EP0706891A2 - Apparatus and methods for non impact imaging and digital printing - Google Patents
Apparatus and methods for non impact imaging and digital printing Download PDFInfo
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- EP0706891A2 EP0706891A2 EP95305603A EP95305603A EP0706891A2 EP 0706891 A2 EP0706891 A2 EP 0706891A2 EP 95305603 A EP95305603 A EP 95305603A EP 95305603 A EP95305603 A EP 95305603A EP 0706891 A2 EP0706891 A2 EP 0706891A2
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- Prior art keywords
- dielectric
- imaging
- drum
- image
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03G—ELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
- G03G15/00—Apparatus for electrographic processes using a charge pattern
- G03G15/22—Apparatus for electrographic processes using a charge pattern involving the combination of more than one step according to groups G03G13/02 - G03G13/20
- G03G15/32—Apparatus for electrographic processes using a charge pattern involving the combination of more than one step according to groups G03G13/02 - G03G13/20 in which the charge pattern is formed dotwise, e.g. by a thermal head
- G03G15/321—Apparatus for electrographic processes using a charge pattern involving the combination of more than one step according to groups G03G13/02 - G03G13/20 in which the charge pattern is formed dotwise, e.g. by a thermal head by charge transfer onto the recording material in accordance with the image
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/385—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective supply of electric current or selective application of magnetism to a printing or impression-transfer material
- B41J2/41—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective supply of electric current or selective application of magnetism to a printing or impression-transfer material for electrostatic printing
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Electrophotography Using Other Than Carlson'S Method (AREA)
- Printers Or Recording Devices Using Electromagnetic And Radiation Means (AREA)
Abstract
Description
- The present invention relates to apparatus and methods for non-impact imaging and digital printing.
- There exist in the patent literature disclosures of a great number of techniques for non-impact printing and imaging. The most widely used of these techniques is electrophotography wherein an electrostatic image is optically formed on a photoconductor, which is then developed with a toner. The toner image is transferred to a substrate and fused thereon.
- An additional technique in general use is ionography, wherein an electrostatic image is formed on a dielectric substrate by firing charges directly onto the substrate using an imagewise ion source.
- A technique for the transfer of electrostatic images from a dielectric photoconductor onto a dielectric substrate has also been proposed in Electrophotography by R.M. Schaffert, 2nd Edition, Focal Press, London, l975 at pages l66 - 176 and in U.S. Patent 3,055,006. This technique, known as TESI (Transfer of Electrostatic Images) employs an imagewise optical signal to create a charge image on a photoconductor. The charge image is subsequently replicated onto a dielectric substrate by applying single polarity charges to a surface of the dielectric substrate opposite from that surface which faces the photoconductor.
- There is thus provided in accordance with a preferred embodiment of the present invention imaging apparatus including a dielectric substrate with at least two generally opposite surfaces; a plurality of elongate electrodes underlying a first surface of the dielectric substrate; imaging circuitry for application of voltage signals to the plurality of electrodes; a charge source operative to supply a flow of charges to a second surface of the dielectric substrate up to and not beyond a generally linear boundary disposed along the second surface of the dielectric substrate and transversing the plurality of elongate electrodes.
- Additionally in accordance with a preferred embodiment of the present invention, the charge source includes an edge of an elongate shield which defines the generally linear boundary.
- Moreover, in accordance with yet a further embodiment of the invention, the elongate shield includes an electrostatic shield.
- In yet a further embodiment of the invention, the elongate shield includes a physical barrier.
- In further accordance with an embodiment of the present invention, the charge source includes an AC corona.
- Further in accordance with a preferred embodiment of the present invention, the charge source includes a liquid which exhibits electrical conductivity; an applicator which is operative to apply the liquid to the second surface of the dielectric substrate; a termination electrode; and a physical barrier which defines the generally linear boundary.
- Alternatively, the liquid may be characterized in that it transfers charges to the second surface of the dielectric element.
- In accordance with yet a further embodiment, the applicator is operative to rinse the second surface of the dielectric element with the liquid, thereby also providing a cleaning function.
- Moreover, the physical barrier may include a dielectric blade.
- Furthermore, the termination electrode includes a conductive coating on one surface of the dielectric blade.
- Still further in accordance with a preferred embodiment of the present invention, the conductive coating is biased to a predetermined uniform potential.
- In accordance with yet a further embodiment of the present invention, apparatus further includes a developing unit operative to produce a developed image on the dielectric substrate.
- Moreover, the apparatus may include a transfer unit operative to transfer the developed image to an output medium.
- There is thus provided in accordance with a preferred embodiment of the present invention, a method for providing a dielectric substrate with at least two generally opposite surfaces; providing a plurality of elongate electrodes underlying a first surface of the dielectric substrate; applying voltage signals to the plurality of electrodes; supplying a flow of charges to a second surface of the dielectric substrate up to and not beyond a generally linear boundary disposed along the second surface of the dielectric substrate and transversing the plurality of elongate electrodes.
- Moreover, the step of supplying a flow of charges includes extraction of ions from an ion pool.
- Yet in further accordance with the present invention, the step of supplying a flow of charges includes the steps of applying a liquid to the second surface of the dielectric substrate; providing a termination electrode; and providing a physical barrier which defines the generally linear boundary.
- Further in accordance with the present invention, the applying of a liquid is further operative to rinse the second surface of the dielectric element with the liquid, thereby providing a cleaning function.
- Additionally, the step of producing a developed image on the dielectric substrate may be included.
- According to yet a further embodiment of the present invention, the step of transfering the developed image to an output medium is included.
- In accordance with yet a further embodiment of the present invention, the step of displacing the generally linear boundary relative to the dielectric substrate is included.
- There is thus provided in accordance with the present invention, digital color printing apparatus including an intermediate transfer medium; a plurality of imaging units disposed about the intermediate transfer medium and operating in time synchronization wherein each printing unit includes: an imaging drum having an outer dielectric surface; a plurality of elongate electrodes underlying the outer dielectric surface; imaging circuitry for application of voltage signals to the plurality of elongate electrodes; a charge source operative to supply a flow of charges to the outer dielectric surface up to and not beyond a generally linear boundary disposed along the outer dielectric surface of the imaging drum and transversing the plurality of elongate electrodes; a developing unit operative to apply pigmented toner to the outer dielectric surface, producing toned images thereon; and a primary transfer unit operative to transfer the toned images to the intermediate transfer medium; and a secondary transfer unit operative to transfer the toned images from the intermediate transfer medium to a print medium.
- Moreover, each of the developing units of the plurality of image printing units utilizes a distinct toner color.
- Furthermore, the plurality of image printing units are operative to provide full process color.
- In accordance with an embodiment of the present invention, the intermediate transfer medium includes a drum.
- Alternatively, the intermediate transfer medium may include a belt.
- The present invention will be understood and appreciated more fully from the following detailed description, taken in conjunction with the drawings in which:
- Figs. lA, lB, lC and lD are illustrations of the application of voltage or charge on various surfaces over time in accordance with a preferred embodiment of the present invention;
- Fig. 2 is an illustration of a time varying voltage signal on a first surface of a dielectric substrate resulting in a corresponding charge pattern being retained on an opposite surface of the dielectric substrate in accordance with a preferred embodiment of the present invention;
- Figs. 3A and 3B are respective generalized and side view illustrations, taken along the line IVB -IVB, of apparatus for applying voltage and charges to opposite surfaces of a dielectric substrate in accordance with another embodiment of the present invention;
- Figs. 4A and 4B are respectively graphical and pictorial illustrations of the operational parameters of apparatus for continuous toning by optical density modulation in accordance with a preferred embodiment of the invention;
- Fig. 5 is a schematic illustration of an alternate embodiment of the apparatus of Figs 3A and 3B;
- Figs. 6A, 6B and 6C are illustrations of parameters for obtaining a continuum of gray levels by pixel size modulation in accordance with an embodiment of the present invention;
- Figs. 7A and 7B are pictorial illustrations of side and top views, respectively, of an alternative embodiment of an alternating polarity charge source providing a charge flow having at least one defined edge;
- Fig. 7C is an alternative embodiment of the alternating polarity charge pool apparatus of Fig. 7A.
- Fig. 8 is a graphical illustration of the intensity of an ion current measured by a current measuring device as a function of the relative displacement in a sweep direction between an alternating polarity charge source and the device in accordance with a preferred embodiment of the present invention;
- Figs. 9A and 9B are pictorial side and top view illustrations respectively, of a further alternating polarity charge source providing a charge flow having at least one defined edge;
- Figs. 10A and 10B are pictorial side and top illustrations of an alternative embodiment of an alternating polarity charge source providing a charge flow having at least one defined edge in accordance with the present invention;
- Fig. 11A is a pictorial illustration of a side view of apparatus for providing an alternating polarity charge flow having at least one defined edge in accordance with a further embodiment of the present invention.
- Fig. 11B is an illustration of the amplitude modulation of voltage applied to apparatus for providing an alternating polarity charge flow over time in accordance with a preferred embodiment of the present invention.
- Fig. 11C is a pictorial illustration of a side view of apparatus for providing an alternating polarity charge flow having at least one defined edge in accordance with an alternate embodiment of the present invention.
