided, so that fresh toner fluid may be continually dispersed in a large area across the developing electrode surface, and spent toner fluid withdrawn, in a staged manner of flow.
Claims, 5 Drawing Figures U.S. Patent Dec. 30, 1975 Sheet 1 of2 3,929,099
ELECTROSTATIC IMAGING TONING DRYING TONER APPARATUS FOR ELECTROPHOTOGRAPHIC DEVELOPMENT BACKGROUND OF THE INVENTION In various well-known Transfer of Electrostatic Image (TESI) processes, and the like, an electrostatic charge pattern corresponding to a desired image is impressed on dielectric sheeting, such as conventional coated paper, in any well-known manner. This electrostatic or latent image is quite stable, and may be retained for a matter of minutes, or even hours or days, but is, of course, invisible to the eye.
Accordingly, in TESI and similar processes, after an electrostatic image has been impressed upon dielectric sheeting, the sheeting is passed through a toner apparatus to cause particles of carbon black or the like to adhere selectively to the areas of electrostatic charge on the dielectric sheeting, without adhering to the electrostatically neutral areas of the sheeting.
A large number of toner device designs for developing latent, electrostatic images exist; a few of these being disclosed in U.S. Pat. Nos. 3,202,526; 3,203,395; 3,627,410; and 3,651,782.
The basic principle involved in many toner apparatus is to place the electrostatically-imaged dielectric sheet in proximity to a developing electrode surface. Simultaneously, toner fluid is circulated across the dielectric sheet, to cause the pigment particles of the fluid to adhere to the electrostatically-charged image areas. Thereafter, the dielectric sheet is dried, to permit a binder agent such as a resin to cause the pigment to permanently adhere to the dielectric sheet.
Significant problems have existed in the prior art, which have restricted the utility of fluid toner devices as a means of developing dielectric sheets having latent electrostatic images. First, during the development process, the electrostatic sheet is desirably precisely and uniformly spaced from the developing electrode, yet with room for toner solution to circulate between the dielectric sheet and the developing electrode surface. Generally, the prior art has not provided a satisfactory solution for accomplishing this.
Also, the toner solution in use is quickly depleted of pigment particles. If the spent toner solution is permitted to continue to circulate in the presence of the electrostatic image on the dielectric sheet, it. will begin to wash away pigment particles which have already been deposited on the electrostatic image, resulting in a poor, smeared image on the dielectric sheet.
In accordance with this invention, the above problems are effectively eliminated, resulting in toner apparatus which can reliably provide uniformlytoned electrostatic images, thus providing an effective toner module for a photocopying system using the TESI principle, or other related systems.
DESCRIPTION OF THE INVENTION In one aspect, the apparatus of this invention utilizes a generally flat developing electrode surface for receiving dielectric sheeting. Typically, the electrode surface acts as a ground in order to intensify the electric field in the toning region. Means are provided for circulating toner fluid across the developing electrode surface in a unidirectional, flowing stream. Means are also provided for laying the sheeting on the flowing stream of toner fluid, so that it in effect floats on the flowing stream. As a result of this, the sheeting is spaced from 2 the developing electrode surface in automatic, uniform manner by the stream of toner fluid, utilizing the selfregulating thickness of the fluid stream for improved development of latent electrostatic images.
While not wishing to be restricted to any particular theory of operation of this invention, it is believed that the well-known Bernoulli Effect exhibited by flowing streams in enclosed flow conditions is an important principle utilized by this invention. Basically, the Bernoulli Effect is based on the fact that the pressure of an enclosed flowing stream of fluid is inversely related to the velocity of that stream. As a result, referring to the unidirectional flowing stream of toner across the electrode surface, the dynamics of the flowing stream between the electrode surface and the sheeting results in a self-regulating uniformity of fluid stream thickness. Accordingly, the dielectric sheet will be uniformlyspaced from the electrode surface as it floats on the stream of fluid.
In another aspect of this invention, toner fluid staging means are provided, comprising means for simultaneously supplying fresh toner fluid to flow in a stream across the developing electrode surface from several, spaced toner fluid inlets, including at least one central fluid inlet which is spaced from the ends of the electrode surface. Means are also provided for simultaneously withdrawing spent toner fluid from the electrode surface at several, spaced fluid outlets. One of the fluid outlets positioned adjacent the above central fluid inlet. As a result of this, fresh toner fluid may be continually dispersed in large areas across the electrode surface, for contact with the dielectric sheeting,
' circulating across the electrode in two or more stages or circulating flow paths. This can be utilized to prevent the smearing problem previously encountered when spent toner. fluid is allowed to remain in contact with the dielectric sheeting too long.