- Fig. 12A is a simplified illustration of printing apparatus constructed and operative in accordance with another preferred embodiment of the present invention;
- Figs. 12B and 12C are signal diagrams illustrating electrical signals produced by the apparatus of Figs. 3A and 3B;
- Fig. 13A is a simplified illustration of printing apparatus constructed and operative in accordance with another preferred embodiment of the present invention;
- Fig. 13B is an illustration of the operation of the apparatus of Fig. 13A;
- Fig. 14A is a generalized pictorial illustration of a digital receptor imaging drum constructed and operative in accordance with a preferred embodiment of the present invention;
- Fig. 14B is a sectional illustration of a portion of the drum of Fig. 14A, taken at line B - B on Fig. 14A;
- Figs. 15A, 15B, 15C and 15D are sectional illustrations, taken along line B of Fig. 14A, of four alternative embodiments of the imaging drum of Fig. 14A;
- Fig. 16A is a partially cut away generalized pictorial illustration of a preferred embodiment of the drum of Figs. 14A and 15C;
- Fig. 16B is a partially sectional, partially pictorial illustration of a further variation of the imaging drum of Figs. 14A and 15C;
- Fig. 16C is an enlarged illustration of a portion of the imaging drum of Fig. 16A, at an intermediate stage of drum fabrication;
- Fig. 16D is a generalized pictorial illustration of a further variation of the imaging drum of Figs. 14A and 15C;
- Fig. 16E is a partially cut-away illustration of part of the imaging drum of Fig. 16D;
- Figs. 17A and 17B are schematic illustrations of alternate embodiments of the imaging electronics used in the apparatus of Figs. 14A and 14B;
- Fig. 18 is an illustration of a continuous tone pattern generated using the apparatus of Fig. 17A;
- Figs. 19A and 19B are block diagram illustrations of the architecture of the apparatus of Fig. 17A when used for producing a continuous tone pattern;
- Fig. 20 is an illustration of a halftone pattern generated using the apparatus of Fig. 17A
- Figs. 21A and 21B are block diagram illustrations of the architecture of the apparatus of Fig. 17A when used for producing a pixel-size modulated half-tone pattern; and
- Fig. 22 is a block diagram illustration of the architecture of the apparatus of Fig. 17A when used for producing a super-pixel halftone pattern.
- Fig. 23 is a schematic illustration of printing engine apparatus operative in accordance with a preferred embodiment of the present invention.
- Fig. 24 is a structural illustration of printing engine apparatus representing an embodiment of the present invention.
- Fig. 25 is a schematic illustration of digital color copier apparatus operative in accordance with a preferred embodiment of the present invention.
- Fig. 26 is a schematic illustration of print laminator apparatus operative in accordance with a preferred embodiment of the present invention.
- Fig. 27 is a schematic illustration of printing apparatus operative to provide high speed one-sided or duplex printing in an embodiment of the present invention.
- Fig. 28 is a schematic illustration of printing apparatus operative to provide high speed one-sided or duplex printing in accordance with an alternative embodiment of the present invention.
- Fig. 29 is a schematic illustration of printing apparatus operative to provide high speed one-sided or duplex printing in accordance with a further embodiment of the present invention.
- Reference is now made to Figs. lA - lD, which illustrate the operation of the present invention. Fig. lA illustrates an arbitrary voltage at a typical point location on a first surface of a dielectric substrate as it varies over time. The voltage may be applied to the typical point location by means of a conductive backing associated with the first surface of the dielectric substrate in touching or capacitive relationship therewith. The conductive backing may be a separate conductor in close proximity to, or alternatively a permanent coating or layer formed on, the first surface of the dielectric substrate.
- Fig. 1B illustrates, on the same time scale as in Fig. 1A, the application of a flow of charges to a second surface of the dielectric substrate, which is opposite to and generally uniformly spaced from the first surface, to temporarily neutralize the effect on the second surface of the voltage applied to the first surface. Following application of such charges the second surface retains a charge corresponding to the voltage which was applied to the first surface, at the time T2 that the application of such charges ceased, but of an opposite polarity thereto.
- According to a preferred embodiment of the invention, the flow of charges comprises an alternating polarity charge flow to a second surface of the dielectric substrate which is opposite to and generally uniformly spaced from the first surface. It is preferred that the time variation of the voltage applied to any given location on the first surface be sufficiently small such that at least during an end portion of the duration of the alternating polarity charge flow at such location, the voltage variation is essentially zero.
- The alternating polarity charge flow at each location is represented in Fig. lB by a stack of positive and negative charges. The beginning and end of the duration of the application of the alternating polarity charge flow at each location are indicated in Fig. 1B respectively as Tl and T2.
- Fig. 1C illustrates the apparent surface voltage on the second surface of the dielectric substrate. It is noted that this voltage tracks the voltage on the first surface until the charge flow begins at time Tl. Upon termination of the charge flow at time T2, the apparent surface voltage of the second surface is very nearly zero. If, thereafter, the voltage on the first surface is brought to zero, as indicated in Fig. 1A, the apparent surface voltage on the second surface becomes approximately the negative of the voltage on the first surface at time T2, due to charge retention on the second surface, as indicated in Fig. 1C.
- Fig. 1D is an expanded time scale illustration corresponding to Fig. 1C and illustrating with greater particularity the effect of one possible application of an alternating charge flow to the second surface, which results in a reduction in the apparent surface voltage on the second surface from the voltage at T1 to very nearly zero at T2.
- Referring now to Fig. 2, there is shown schematically an arbitrary voltage signal provided on a
dielectric substrate 10 at afirst surface 12 thereof, which is preferably backed with a conductive backing l4 to which is coupled a time-variable voltage source l6. Fig. 2 also illustrates in one dimension, the corresponding spatial charge pattern, of opposite polarity to the corresponding voltage signal, which is retained on a second surface l8 of the dielectric substrate in accordance with the dynamic charge retention of the present invention, by application of a flow of charges to the second surface which is operative to temporarily neutralize the effect on the second surface of the voltage applied to the first surface l2. The application of the flow of charges is preferably provided by an alternating polarity charge source (APCS) 20, capable of achieving a spatial edge accuracy consistent with the desired resolution, which may be of the type described hereinbelow. - The charge source 20 is preferably moved at a velocity v along the second surface l8 of the dielectric substrate l0, indicated by an
arrow 22. - Reference is now made to Figs. 3A and 3B which illustrate apparatus for applying voltage and charges to opposite surfaces of a
dielectric substrate 42 in accordance with another embodiment of the present invention. - In this embodiment, an elongate alternating polarity charge source (EAPCS) 46, such as that described herein and being capable of achieving a spatial edge accuracy consistent with the desired resolution is scanned in one dimension, perpendicular to its longitudinal axis, along a
second surface 48 ofsubstrate 42, by means of a linear drive mechanism including aworm screw 50 cooperating with ascrew rider 52, fixed tosource 46. Anelectric motor 54 drives theworm screw 50 in response to the outputs of a commercially availablesynchronized driver 56. A host computer (not shown) provides positioning instructions via amultiplexer 58 todriver 56. - In this embodiment, a multisectional
conductive backing layer 60, typically comprising a plurality ofelongate electrodes 44, is associated with the first surface of thedielectric substrate 42. Eachelectrode 44 is provided with an information content modulated time varying voltage via a correspondingdriver 62, in response to control signals received from the host computer viamultiplexer 58. - It may be appreciated that in the embodiment of Figs. 3A and 3B a charge pattern is written on the second surface by information content modulation of voltages applied simultaneously to the different regions of the first surface of the
dielectric substrate 42 viaelectrodes 44 in synchronism with the one dimensional scanning motion ofsource 46. - It is appreciated that a desired two-dimensional spatial resolution may be achieved by adjusting appropriate parameters. In a first dimension, the parameters to be adjusted include the width of the
elongate electrodes 44, the width of agap 45 betweenadjacent electrodes 44, the thickness of thedielectric layer 42 and the dielectric constant of thedielectric layer 42. In a second dimension, the parameters include the edge definition of theEAPCS 46. Thegaps 45 should be filled with electrically insulative dielectric material having high dielectric strength. Alternatively,gaps 45 may be filled with highly resistive material. - It is further appreciated that the dynamic charge retention techniques described hereinabove allow an uninterrupted line of uniform width as small as one pixel to be achieved. The advantages of these techniques include the replacement of dot pixels thus eliminating holes between pixels. Accordingly, intentional overlap of pixels is not necessary.
- Multi-sectional
conductive backing layer 60 may comprise a uniform conductive film from which a plurality of electrodes are created using an etching technique such as laser etching, chemical etching, or ion etching. Alternatively the multi-sectional conductive backing layer may comprise a grid comprising a weave of straight conductive wires in one dimension and insulating curved wires in a second dimension. This type of grid is available from Carbotex of Grutlistrasse 68, Zurich, Switzerland. Alternatively, the multi-sectionalconductive backing layer 60 may be produced by electroforming or winding techniques. - Reference is now made to Figs. 4A and 4B which illustrate operational parameters for continuous toning apparatus in accordance with a preferred embodiment of the present invention.
- It is appreciated that certain toners are characterized by the property that the optical density of a toned area can be controlled by the development voltage. Some liquid toners and certain dry toners are examples of this type of toner.
- It is also appreciated that the dynamic charge retention techniques described hereinabove are capable of writing continuous voltage levels thus enabling the generation of one-pass monochrome toned images of continuous optical densities, when toners of the type described hereinabove are used.
- In accordance with a preferred embodiment of the present invention, continuous color printing using standard subtractive colors and optical density modulation can be achieved in accordance with the dynamic charge retention writing techniques described herein and standard multi-pass printing techniques.
- Fig. 4A graphically demonstrates hypothetical optical densities of four basic printing colors (CMYK) typically used with subtractive color printing systems as a function of the development voltage of each of the toner colors.
- Fig. 4B illustrates a single area of a
color print 345 to which four basic printing colors (CMYK) have been sequentially transferred in accordance with standard multi-pass printing techniques. - The specific optical density of each color across any area may be controlled by writing (in accordance with the writing techniques described hereinabove in association with Figs. 3A and 3B) at the corresponding area a voltage level which corresponds to the desired optical density for that color.
- It is appreciated that the subtractive combination of the optical densities of each of the four basic printing colors over an area results in a color having any of a continuum of color shades.
- It is also appreciated that a color shade may be uniformly distributed within the borders of an entire area. Therefore, the specific color shade desired is achieved at the level of one pixel and not as a result of the combination of several pixels.
- This embodiment offers continuous control over color levels providing high quality color prints.
- Reference is now made to Fig. 5 which illustrates a schematic representation of imaging electronics for use in the apparatus of Figs. 3A and 3B for writing continuous as well as half-tone levels.
- A
clock input 352 is pulsed in coordination with input data causing ashift register 354 to sequentially address each of a plurality ofconductive electrodes 356. Theconductive electrodes 356 may correspond toconductive electrodes 44 in Figs. 3A and 3B. The electrode being addressed at any given time receives a voltage level fromimaging electronics 358 and is charged to that voltage level. Typically,imaging electronics 358 comprises a digital to analog high voltage converter. - Associated with each
electrode 356 is acapacitor 360 which retains the given voltage level until the electrode is subsequently addressed and receives a new voltage level. - It is appreciated that the dynamic charge retention techniques of the present invention allow charges of either polarity to be written to the substrate. It is further appreciated that one individual charge pattern can contain charges of both polarities. The number of voltage levels achievable in accordance with this embodiment is not dependent on the print head. Instead, the number of voltage levels is determined by the
imaging electronics 358. - Reference is now made to Figs. 6A - 6C which illustrate a method for obtaining a continuum of monochrome gray levels by providing pixel size modulation in accordance with an embodiment of the present invention.
- Fig. 6A graphically represents monochromatic gray levels that can be achieved over an area as a function of the fractions of each of the pixels comprising that area that are toned. Pixels are charged and toned in accordance with the writing techniques described hereinabove, particularly with reference to Figs. 3A and 3B, and standard toning techniques.
- The dimension of a pixel in the direction of the sweep of the charge source may be represented by L. The dimension of a pixel in the second direction is determined by the width of the conductive electrode associated with that pixel. (a/L) is the toning fraction, where a is a function of the velocity of the charge source multiplied by the effective time duration during which the bias voltage on the conductive electrode changes during the writing of a single pixel.
-
Curve 470 illustrates one possible representation of gray levels that can be achieved by controlling the toning fraction of each pixel. In this representation, the voltage basing the conductive electrode is zero at the beginning and end of a sweep of the pixel by a charge source. During the sweep, the voltage biasing the conductive electrode is raised to a high level for a time duration determined by the desired toning fraction. -
Curve 472 illustrates an alternate representation of gray levels that can be achieved by controlling the toning fraction of each pixel. In this representation, the voltage basing the conductive electrode is at a high level at the beginning and end of a sweep of the pixel by a charge source. During the sweep, the voltage biasing the conductive electrode is reduced to zero for a time duration in accordance with the desired toning fraction. - It is appreciated that a continuum of monochrome gray scales may be achieved for an area by selecting the appropriate voltages for the beginning and end of the sweep of each of the pixel locations comprising that area (following
curve 470 orcurve 472 depending upon the desired grey level). - Figs. 6B and 6C illustrate close-up views of the fractionally toned image of the pixels of two adjacent conductive electrodes (not shown) where the pixels of one electrode have been phase shifted with respect to the pixels of the second electrode.
- Two different gray scales are shown (Fig. 6B and Fig. 6C).
- It is appreciated that the phase shift with respect to adjacent electrodes enabled by pixel size modulation techniques described hereinabove allows half tone gray scales with high spatial frequency of pixel arrangements to be achieved.
- It is further appreciated that continuous color shades, via half tone, can be achieved using pixel size modulation techniques to vary the toning fraction of each pixel during each of four monochrome passes carried out during standard multi-pass subtractive color printing.
- It is appreciated that the dynamic charge retention techniques described hereinabove, particularly with reference to Figs. 3A and 3B, provide a method for generating a charge pattern that contains charges of both polarities. It is understood that there exist toners which develop positive charge images and similarly there are other toners which develop negative charge images.
- Therefore by using two different color toners which develop opposite polarity charge images, a two-color image may be produced in a single pass. The two-color image may contain any of a continuum of shades of the two colors, in accordance with the techniques for continuous toning described hereinabove, or alternatively, in accordance with the techniques for pixel size modulation half- tones described hereinabove. One possible application for this technique is in the generation of "highlight" images.
- Reference is now made to Figs. 7A - 7B which are pictorial illustrations of side and top views, respectively, of an alternating polarity charge source providing a charge flow having at least one defined edge in accordance with an embodiment of the present invention.
- Alternating polarity
charge pool apparatus 502 comprises a non-imagewise source of ions.Apparatus 502 may also comprise anelongate conductor 504 coated with adielectric layer 506 and a transversely orientedscreen electrode 508 contacting or closely spaced from the dielectric-coated conductor and coiled about an innerdielectric support structure 507 as described in U.S. Patent 4,409,604 assigned to Dennison Manufacturing Company of Framingham, Mass, USA. - Typically inner
dielectric support structure 507 is rod shaped. Alternately, innerdielectric support structure 507 may be of any suitable shape such as that illustrated in Fig. 7C below. - In accordance with a particular configuration of
apparatus 502, transversely orientedscreen electrode 508 is coiled aroundelongate conductor 504. Whenapparatus 502 is operational, a pool of positive and negative ions is continuously generated in the air space immediately surrounding the dielectric-coatedconductor 504 at the regions in between the locations where the coiled conductor crosses over the dielectric-coated conductor. - An elongate
electrostatic shield 510, typically comprising a conductive material, may be configured as illustrated to partially enclosecharge pool apparatus 502. - It is appreciated that the charge source of Figs. 7A -- 7B is capable of providing an ion beam with at least one edge sharply defined. It is appreciated that
charge pool apparatus 502 alone does not provide an elongate ion beam with a sharply defined edge. - It is further appreciated that
charge pool apparatus 502 may serve as an elongate alternating polarity charge (EAPCS) source described hereinabove in accordance with dynamic charge retention techniques described hereinabove. This configuration is presented to offer an example of possible configurations for the EAPCS and is not intended to be limiting. - An excitation voltage is applied to elongate
conductor 504 either continuously or in amplitude modulated bursts of any suitable predetermined wave form. The excitation voltage is typically a high AC voltage with an amplitude of 2000V pp and has a frequency in the range between several hundred kHz to several MHz. - Typically, elongate
electrostatic shield 510 and transversely orientedscreen electrode 508 are grounded and the dominant force in charge extraction is the ASV. As the ASV decreases, charge extraction is reduced accordingly until neutralization of the ASV. - A
dielectric surface 512, typically of the type described hereinabove particularly in accordance with Figs. 3A - 3B, sweeps relative to the charge source. Alternatively,dielectric surface 512 may be an outer dielectric surface of a digital input electrostatic (D/E) imaging drum as described in one or more of applicant's co-pending patents and patent applications including U.S. Patents 5,289,214 and 5,157,423. Alternately, any other suitable dielectric surface on which charges are to be accumulated may be used. - Preferably, the gap between
dielectric surface 512 and shield 510 is about 100 - 300 microns. Typically,dielectric surface 512 comprises a plurality of regions each having associated therewith an apparent surface voltage (ASV). During the sweep, these regions of the dielectric surface are brought into their maximum propinquity with the charge pool. The ASV of each region creates an electric field betweendielectric surface 512 and the charge pool. -
Electrostatic shield 510 serves to tailor the electric field created. The ASV at regions on the dielectric surface which have direct unshielded access to the charge pool causes ions of the appropriate polarity to be extracted until the ASV at that region is neutralized. The ASV at regions ondielectric surface 512 which are shielded from the charge pool are not involved in ion extraction. When a region on the dielectric surface is in a location which is not shielded from the charge pool, the region may accumulate charges in accordance with the techniques described hereinabove. When the region is moved to a shielded location, additional charge will not accumulate on that region. - According to an alternate mode of operation, elongate
electrostatic shield 510 and transversely orientedscreen electrode 508 receive a screen AC voltage, instead of being grounded. The screen AC voltage comprises a phase shifted high amplitude modulated AC voltage at the same frequency as the excitation voltage applied to elongateconductor 504 to obtain the effect illustrated by the graph of Fig. 1D. The amplitude of the screen AC voltage is on the same order of magnitude as the maximum ASV, which is selected in accordance with charge image parameters. In this case, charge extraction is a combined function of the ASV and the screen AC voltage. The phase shift, between the screen AC voltage and the excitation voltage supplied to elongateconductor 504, determines the efficiency of charge extraction from the charge pool by the screen AC voltage. This provides the advantage of accelerated neutralization of the ASV. As the ASV is neutralized, the amplitude of the screen AC voltage is gradually decreased to zero, so that the final charge level retained corresponds only to the ASV that was present on thedielectric surface 512 prior to activation of thecharge pool apparatus 502. It is appreciated that amplitude modulation techniques may be used in accordance with any of the embodiments of Figs. 7A -- 11A. - It is appreciated that the extracted ions typically form a beam with at least one sharply defined edge. In accordance with the techniques described in accordance with this embodiment of the invention, preconditioning of the dielectric surface to be charged is not necessary. Therefore, the width of the charge beam is not significant as long as one edge is sharply defined. It is also appreciated that charges from the opposite, undefined edge of the ion beam do not affect the final amount of charge that is retained at a region. When the region moves past the sharply defined edge, the appropriate amount of negative or positive charges is retained to balance the effect of the conductive backing potential regardless of any stray charges that may have accumulated at that region from the opposite, undefined edge. The edge resolution achievable in the direction of the sweep may be a function of the intensity of the ion beam and the sharpness of the beam edge.