Preferably, the developing electrode surface is, as stated above, flat and, in position of use, defines a small angle to the horizontal plane in a direction to permit a unidirectional stream of toner fluid to flow downwardly atthe angle selected. The angle is preferably about 5 to 20 from the horizontal plane. While the electrode surface may be electrically charged in some circumstances,excellent results are achieved with un-' charged electrode surfaces that are grounded.
The toner fluid staging means described above preferably definesthree or more separate, spaced fluid inlets for supply of fresh toner fluid to the developing electrode surface', and a corresponding number of separate, spaced fluidoutlets for spent toner fluid. These are arranged to provide at least three successive, generally separate toner fluid flow paths across the electrode surface, so that the dielectric sheeting is continuously in contact with fresh toner fluid.
Preferably, the stream of toner fluid is pumped across the developing electrode surface in such quantity that the uniform depth of the stream across the developing electrode surface is from about 0.5 to 2 millimeters. For the developing electrode specifically disclosed in the drawings below, which may be 11 inches wide, and has interconnecting fluid inlets of uniform dimension, to provide an essentially equal flow rate through each of the fluid inlets, a total toner fluid flow rate of about 3,600 ml. per minute has been found to be suitable.
A suitable toner fluid for use with this invention is LP 2770, sold by the GAP Corporation of Wayne, NJ. This toner fluid comprises carbon pigment in a hydrocarbon solvent and a dissolved resin binder.
Referring to the drawings,
FIG. 1 is a schematic illustration of a basic set of steps involved in the preparation of photocopies from an original or negative transparency by means of a transfer of electrostatic image process or the like.
FIG. 2 is an elevational view of a toner module device incorporating the invention of this application, with some parts removed for clarity.
FIG. 3 is a sectional view taken alongLine 33 of FIG. 2, showing the relationship of electrostaticallyimaged dielectric paper, and showing contact electrode means on the back side of the electrostatically-imaged paper.
FIG. 4 is an enlarged, sectional view taken along Line 4-4 of FIG. 2.
FIG. 5 is an enlarged, plan view, with portions partially broken away, of the developing electrode surface of the toner module of FIG. 2.
Referring to FIG. 1, the series of process steps typically accomplished in transfer of electrostatic image reproduction is shown. An electrostatic image corresponding to a visual image in a transparent negative or the like is prepared by any conventional process involving the transfer of an electrostatic image, typically from a photoconductive electrode across an air gap no larger than several microns to a sheet of paper coated with a dielectric material. Such coated papers are available from the Weyerhauser Company as Type M dielectriccoated paper, or may be made in accordance with US. Pat. No. 3,519,819.
The coated papers, after receiving an electrostatic image, are toned by being brought into contact with liquid toner in accordance with this invention, and are thereafter sent through a pair of squeegee rollers and briefly heated in a conventional manner to dryness, to produce permanent photocopies of the original transparent negative.
Referring to FIGS. 2 through 5, a toner device of this invention is shown, which may be incorporated as a module into a complete device, which incorporates the electrostatic imaging, toning, and drying functions in a single operation.Toner device 10 comprises a sheet metal member defining a flat, developingelectrode surface 12 for receivingpaper sheeting 14 having a conventional dielectric surface (a fragment of which is shown in FIG. 2).Sheeting 14 may be advanced into proximity with developingelectrode surface 12 through a pair ofrollers 16, so that sheeting l4 rests above the developingelectrode surface 12, being supported by a stream of toner fluid in a manner described below.Sheeting 14 then is advanced through a second pair ofrollers 18, which may function as squeegee rollers for the drying step, if desired.
Developingelectrode surface 12 is flat to facilitate improved uniformity of spacing ofsheet 14 fromsurface 12, for the improved results which may be obtained by this invention.Electrode surface 12 is supported byreceptacle 20 at a slight angle of about 5 to 20 from the horizontal (shown in this embodiment to be about 10 to 15) to facilitate the flow of toner fluid acrosselectrode surface 12.