- According to an alternative embodiment, an elongate grounded shield generally enclosing
charge pool apparatus 502, except for an elongate opening, may be used to provide an ion beam with two defined edges. - Reference is now made to Fig. 7C which is a pictorial illustration of a side view of an alternative embodiment of alternating polarity
charge pool apparatus 502 of Fig 7A in accordance with an alternative embodiment of the present invention. - Alternating polarity
charge pool apparatus 511, comprises a non-imagewise source of ions.Apparatus 511 may further comprise anelongate conductor 513 coated with adielectric layer 515 and a transversely orientedscreen electrode 517 contacting or closely spaced from the dielectric-coated conductor and coiled about an innerdielectric support structure 519 as described in U.S. Patent 4,409,604 assigned to Dennison Manufacturing Company of Framingham, Mass, USA. - In the embodiment of
apparatus 511 of Fig. 7C, innerdielectric support structure 519 is shaped so as to provide greater exposure ofelongate conductor 513 toscreen electrode 517. This allows increased ion generation without compromising the mechanical strength of alternating polaritycharge pool apparatus 511. - Reference is now made to Fig. 8 which is a graphical illustration of the intensity of an ion current measured by a current measuring device as a function of the relative displacement in a sweep direction between an alternating polarity charge source and the device in accordance with a preferred embodiment of the present invention;
For the measurements illustrated herein, a conductive current probe with a constant bias voltage of 400 V (providing an ASV of 400 V) was used to monitor the steady-state ion beam. -
Curve 520 illustrates a typical ion beam profile for the case where apparatus 502 (Figs. 7A and 7B above) does not comprise an electrostatic shield. -
Curve 522 illustrates a typical ion beam profile for the case where apparatus 502 (Figs. 7A and 7B above) comprises an electrostatic shield, typically of the type described hereinabove and indicated byreference number 510. - The two sets of measurements were carried out under the same conditions. In particular, the distance between the probe and the charge pool remained unchanged.
Curve 522 illustrates the region in which the beam has a sharp edge. The shaded area represents the uncertainty of the measurement due to the accuracy of the measuring device. The edge of the ion beam (illustrated by curve 522) using the shield apparatus is sharply defined. By contrast the edge of the ion beam (illustrated by curve 520) in the non-shielded apparatus is not sharply defined. - It is appreciated that
curves - Reference is now made to Figs. 9A - 9B which are pictorial respective side and top view illustrations of
apparatus 530 for providing an alternating polarity charge source having at least one defined edge. -
Apparatus 530 comprises alternating polaritycharge pool apparatus 532 which includes a non-imagewise source of ions, comprising ahigh voltage electrode 534 coupled to a highvoltage AC source 535 and two typically groundedscreen electrodes screen electrodes -
Screen electrodes high voltage electrode 534 by adielectric layer 540. Aspace 542 is defined betweenscreen electrodes screen electrodes - It is appreciated that alternating polarity
charge pool apparatus 532 does not itself provide an elongate ion beam with a sharply defined edge. - In order to achieve an ion beam which has at least one edge defined in accordance with the techniques described hereinabove particularly with respect to Figs. 7A - 7C,
apparatus 530 further comprises an elongateelectrostatic shield 544.Shield 544, typically comprising a preferably conductive material, is located with some spacing relative to chargepool apparatus 532. Typically shield 544 is grounded. Alternately, shield 544 may receive an amplitude modulated voltage in accordance with the techniques described herein.Electrostatic shield 544 may be configured as illustrated wherebycharge pool apparatus 532 is partially obscured byshield 544. - It is appreciated that
apparatus 530 may serve as an elongate alternating polarity charge source in the dynamic charge retention techniques described hereinabove. It is noted that the configuration presented here is a further example of a possible configuration for the charge source and is not intended to be limiting. - Reference is now made to Figs. 10A and 10B which are pictorial illustrations of
apparatus 550 for providing an alternating polarity charge flow having at least one defined edge. -
Apparatus 550 comprises alternating chargepool generating apparatus 552, acasing 556 and an elongateelectrostatic shield 560.Apparatus 552 preferably comprises one ormore corona wires 554 some or all of which may be dielectrically coated. Alternatively,corona wires 554 may not be dielectrically coated. Eachcorona wire 554 is operative to receive a high AC voltage. All of thewires 554 may be biased by the same AC source (not shown). Alternatively,corona wires 554 may be biased by AC sources having different amplitudes. Eachcorona wire 554 may receive a different AC voltage. -
Corona wires 554 are confined by an isolatingcasing 556, typically formed of a dielectric material. Casing 556 typically contains anelongate screen electrode 558 which is partially open and wherein an ion pool is created.Screen electrode 558 andelectrostatic shield 560 are typically grounded. Alternately, when using amplitude modulation techniques as described herein,screen electrode 558 andelectrostatic shield 560 receive a high amplitude modulated AC voltage. - The open area of
screen 558 may comprise a gridlike area as shown. Alternatively, the open area may comprise at least one elongate slot. - According to an alternate embodiment of
apparatus 552, casing 556 may further comprise an inlet through which conditioned air may flow ontocorona wires 554. In this embodiment, the intensity of the ion pool created atscreen 558 may be increased. - In order to achieve an ion beam which has at least one edge as described hereinabove particularly with reference to Figs. 7A - 7B, elongate
electrostatic shield 560 typically comprising a grounded conductive material, is spaced relative to chargepool apparatus 552.Electrostatic shield 560 may be configured as illustrated so thatcharge pool apparatus 552 is partially obscured. - It is appreciated that
apparatus 550 may serve as an elongate alternating polarity charge (EAPCS) source described hereinabove in accordance with the dynamic charge retention techniques described hereinabove. This configuration is an example of a possible configuration for the EAPCS and is not intended to be limiting. - Reference is now made to Fig. 11A which is a pictorial illustration of a side view of apparatus for providing an alternating polarity charge flow having at least one defined edge in accordance with a further embodiment of the present invention.
-
Apparatus 598 comprises alternatingcharge pool apparatus 600 andbarrier 602 withelongate edge 604. Alternating polaritycharge pool apparatus 600 may be of the type described hereinabove with reference to Figs. 7A - 10B, with particular reference to Fig. 7C. - A
dielectric surface 512, typically of the type described hereinabove particularly in accordance with Figs. 3A - 3B, sweeps relative to alternating polaritycharge flow apparatus 598. Preferably,barrier 602 is placed in contacting proximity ofdielectric surface 512. It is appreciated thatedge 604 ofbarrier 602 serves as an electrostatic shield. - Typically,
dielectric surface 512 comprises a plurality of regions each having associated therewith an apparent surface voltage (ASV). During the sweep, these regions of the dielectric surface are brought into their maximum propinquity withcharge pool 606. - When a screen electrode (not shown) of alternating
charge pool apparatus 600 is grounded, as described hereinabove, with reference to Figs. 7A - 10B, the ASV of each region creates an electric field betweendielectric surface 512 andcharge pool 606 causing ions to be extracted and deposited on thedielectric substrate 512, neutralizing the ASV. - Alternately, modified amplitude modulation techniques, with its associated benefits, may be used, whereby a high amplitude modulated AC voltage is applied to the screen electrode (not shown) of alternating
charge pool apparatus 600. - Charge is supplied up to and not beyond
edge 604 ofbarrier 602. Thus, after an area ofdielectric surface 512 has swept overedge 604 ofbarrier 602, additional charge will not reach that area due to the generally linear physical boundary created by contact betweenelongate edge 604 ofbarrier 602 anddielectric surface 512. Thus, the density of retained charge on a given region corresponds to the ASV of that region asdielectric surface 512 sweeps overedge 604. -
Barrier 602 may typically be a blade made from an elastomeric dielectric material. The precise material is selected so as to be free of triboelectricity when brought into contact withdielectric surface 512, in order to prevent interference with charge retained ondielectric surface 512. - It is further appreciated that
apparatus 598 may serve as an elongate alternating polarity charge source (EAPCS) described hereinabove in accordance with dynamic charge retention techniques described hereinabove. This configuration is presented to offer an example of possible configurations for the EAPCS and is not intended to be limiting. - Reference is now made to Fig. 11B which shows, as a function of time, the amplitude modulated AC voltage applied to the screen electrode (not shown) of
apparatus 600 of Fig. 11A, in accordance with the amplitude modulation techniques described herein. - Reference is now made to Fig. 11C which is a pictorial illustration of a side view of apparatus for providing an alternating polarity charge flow having at least one defined edge in accordance with a further embodiment of the present invention.
- Alternating polarity
charge flow apparatus 610 is operative to supply an edge-defined flow of charges of either polarity to adielectric surface 612. - Typically,
dielectric surface 612 is capacitively associated with a plurality of electrodes (not shown) which receive information-bearing voltage signals from imaging electronics and which create a plurality of regions thereon, each having associated therewith an apparent surface voltage (ASV). -
Dielectric surface 612 may be of the type described hereinabove with particular reference to Figs. 3A - 3B. Alternatively,dielectric surface 612 may be an outer dielectric surface of a digital input electrostatic (D/E) imaging drum as described in one or more of applicant's co-pending patents and patent applications including U.S. Patents 5,289,214 and 5,157,423. Alternately, any other suitable dielectric surface on which charges are to be accumulated may be used. - Alternating polarity
charge flow apparatus 610 comprises aliquid applicator 613, ashield 614, and anelongate termination electrode 618.Shield 614 typically extends in a direction perpendicular to a sweep direction ofdielectric substrate 612. -
Liquid applicator 613 is operative to apply a liquid 620 todielectric surface 612.Liquid 620 may be electrically conductive. Alternatively, liquid 620 may be a non-conductive liquid which exhibits electrical conductivity when subject to certain stimuli. -
Liquid 620 preferably contacts but does not wetdielectric surface 612. For example, ifdielectric surface 612 is hydrophobic, then water may be an appropriate conductive liquid. In accordance with the specific properties and viscosity ofliquid 620,liquid applicator 613 may apply liquid 620 todielectric surface 612 using contact means (roller, sponge) or non-contact means (spray jets or non-contacting rollers), or a combination thereof. -
Shield 614 may comprise any suitable means for establishing a generally linear boundary with at least one well-defined elongate edge ondielectric surface 612. Beyond the well-defined elongate edge, liquid 620 contactingdielectric surface 612 is substantially not present, leaving a generally dry surface with charges retained thereon. -
Shield 614 may be an elastomeric dielectric blade which is placed in contact withdielectric surface 612 to create a barrier thereon. The precise material may be selected so as to be free of triboelectricity when brought into contact withdielectric surface 612, in order to prevent interference with charge retained thereon. -
Elongate termination electrode 618 is typically a conductive element having a predetermined uniform potential. Preferably,elongate termination electrode 618 is grounded. It is desirable forelongate termination electrode 618 to be positioned nearshield 614 in order to create ionic conduction inliquid 620 betweenelongate termination electrode 618 anddielectric surface 612 alongshield 614. Typically, the gap betweenelongate termination electrode 618 anddielectric surface 612 alongshield 614 is between 50 -- 1,000 microns. -
Elongate termination electrode 618 may be formed by coating a surface ofshield 614 with a conductive material. Alternately,elongate termination electrode 618 may be an independent element. - Charged images are created on
dielectric surface 612 in the following manner. -
Dielectric surface 612 sweeps relative to alternating polaritycharge flow apparatus 610.Liquid 620 is applied todielectric surface 612 usingliquid applicator 613 as described hereinabove, creating a liquid-dielectric interface. - The ASV of each region of
dielectric surface 612 creates an electric field betweendielectric substrate 612 andelongate termination electrode 618.Elongate termination electrode 618 serves to intensify the electric fields stemming from the ASV of each region ofdielectric surface 612. The electric fields cause ionic conduction inliquid 620. - In accordance with the ASV at any given time, charges of either polarity flow from
liquid 620 to the liquid-dielectric interface and are retained ondielectric surface 612. Charge transfer from a conductive liquid to a dielectric surface is known in the art and is described in U.S. Patent 2,904,431 to A.J. Moncrieff Yeates, U.S. Patent 2,987,660 to L.E. Walkup and U.S. Patent 3,579,332 to P.W. Chudleigh. - As the ASV at a region of
dielectric surface 612 is neutralized, the transfer of charges from liquid 620 to that region diminishes. -
Shield 614 provides an elongate generally linear boundary beyond which liquid 620 ondielectric surface 612 does not pass. Thus, regions ofdielectric surface 612 which have swept over the boundary established byshield 614 no longer bear liquid 620. Accordingly, no further charge is supplied to those regions ofdielectric surface 612. The density of retained charge at a given region corresponds to the ASV of that region asdielectric substrate 612 sweeps over the well-defined edge boundary created byshield 614. - It is appreciated that alternating polarity
charge flow apparatus 610 may serve as an elongate alternating polarity charge (EAPCS) source described hereinabove in accordance with a modified version of dynamic charge retention techniques described herein. It is appreciated that alternating polaritycharge flow apparatus 610 may provide liquid 620 continuously todielectric surface 612. Thus, when an alternating polarity charge flow apparatus such as the one described herein in Fig. 11C is used as an EAPCS in dynamic charge retention techniques, it is desirable that the voltages applid to conductive backing (not shown) ofdielectric surface 612 are continuously refreshed. - This embodiment is presented to offer an example of possible embodiments of the EAPCS and is not intended to be limiting.
- Charge patterns retained on
dielectric substrate 612 in accordance with the techniques and apparatus described herein may be developed using dry or liquid toner to establish a visible image thereon. Developing may be carried out using developing apparatus (not shown) as is known in the art and as described hereinbelow. - In accordance with an embodiment of the present invention, liquid 620 may include one or more solvents which are operative to assist in cleaning and/or rinsing of
dielectric substrate 612. This is particularly effective when charge image created ondielectric substrate 612 is developed using a liquid toner as is known in the art and as is described hereinbelow. - It is appreciated that in accordance with this embodiment, deposition of charge and cleaning of residues from
dielectric surface 612 may be carried out simultaneously. - Reference is now made to Figs. 12A - 12C which illustrate a system for writing and developing electrostatic images in accordance with another embodiment of the present invention. The illustrated embodiment employs a
drum 700 having adielectric layer 702 on its outer surface, which is rotated in a direction indicated byarrow 704. - A plurality of conducting electrodes (not shown) are embedded in the
dielectric layer 702 and extend over the periphery of the outer surface of the drum.Electronic circuitry 706 may be mounted interiorly of the outer surface of the drum and oflayer 702, whereby each electrode may be connected to a driver forming part of thecircuitry 706. - Associated with
drum 700 and more particularly withdielectric layer 702 is acharge source 708, preferably of the type shown in any of Figs. 7A - 11A. A magneticbrush developer unit 710 and acleaning unit 716 are operatively associated withdrum 700 in a conventional manner. - The apparatus of Figs. 12A - 12C is particularly characterized in that charge image generation and developing may take place simultaneously at different regions of the drum. This is achieved by operating the
charge source 708 discontinuously, in a series of bursts, as indicated in Fig. 12B. - During each burst of the operation of
charge source 708, all of the electrodes embedded indielectric layer 702 receive appropriate voltages representing a single raster line of an image to be printed. Immediately following operation of thecharge source 708, i.e. in between the bursts shown in Fig. 12B, the drivers incircuitry 706 supply to each such electrode a voltage which is equal and opposite to the voltage applied thereto during the operation ofcharge source 708. - Fig. 12C shows the voltage on a given electrode both during the bursts of operation of the
charge source 708 and in between the bursts, in response to operation of the drivers incircuitry 706. - The result of these operations is that in each electrode, an electrical signal is generated which is composed of high Fourier frequency components and a zero DC component. The elimination of the DC component eliminates spurious operation of the magnetic brush developer unit 7l0 which would otherwise occur.
- It is further noted that when the
developer unit 710 employs dual-component toners the high Fourier frequency components in the signal also do not result in spurious toner deposition by thedeveloper unit 710. - In this way, the signals present on the electrodes during development by
developer unit 710 do not interfere with the desired development of the latent image on thedielectric layer 702, but operate only for desired latent image generation. - The toned image produced by
developer unit 710 is transferred to an output substrate, typically paper, by atransfer unit 712 and fixed to the output substrate by a fixingunit 714 using standard toner fixing techniques. Any residual toner on the outer surface of thedrum 700 is removed by thecleaning unit 716 using standard techniques. - Reference is now made to Figs. 13A and 13B which illustrate a system for writing electrostatic images in accordance with yet another embodiment of the present invention. The illustrated embodiment employs time multiplexing of the output of a limited number of drivers to a plurality of different arrays of individual charge sources, such as shown in Figs. 3A and 3B.
- As seen in Figs. 13A and 13B, a charge
source array assembly 800 includes a plurality of individual charge sources, which are indicated by the letters a - h and are seen to be arranged in staggered, mutually partially overlapping relationship with asubstrate 802 bearing a plurality ofelectrodes 804. The individual charge sources receive signal inputs from atime multiplexer 806 which in turn receives signal inputs from drivers (not shown). The individual charge sources a - h may be of the type illustrated in any of Figs. 7A - 11C. - In accordance with this embodiment,
electrodes 804 may be connected in primary groups which are then subdivided into secondary groups. The number of primary groups is a function of the number of charge source line arrays in chargesource array assembly 800. For example, in Fig. 13A, two charge source line arrays are shown, so two primary groups ofelectrodes 804 may be used. - The secondary grouping of each primary group of
electrodes 804 corresponds to the number of individual charge sources making up a single line array. For example, in Fig. 13A, there are four individual charge sources per line array, therefore each primary group ofelectrodes 804 is subdivided into four secondary groups. It is appreciated that theelectrodes 804 from each secondary group in a primary group are connected in parallel to a shared set of high voltage imaging electronics. By connectingelectrodes 804 in secondary groups, the number of outputs from, and therefore the volume of, high voltage imaging electronics is reduced. - Electrostatic charge patterns are written by sequentially activating each charge source of a first line array of charge
source array assembly 800. During activation of a charge source, voltage information is supplied toelectrodes 804 located beneath the active charge source. Voltage signals supplied to eachelectrode 804 are also supplied to allother electrodes 804 in the same subgroup. However, onlyelectrodes 804 underlying the active charge source will retain charge in accordance with the dynamic charge retention techniques described herein. - Charge sources in a single array are sequentially activated to write a charge image over the dielectric substrate associated with
electrodes 804 of an entire primary group. Whensubstrate 802 moves relative to chargesource assembly 800, the activation and charge writing cycle is repeated for the second primary group and its associated line array of charge sources:
It is appreciated that charge sources of chargesource array assembly 800 are arranged in an overlapping fashion. Furthermore, there exists overlap between primary groups ofelectrodes 804. Thus, the need for a high level of registration between chargesource array assembly 800 andsubstrate 802 is eliminated. - Reference is now made to Figs. 14A and 14B which illustrate a digital receptor imaging drum suitable for use in a variety of imaging applications including those described hereinabove and hereinbelow and in the copending applications referred to hereinabove, the description of which is hereby incorporated by reference.
- Fig. 14A shows a
drum 820 on whoseouter surface 822 latent electrostatic images may be generated in accordance with the dynamic charge retention image writing techniques described hereinabove and hereinbelow. - The
outer surface 822 includes portions which are imaging regions and other portions which are not imaging regions. Images are created at the imaging regions using an edge-defined alternating polarity charge source (not shown), and signals supplied to a conductive backing forming part of the drum. The charge source may be any suitable one of the charge sources described hereinabove, and particularly those illustrated in any of Figs. 7A - 11C. The conductive backing preferably comprises a plurality of electrodes. - Alternately, drum 820 may be used for image reading in accordance with techniques described hereinbelow and in Applicant's co-pending applications.
- Fig. 14B shows a cross section of an imaging region of the drum. The drum comprises an outer
dielectric imaging layer 824 which may extend over both the imaging regions and the non-imaging regions. At imaging regions, aconductive backing 826 is associated with the outerdielectric imaging layer 824. The conductive backing overlies aninner dielectric layer 828. Imaging electronics (not shown) are associated with the electrodes of theconductive backing 826. - The outer
dielectric imaging layer 824 can be made of any material that is suitable for use with theconductive backing 826. A suitable material may include dielectric polymeric-based materials, such as polyethylene terephthalate (PET, PETP), polyimides, or abrasion-resistant polysiloxanes. Alternatively inorganic materials, such as glass or ceramics may be used. It is appreciated that a photoconductive material could be used for outerdielectric imaging layer 824 in accordance with certain embodiments of the invention. - The
conductive backing 826 preferably comprises densely spaced thin conductive ring electrodes. The density of the electrodes, the transverse cross-sectional geometry thereof and the thickness of the outerdielectric imaging layer 824 determine the spatial resolution of the latent image in the axial direction parallel to thelongitudinal axis 830 of thedrum 820. -
Drum 820 preferably contains imaging electronics which preferably includes serial to parallel data conversion electronics and high voltage electrode drivers. - Alternatively or additionally, drum 820 may contain imaging electronics which include parallel to serial data conversion and transmission electronics; and sample and hold circuitry for sensing signal information from outer
dielectric imaging layer 824. It is appreciated that this type of imaging electronics is useful for image reading as described hereinbelow. - In accordance with some preferred embodiments of the present invention, imaging electronics also includes memory electronics which stores data representing one or more pages. The memory electronics is typically configured so as to comprise a data bus sufficiently long so as to be capable of providing parallel output to each of the high voltage electrode drivers.