Receptacle constitutes a fluid tight container for a supply of toner fluid, which may be added or removed throughscalable inlet 22, having sealingplug 24.
Fluid pump motor 26 is provided to pumptoner fluid 28, which is stored in the bottom ofreceptacle 20, throughconduit 30 to developingelectrode surface 12,
where it flows in a broad stream 31 (FIGS. 4 and 5), which is-of generally uniform thickness (with the exception of the inlet and outlet areas to be described below), to uniformly supportsheet 14 on a uniform, generally unidirectionally flowing stream of toner fluid, for uniform toning of the underside ofdielectric sheeting 14.
Referring in particular to FIG. 5, tonerfluid inlet conduit 30 may be seen at its position where it joins developingelectrode surface 12.Branch inlet channels 32, 33 pass underneathelectrode surface 12 for distribution of toner fluid across the surface. Toner fluid enters said surface fromchannels 32 at three different, spaced zones through a plurality ofinlet ports 34, 36, and 38, which pass through sheetmetal electrode surface 12. Accordingly, several spaced fluid inlets are provided for supply of fresh toner fluid to the developing electrode surface, to assure a continuing supply of fresh toner solution across theentire electrode surface 12.
Correspondingly, spent toner fluid may be withdrawn through apertures'40, 42, and 44 which provide communication throughelectrode surface 12 withcollection channels 46, 47.Channels 46 in turn communicate with main collectingchannel 48, which is open atend 50, and from which toner fluid flows back intoreceptacle 20. Channel 47 is open at the bottom, so toner fluid falls directly back intoreceptacle 20.
Inlet channels 32, 33, andcollection channels 46, 47 may be defined by anintegral plastic member 49, as shown in FIG. 3.
As a result of this arrangement, asdielectric sheeting 14 passes overelectrode surface 12, fresh toner fluid pours frominlet ports 34 acrosselectrode surface 12 in a uniform stream, supportingsheeting 14 and uniformly spacing it fromsurface 12. After moving approximately lr inches, in the embodiment shown, most of the toner fluid frominlet ports 34 is collected throughcollection apertures 40 and recycled in the manner described above.
Similarly, a new supply of fresh toner fluid is provided to surface 12 byinlet ports 36 at a flow rate equal to that ofports 34. This toner fluid also flows acrosssurface 12, and is mostly collected throughapertures 42 for recycling.
Likewise, a third supply of fresh toner fluid at a similar flow velocity to the previous supplies is emitted through inlet ports 38, to flow acrosssurface 12 and to be generally collected byapertures 44.
Sufficient toner fluid preferably remains in the vicinity ofcollection apertures 40, 42 to keep dielectric sheeting spaced fromsurface 12 in the region between eachaperture 40, 42, and its adjacent,downstream inlet ports 36, 38.
The uniformity of flow of toner fluid frominlet ports 34, 36, and 38 is controlled by the fact that the ports are of equal, transverse dimension and are interconnected withcommon inlet 30.Channels 32 are of sufficiently large transverse dimension so that the flow through all ofports 34, 36, and 38 is generally uniform.
As a result of the above, a staged, generally unidirectional flow of three successive, generally separate toner fluid flow paths is provided acrosselectrode surface 12, beginning atinlet ports 34 and ending atoutlet apertures 44, for generally uniformly-spaced support of dielectric sheeting, which preferably moves in the general direction of the toner fluid flow acrosselectrode 12 at a velocity of 2 to 6 inches per second, and at least as fast as the velocity of the stream of toner solution, to prevent toner solution from wetting the upper side of the forward edge of thesheeting 14. The triple staged flow arrangement utilized in this invention assures that the dielectric sheeting is continuously exposed to fresh toner fluid, which prevents the wash-out of toned images by prolonged exposure to spent toner fluid.
Similarly, the wide and uniform flow of toner solution carriesdielectric sheeting 14 acrosselectrode surface 12 in a manner to generally uniformly spacedielectric sheeting 14 fromsurface 12.
Typically, the flow through inlet and accordingly throughinlet apertures 34, 36 and 38 is so adjusted to provide an essentially uniform depth across the developing electrode surface of 0.5 to 2 mm., except, of course, at the various apertures and ports insurface 12. Hence, the spacing betweenelectrode surface 12 anddielectric sheeting 14 is uniform.