- During image writing, page data may be input to the imaging electronics from a high-speed data bus as described hereinbelow and serially propagated to all of the high voltage electrode drivers. Alternatively, during image writing, page data which is stored in the memory electronics may be fed in parallel to the high voltage electrode drivers causing the same general image to be written repeatedly. It is noted that in accordance with a further mode of operation data input to the high voltage drivers may comprise a combination of data from memory with data from the high-speed data bus. Thus, certain portions of the data on the printed page will be varied from image to image , while certain portions will remain fixed until new page data is input from the high speed data bus.
- Use of memory electronics provides stored digital or electronic data which serves as an "electronic master" for multiple reproductions of the same general page. By loading the serial data input into memory once and then using parallel data feeding from memory to the electrode drivers for a defined number of similar pages, the speed of data propagation is significantly increased, thus increasing the entire image writing speed.
- It is appreciated that using an electronic master stored in memory electronics reduces the dependency of the writing speed on the external data transfer rate when generating numerous reproductions of the generally same image.
- External data representing the latent image to be generated may be supplied to the imaging electronics through one or
several connectors 832. It is appreciated thatconnectors 832 may be located additionally or alternatively on the faces of the drum or on adrum axle 834. Alternatively or additionally, data connections between the rotating drum and the stationary data source may be effected using slip rings (not shown), which may include mechanical, optical or conductive liquid based elements. Alternatively in accordance with certain configurations, where the drum does not complete full rotations, information may be transferred through a flexible cable. - The length of the drum along
axis 830 may be any desired length and is typically selected to conform to standard print formats, for example, standard A and B formats. - The printing properties of the drum, its durability, the speed of operation, the toning materials, the operating voltages and the print cycle are determined in part by the materials used in building the drum. For example, drums with an outer dielectric glass or ceramic imaging surface are expected to provide enhanced durability.
- In accordance with an alternate image reading embodiment of the present invention, outer
dielectric imaging layer 824 can be replaced by an outer photoconductive layer (not shown). In this embodiment, imaging electronics for image reading applications, as described hereinabove and hereinbelow, are required. - Reference is now made to Figs. 15A - 15D which illustrate four alternative arrangements of imaging regions on the cylindrical surface of
drum 820. - As noted above, the surface of
drum 820 comprises one or more imaging regions with the remaining surface of the drum not being active in the imaging process. The size of the non- active surface area is selected to achieve the desired drum diameter in accordance with a desired print cycle and print engine configuration. The division between imaging and non- imaging regions thus depends on the printing cycle, printing speed and other characteristics of a given printing engine. Possible configurations include, for example: - 1. A single imaging region extends across less than half of the drum surface. One printing cycle is carried out per complete drum rotation. In this case, the drum typically continuously rotates in a single direction. This embodiment is shown in Fig. 15A where the conductive backing is indicated by
reference numeral 836. - 2. Two distinct independent imaging regions are separated by non-imaging regions. Two printing cycles are carried out per complete drum rotation, one cycle for each imaging region. In this case, the drum typically continuously rotates in a single direction. This embodiment is shown in Fig. 15B where the conductive backing portions are indicated by
reference numerals - 3. A single imaging region extends across most or all of the drum surface. Each printing cycle is accomplished by several rotations of the drum. In this case, the drum typically continuously rotates in a single direction. Alternatively, a printing cycle may be carried out by a combination of clockwise and counterclockwise rotations of the drum. These embodiments are shown in Figs. 15C and 15D, where the conductive backing portions are indicated by
reference numerals - Typically, the imaging regions and non-imaging regions have similar external appearance. Alternatively, the regions may be externally distinguishable.
- Reference is now made to Figs. 16A - 16E which illustrate preferred interior structures for
drum 820. Referring first to Fig. 16A, it is seen that the drum, indicated byreference numeral 846, comprises aconductive backing 847 comprising closely spacedelectrodes 848 embedded in adielectric substrate 850, imaging electronics located on primary printedcircuit boards 852 located interior of the drum andconnectors 854 connecting theelectrodes 848 to the printedcircuit boards 852. Theelectrodes 848 andconnectors 854 are shown in Fig. 16A with exaggerated dimensions and spacing. In reality, each electrode has a width of approximately 20 - 40 microns and the electrodes are separated from one another by a spacing of approximately 10 - 20 microns. Theconnectors 854 may be pads formed by printed circuit techniques. In reality, the width of eachconnector 854 is typically on the order of 100 microns and the gap between connectors is also typically on the order of 100 microns. - The
dielectric substrate 850 havingelectrodes 848 embedded therein may be fabricated by any suitable technique including, for example, techniques mentioned hereinabove. - Two general methods for producing the
conductive backing 847 of the imaging region of the drum are described hereinbelow with reference to Figs. 16C and 16D. -
Drum 846 comprises animaging region 856 which extends across most of the drum surface and anon-imaging region 858.Non-imaging region 858 covers theconnectors 854 which connectconductive electrodes 848 to primary printedcircuit boards 852. Each primary printedcircuit board 852 typically contains a single line array ofconnectors 854. - Typically, primary printed
circuit boards 852 are shaped to fit insidedrum 846. The line array ofconnectors 854 of each printedcircuit board 852 is positioned for exposure through anarrow slot 860 in the drum surface, which slot extends parallel to the longitudinal axis ofdrum 846. The number ofslots 860 may correspond to the number of primary printedcircuit boards 852. Alternately, eachslot 860 may correspond to more than one primary printedcircuit board 852. - Imaging electronics, including digital serial-to- parallel data transfer and high-voltage electrode drivers, may be located on a non-connector section of printed
circuit board 852. The non-connector section of primary printedcircuit boards 852 may be flexible or rigid depending on the drum structure and diameter. - Reference is now made particularly to Fig. 16B which shows an alternative inner configuration of
drum 846. In this configuration, two sets of parallel printed circuit boards are used, aprimary set 862 and asecondary set 864. Each printed circuit board inprimary set 862 is connected to a plurality of conductive electrodes 848 (Fig. 16A) by means of a single line array of connectors. Preferably, the primary set of printedcircuit boards 862 does not contain any electronic components. Instead, the primary set of printedcircuit boards 862 serves only as an interconnection betweenconductive electrodes 848 and the secondary set of printedcircuit boards 864. - Alternatively, a pre-formed rigid base, comprising any suitable dielectric material (for example ceramic, glass, anodized aluminum, etc.) with a surface pattern created using a conductive material (for example copper, gold, etc.) may be used in place of the primary set of printed
circuit boards 862. - The secondary set of printed
circuit boards 864, which may be made of a flexible or rigid material, comprises imaging circuitry and a set of connectors. The number and layout of connectors on the secondary set of printedcircuit boards 864 corresponds to that on theprimary set 862. - Electrical connection in registration between the connectors of the printed circuit boards of the
primary set 862 and of thesecondary set 864 may be effected using elastomeric high density contact arrays (zebra connectors) 866. Alternately, any other suitable method for generating high density electrical connections between the two sets of printed circuit boards may be used. - It is appreciated that connectors may be placed on one or both sides of the printed circuit boards of the
primary set 862. Typically, contact between the set of connectors on the primary and secondary sets may be carried out through application of pressure. - It is appreciated that the number of printed
circuit boards 864 comprising the secondary set may be determined in accordance with the specific mechanical structural considerations ofdrum 846 and design considerations of the printed circuit boards. For example, numerous secondary printedcircuit boards 864 could be arranged in a cascade and connected to one printed circuit board of theprimary set 862 allowing for simplification of each secondary printedcircuit board 864. - It is further appreciated that in accordance with this configuration, printed circuit boards of the
secondary set 864 are removable fromdrum 846 by releasing the pressure holding the connectors. Thus, the outer part ofdrum 846 may be replaced without necessitating replacement of thesecondary set 864 of printed circuit boards or of the imaging electronics formed thereon. - Reference is now made to Fig. 16C which illustrates
conductive electrodes 848 ofdrum 846 at an intermediate stage of fabrication. - A
conductive wire 868 is tightly wrapped around aninner dielectric surface 850 ofdrum 846 resulting in a coiling of the wire into spacewound rings aboutsurface 850 with a very precise pitch. Prior to wrapping the wires, a thin adhesive layer (not shown) may be adhered to theinner dielectric surface 870 of thedrum 846 to ensure proper alignment and spacing of the wires. - The wires should exhibit sufficiently high electrical conductivity combined with mechanical strength so as not to tear during the winding process. The wires may be made of stainless steel, copper alloys, tungsten, etc. and may be uncoated. Alternatively, the wires may be coated with an insulating material such as glass or alternatively with a polymeric coating such as polyurethane, polyimide, etc. The actual material for the wire and for its coating are selected to best suit the fabrication process, the desired properties of the printing device and other materials used in production.
- The pitch of the coil is selected to match the spacing of
connectors 872 of the first primary printedcircuit board 876 which is located in aslot 877. The wire is coiled until eachconnector 872 is located in contact with an individual turn of the wire. Primary printedcircuit boards 878 may be of the type described above in conjunction with Fig. 16A or Fig. 16B. - After the wire is coiled so that each
connector 872 of the first primary printedcircuit board 876 is located in contact with an individual coil of the wire, the wire is bonded toconnectors 872. Bonding may be accomplished by parallel gap bonding techniques. Alternatively, bonding may be carried out by employing reflow wire soldering techniques using hot rams, or non-contact hot air jets. Where necessary, the insulating coating may be stripped off the segments of the wire that are located in the connector region, during or after the winding process. For wires with a solderable coating, stripping may be carried out during the soldering process. Additionally, or alternatively any other suitable bonding technique may be used. - In accordance with a further embodiment of the invention,
connectors 872 of the primary printedcircuit boards 876 may be precoated with a predetermined amount of soldering material per connector, for example, thin-lead solder. This method facilitates the bonding process for fine-pitch soldering. - After the wire has been bonded to all the corresponding connectors in a
single line array 874, a thin layer of dielectric material encapsulates theline array 874 ofconnectors 872 to electrically insulate them from each other. - The wire coil is then cut parallel to the drum axis adjacent both sides of an
adjacent slot 879. The cuts disconnect from each other adjacent portions of the coil in electrical contact with adjacent connectors of a givenline array 874. The result is an array of precisely spaced mutually electrically-insulated conductive rings each of which is separately connected to a separate connector forming part ofarray 874. These rings constitute some of the electrodes of the present invention. Additionally, the cuts remove those portions of wire which would otherwise extend over anadjacent line array 880 ofconnectors 882 of an adjacent primary printedcircuit board 884. - After the above steps have been completed on the first primary printed
circuit board 876, they are repeated for every primary printedcircuit board 878 typically continuing until each connector on each primary printed circuit board is in electrical contact with a wire. The spacing between connectors in each single line array on each primary printed circuit board is constant. However, the first connector and thus all subsequent connectors in the line array on each primary circuit board are staggered along an axis parallel to the longitudinal axis of the drum slightly relative to the connectors of each adjacent primary printed circuit board. - The number of connectors used, which determines the pitch of the winding, can be varied to achieve different spatial resolutions along the drum axis direction. Using several primary printed circuit boards and several sequential corresponding winding steps enables high spatial resolution of the conductive electrodes to be realized while enabling relatively lower resolution to be employed for the connectors, which resolutions are better suited to printed circuit board manufacturing and bonding processes. Alternatively, when lower resolutions are required, or when otherwise desirable, a single primary printed circuit board can be used.
- Densities greater than 600 lines (wires) per linear inch can be achieved using this technique, as can be appreciated by a consideration of the examples shown in Figs. 16A, 16B and 16C, where four primary printed circuit boards and 1600 connectors are employed in association with each primary printed circuit board.
- Alternatively, the
conductive backing 847 ofdrum 846 may be prepared by other techniques which allow the creation of densely packed conductive electrodes. - Reference is now made particularly to Figs. 16D and 16E, which illustrate an alternative configuration of the conductive backing and the inner structure of
drum 820 in accordance with an embodiment of the present invention. - The conductive backing comprises a
multi-layer blanket 886 which includes aflexible dielectric carrier 890 and afurther layer 894 on which is formed a plurality ofconductive electrodes 896, where the electrodes terminate in a fan outarray 898 of connectors.Conductive electrodes 896 together with fan outarray 898 may be produced onlayer 894 by photoetching, plasma etching, laser etching, mechanical etching, electroforming or a combination thereof. -
Blanket 886 is wrapped aroundinner layer 828 ofdrum 820, with each blanket end being inserted into aopening 902. Fan outarrays 898 at the blanket ends are aligned with a secondary set of printedcircuit boards 904 that are located withindrum 820. Fan outarrays 898 at each blanket end may comprise one ormore contact regions 906. Through thecontact regions 906, electrodes ofblanket 886 are electrically connected to secondary printedcircuit boards 904. Typically, the electrical connection may be made using elastomeric contact arrays as described hereinabove. Alternately any other high density connectors may be used.Blanket 886 eliminates the need for a set of primary printed circuit boards. A thin adhesive layer may be used to ensure adhesion ofdielectric carrier 890 to druminner layer 828. - After a conductive backing has been produced by any of the methods described hereinabove with reference to any of Figs. 16A - 16E, or by any suitable alternate method, outer
dielectric surface 824 is formed. Outerdielectric surface 824 is created by coatingconductive backing 826 with a dielectric layer or layers resulting in a uniform smooth outer layer with predetermined total thickness. - The capacitance of outer
dielectric surface 824 is determined by the dielectric constant of the material or materials used in the coating process and the accumulated thickness of all of the coating layers. - Typically, the total thickness of outer
dielectric surface 824 is between 10 - 50 microns. The capacitance of outerdielectric surface 824 plays an important role in determining the final resolution of the latent image and the maximum charge density that can be accumulated on the surface per the voltage applied to the conductive backing. - In addition to its dielectric properties, the material used for the outer dielectric coating should have appropriate surface energy, be sufficiently durable and abrasive resistant.
- Various techniques may be used to create outer
dielectric imaging layer 824 ofdrum 820. The specific method used is chosen to conform to the configuration ofconductive backing 826 and the specific materials used. Prior to coating, the surface ofconductive backing 826 may be chemically treated to prepare for coating with one or many thin dielectric layers. - Coating techniques may comprise fog spraying of dielectric polymeric-based solutions or dispersions. Typically, fog spraying is carried out while the drum is rotating. Alternatively, coating may be carried out using dip or roll coating techniques. Depending on the material of the conductive electrodes, either dip or roll coating (with a polymeric based solution, dispersion or two components) or hot melt dip or roll coating (using dielectric thermoplastic materials or glass) may be used.
- After coating, each dielectric layer may be hardened using evaporation, a thermal process, or curing via radiation or heat, depending on the coating material used.
- After all dielectric layers have been coated and hardened, a smooth uniform outer
dielectric imaging layer 824, having an embeddedconductive backing 826, remains. - Alternatively, outer
dielectric surface 824 may be created by a rough casting of polymeric based materials or sintering of ceramics inside a preformed container. After the casting or sintering is complete, the container is removed, and all unnecessary coating material is machined away leaving a coating with a specified even thickness and a smooth outer layer. - Furthermore, outer
dielectric surface 824 may be created by deposition techniques, including vacuum or plasma deposition to deposit a suitable dielectric material. Typically, deposition is carried out while the drum is rotating. - Alternatively, coating techniques may comprise spreading of a dielectric adhesive onto the electrodes of
conductive backing 826, thus filling all gaps. A thin dielectric film (such as polyester based films) of predetermined thickness may then be wrapped around the entire drum surface and pressure laminated to the conductive wires/adhesive surface. Following this step, the adhesive is cured leaving a flat dielectric outer imaging surface adhered to the electrodes. - Optionally any and all of the drums described herein may be provided with an additional thin dielectric outer coating, which preferably is disposable and easily replaceable. This coating, which may be formed of polyethylene terephthalate (PET, PETP) or any other suitable material, may have a thickness in the general range of 10 microns.
- In accordance with an alternate embodiment of the present invention, for image reading applications, an outer photoconductive layer (not shown) may be formed over the electrodes of
conductive backing 826 by any suitable techniques. - Reference is now made to Fig. 17A which is a simplified schematic illustration of the imaging electronics of the printed circuit boards. The imaging electronics comprise a
cascade 909 of multi-channel serial to parallel devices outputting todrivers 910. Eachdriver 910 provides a high voltage output, in the range of up to several hundred volts, which drives a separateconductive electrode 912. - Data is input serially from an external data source, such as a computer, copier, scanner or facsimile receiver, to the imaging electronics via a
data bus 913. Serial data, representing a pattern which is to be generated on the outer dielectric imaging surface of the drum, is typically fed todata bus 913 in 1, 8 or 10 byte words. - The data propagates along the
cascade 909 of multi- channel serial to parallel converting devices. A single output of each device withincascade 909 corresponds to eachconductive electrode 912. For example, if the conductive backing of a drum contains 6400 conductive electrodes, one hundred 64-channel devices or two hundred 32-channel devices may be employed in thecascade 909. Typically, the devices are evenly distributed over the printed circuit boards on which the imaging electronics are located. - After data representing one raster line of a pattern to be generated has been serial loaded across the cascade of multi- channel serial to
parallel converters 909, the data is loaded in parallel tohigh voltage drivers 910. Based on the data,high voltage drivers 910 apply appropriate voltages to the electrodes. - Simultaneous with the application of the voltages to
conductive electrodes 912, an Elongate Alternating Polarity Charge Source (EAPCS), of the type described in any of Figs. 7A - 11C, is activated. It is appreciated that when an EAPCS of the type described in Fig. 11C is used, continuous operation as described herein is used. - The EAPCS may be placed in proximity to the outer dielectric imaging surface of a drum, such as
drum 820 of Fig. 14A or drum 846 of Fig. 16A, and includes at least one well-defined edge. The EAPCS is positioned so that, during drum rotations, the trailing edge of the EAPCS is a well-defined edge. Charge is not supplied by the EAPCS to areas of the outer dielectric imaging surface of the drum that are beyond the edge of the EAPCS. - The EAPCS may be activated for a pulse duration containing tens of plasma cycles. This activation supplies charges to the outer dielectric imaging surface. The final charge retained on the outer dielectric imaging surface of the drum is a dynamic function which corresponds to the voltage signals applied to
conductive electrodes 912 over the pulse duration. The area of charge retention is bounded by the defined edge of the EAPCS. - During EAPCS activation, data representing the next raster line of the image to be generated is serially loaded into
cascade 909, but the data is not forwarded tohigh voltage drivers 910. - Prior to application of voltages corresponding to data for a subsequent raster line of the image, the drum rotates slightly to position the EAPCS for the next line. After rotation of the drum, the new line data is sent to
high voltage drivers 910 and the EAPCS is activated, again causing retention of a new amount of charge, positive or negative, corresponding to the new line data that was fed to the devices. Areas that are beyond the generally linear boundary created by the defined edge of the charge source do not receive additional charge. Instead, they retain the charge that was previously accumulated. - The above-described line writing cycle repeats itself until a latent image of the entire pattern is generated.