Electrically-conductive members 52, which may be spring-biased wires or the like, rest gently against theback side ofdielectric sheet 14, Le, the side ofsheet 14 which is not facingelectrode surface 12.Member 52 is in electrical communication withelectrode surface 12 by means ofconductor member 54. It is believed that the providing of this electrical communication betweenelectrode surface 12 and the back ofdielectric sheet 14 improves the quality of the toning of the electrostatic image onsheet 14. Spring-biasedmembers 52 may also serve as guides to facilitate the positioning ofdielectric sheeting 14 onelectrode surface 12.
The above has been offered for illustrative purposes only, and is not intended to define the invention of this application, which is as defined in the claims below.
That which is claimed is:
1. ln apparatus for the development of latent electrostatic images on dielectric sheeting, said apparatus having a generally flat developing electrode surface for receiving said sheeting, the improvement comprising:
means for circulating toner fluid across said generally flat developing electrode surface in a generally unidirectional flowing stream of uniform thickness; and means for laying said sheeting on said flowing stream of toner fluid, whereby said sheeting is spaced from said developing electrode surface in automatic, uniform manner by said stream of toner fluid, for improved development of latent electrostatic images, and
toner fluid staging means provided for supplying a flow of fresh toner fluid to a plurality of locations on said developing electrode surface, including at least one location on said developing electrode surface spaced from the edges thereof and at an intermediate point along said path of travel, and means for removing spent toner fluid from said developing electrode surface at a location upstream from said one location at said intermediate point.
2. The apparatus of claim 1 in which said developing electrode surface, in position of use, defines a small angle to the horizontal plane in a direction to permit said stream of toner fluid to flow downwardly at said angle.
3. The apparatus of claim 2 having means for moving said sheeting in a path of travel across said developing electrode member in the general direction of said stream of toner fluid.
4. The apparatus ofclaim 3 in which said moving means comprises pairs of cooperating rollers at opposite ends of said developing electrode surface, for moving said dielectric sheeting while also removing excess toner fluid after development.
5. In apparatus for the development of latent electrostatic images on dielectric sheeting having a developing electrode surface, the improvement comprising:
toner fluid staging means, comprising means for simultaneously supplying fresh toner fluid to flow in a stream across said developing electrode surface from a plurality of spaced toner fluid inlets, including at least one central fluid inlet spaced from the edges of said electrode surface; and means for simultaneously withdrawing spent toner fluid from said electrode surface through a corresponding plurality of spaced fluid outlets, one of said fluid outlets being adjacent said central fluid inlet, whereby fresh toner fluid may be continually dispersed in-large areas across said surface-for contact with said sheeting.
6. The apparatus of claim 5 in which said stream of toner fluid across said electrode surface is generally unidirectional, and said toner fluid withdrawing outlet which is adjacent said central fluid inlet is upstream thereof.
7. The apparatus of claim 6 in which said staging means defines at least three separate, spaced fluid inlets for supply of fresh toner fluid to said developing electrode surface, said means for withdrawing spent toner fluid comprising at least three separate, spaced, fluid outlets, to provide at least three successive, generally separate toner fluid flow paths across said electrode surface.
8. The apparatus of claim 7 in which said developing electrode surface, in position of use, defines a small angle to the horizontal plane in a direction to permit said toner fluid to flow downwardly at said angle.
9. The apparatus of claim 8 having means for moving said sheeting in a path of travel across said developing electrode member in the general direction of said stream of toner fluid.
10. The apparatus of claim 9 in which said moving means comprises pairs of cooperating rollers at opposite ends of said developing electrode surface, for moving said dielectric sheeting while also removing excess toner after development.
11. The apparatus of claim 9 in which said dielectric sheeting lies on said stream of toner fluid, to be uniformly spaced thereby from said developing electrode.
12. The apparatus of claim 11 in which said stream of toner fluid is of an essentially uniform depth across said developing electrode surface of 0.5 to 2 mm., whereby said sheeting is uniformly spaced from said electrode surface by said stream of toner fluid.
13. The apparatus of claim ll in which electrically conductive means provides electrical communication between said developing electrode surface and the side of said dielectric sheet facing away from electrode surface.
14. The apparatus of claim 11 in which said spaced, fluid inlets are of equal transverse dimension and inter connected, whereby the fluid flow from each of said inlets is essentially equal to the fluid flow of the other inlets.