- Alternatively, the EAPCS may be operated continuously during the latent image generation process. During continuous operation of the EAPCS, the apparent surface voltage (ASV) of the outer dielectric surface is continuously refreshed, thus the retained charge pattern is continuously refreshed. Conversely, when the EAPCS is operated in pulses, the ASV is supplied in bursts, with the retained charge pattern being refreshed during time intervals whose length determines the dimension of a single raster line of the image in the direction in which the drum rotates.
- Reference is now made to Fig. 17B which is a simplified schematic illustration of imaging electronics of the printed circuit boards for use in reading electrostatic charge images. The imaging electronics comprise sample and hold
circuitry 915 which supply output to acascade 917 of multi-channel parallel to serial data conversion and transmission devices. Each sample and holdcircuit 915 receives input from aconductive electrode 912. - A
data bus 918 serially outputs data to an external data collector. Eachconductive electrode 912 is electrically connected to a sample and holdcircuit 915, which are typically evenly distributed over the printed circuit boards on which the imaging electronics are located. - The data output by
data bus 918 represents digital information corresponding to an electrostatic charge image which was read from the outer dielectric imaging surface of the drum in accordance with techniques described herein. - It is appreciated that the image to be read may be written onto the dielectric outer imaging surface using the dynamic charge retention techniques described herein or any other suitable technique for generation of latent charge images. For example, when the outer dielectric imaging surface is a photoconductor as described hereinabove, a charged latent image can be created on the surface using conventional electrophotography techniques.
- An additional benefit to the image reading techniques described herein is that the reading process effectively erases and uniformly charges the outer dielectric imaging surface in a single step, pre-conditioning the outer dielectric imaging surface. Such pre-conditioning is not necessary when writing images using the dynamic charge retention techniques described herein, but is required prior to the projection of optical images on a photoconductor.
- An Elongate Alternating Polarity Charge Source (EAPCS), of the type described in any of Figs. 7A - 11C, is placed adjacent an outer dielectric imaging surface of a drum , such as
drum 820 of Fig. 14A or drum 846 of Fig. 16A. It is appreciated that during drum rotations for image reading, the leading edge of the EAPCS is a well-defined edge. The EAPCS does not supply charge to areas of the outer dielectric imaging surface of the drum that are beyond the leading edge. - To read a single line of information from outer dielectric imaging surface, the EAPCS may be activated for a pulse duration containing tens of plasma cycles. This activation unifies the charge level across one line of the electrostatic charge pattern, erasing that line of the pattern, and inducing a current flow from each
conductive electrode 912 to a capacitor (not shown) in the corresponding sample and holdcircuits 915. During each line reading cycle, the total charge flow into each sample and holdcircuit 915 is a function of the charge density level that was present at the location on the outer dielectric surface corresponding to theconductive electrode 912 connected to the sample and holdcircuit 915, prior to activation of the EAPCS. - The charge level retained on the line of the outer dielectric imaging surface after line reading is a function of the bias voltage applied to the conductive electrodes during line reading. Typically
conductive electrodes 912 are grounded during line reading. Alternately,conductive electrodes 912 may be biased to a predetermined bias voltage level. It is appreciated that the same level of voltage is typically applied to allconductive electrodes 912 during reading. - Signals from all the sample and hold
circuits 915 are output in parallel to acascade 917 of multi-channel parallel to serial data conversion and transmission devices.Cascade 917 provides digital output data representing one line of the image that was present on outer dielectric imaging surface. Data onoutput bus 918 typically comprises one or eight bits of information, representing 2 or 256 grey levels, respectively. - The above-described line reading cycle repeats itself until digital information representing the entire electrostatic charge image to be read is collected.
- During pulse operation of the EAPCS, the pulse duration is synchronized with the sample and hold circuit cycle. The duration of the pulse defines the dimension of the raster line of the image that is being read.
- Alternatively, the EAPCS may be operated continuously during the image reading process. During continuous operation of the EAPCS, the dimension of a single raster line of the image being read is determined by the sample and hold circuit cycle.
- It is appreciated that the abovedescribed image reading techniques may provide numerous functions including optical scanning and reading, and electrostatic information storage.
- Reference is now made to Fig. 18 which illustrates an image pattern comprising a plurality of
pixels 919 alongconductive electrodes 912, where the charge density of each pixel is determined by input data. - It is appreciated that the imaging electronics may be configured for different methods of achieving grey shades for printing images. Specific printing methods may include optical density modulation or pixel size modulation and micropositioning as described hereinabove, all of which are compatible with the drum configuration and imaging techniques described hereinabove. It is appreciated that a large number of grey shades can be achieved without resolution sacrifices thereby allowing print outs which combine high quality text, graphics and images.
- Optical density modulation allows images to be created by controlling the amount of toner, hence the shade, of each pixel. Alternately, images may be created using super-pixel half-tone patterns, where each super-pixel comprises several pixels and where each pixel is either toned or non-toned. In addition, micropositioning of each pixel may be combined with super pixel half tone pattern techniques.
- It is further appreciated that in accordance with the writing techniques described herein, the imaging electronics and the level of high voltage employed can accommodate a variety of toners and toning techniques, including liquid and dry toners.
- One method for achieving continuous tone
images using drum 820 and the writing techniques described hereinabove is described hereinbelow. - Through amplitude modulation of the voltages applied to the
electrodes 912 by thedrivers 910 during EAPCS activation, the total amount of charge retained may be precisely determined. - A charge pattern containing a two-dimensional array of pixels, where the charge density for each pixel can be selected, is created using the latent image writing techniques and drum described hereinabove. Each pixel is defined as the minimum unit that can be addressed in a line. The number of pixels in the direction of the longitudinal axis of the drum is equal to the number of conductive electrodes therein. The shape of the pixels is determined by the geometry of the conductive electrodes, the thickness of the outer dielectric layer, and the edge definition of the EAPCS. Using appropriate toners and toning techniques, a continuum of shades can be achieved for each pixel.
- A benefit of creating continuous tone images using the writing techniques and drum described hereinabove is that the total charge density at any pixel location is a function of the voltage applied to the conductive electrode during EAPCS activation. Therefore, the charge density is not sensitive to environmental factors, such as temperature, humidity, light, etc. Typically, line-printing techniques, for example LED Arrays in electrophotography, ion guns in ionography, are based on imagewise writing heads which are typically composed of pixel- sized writing sources. Dissimilarities between any of the pixel- sized writing sources comprising an imaging head may result in image non-uniformities.
- The line printing techniques described herein do not employ an imagewise writing head. Instead, the charge density for each pixel location is determined by the voltage applied to the conductive electrodes. Ordinary fluctuations in the charge source do not cause non-uniformities in the image. Therefore, the charge density can be closely controlled and repeatability is achievable.
- Reference is now made to Fig 18A which illustrates an example of the circuitry of basic continuous tone imaging apparatus that can be used to perform amplitude modulation for each
conductive electrode 912. Fig. 19A depicts one preferred embodiment of the apparatus of Fig. 17A, which is particularly suitable for use in generating continuous tone images. - The basic circuitry typically comprises one among a multiplicity of units which make up the cascade 917 (Fig. 17A). Typically, for high quality continuous tone imaging, 8 bit inputs to the data bus are used, where each 8-bit data word corresponds to the desired voltage level for one conductive electrode. When 8-bit word input is used, 256 different voltage levels are available for each conductive electrode corresponding to 256 different shades for each pixel. Since up to four different latent images, one representing each different print color, such as cyan, magenta, yellow, black, may be used for each final color print image, 256 shades for each color translates to millions of possible color combinations.
- Data is serially loaded from
data bus 913 and propagated at a high rate, typically usingloading clock 922, which operates at few tens of MHz, into each data latch 924 of each device. Each data latch 924 corresponds to onesecondary latch 926 and oneoutput voltage stage 928. - Once an entire line of data has been loaded into the data latches 924, the line data is transferred in parallel from data latches 924 to
secondary latches 926. Transferring the data tosecondary latches 926 allows new data representing the next line of the image to be loaded into the data latches 924. Concurrently, all data insecondary latches 926 undergoes a parallel digital to analog high voltage conversion. - The outputs of
secondary latches 926 are supplied to respective gate buffers 927. The outputs of gate buffers 927 are supplied to respective output stages 928. Acontrol unit 930 controls the timing and triggering of the subsystems in each device. - The conversion cycle begins by setting a
binary reference counter 934 on each device to 00000000. In predefined increments, a clock signal is sent fromcontrol unit 930 to reference counter 934incrementing reference counter 934 by units of 1 until a maximum level of 11111111 is reached. Each increment is associated with one of 256 possible output levels. - Reference is now made to Fig. 19B which is a detailed circuit diagram of a
possible output stage 928 of the basic continuous tone circuitry apparatus of Fig. 19A. It is appreciated that other circuits which perform a multi-channel digital to high voltage analog conversion may also be used. - At
output stage 928, which employs high-voltage CMOS technology, digital data fromsecondary latch 926 is converted to an analog output voltage Vout as follows:
A ramping voltage Vref, typically of up to 600 Volts, is applied tooutput stages 928 of all devices incascade 917. Voltage Vref is switched via chargingtransistors 936 causinghold capacitors 938 in eachoutput stage 928 to experience a rise in voltage. - Each time the value in
reference counter 934 is incremented, the digital information insecondary latch 926 associated with eachoutput stage 928 is compared with the value inreference counter 934. Whenreference counter 934 reaches the value held bysecondary latch 926, the chargingtransistor 936 is switched off thereby terminating charging of thehold capacitor 938 of thatoutput stage 928. - When charging
transistors 936 are switched off, Vref may still be ramping. Voltage Vg at the gate ofvoltage follower 940 begins to ramp and continues ramping at the same rate as voltage Vref. Sincevoltage follower 940 acts as a follower of Vg, the output voltage Vout also begins to ramp at the same rate as Vg and Vref. When Vref reaches its peak and begins holding, Vg also reaches its peak and begins holding. Vout follows Vg and reaches its peak at the same time. The overall effect of this operation is a conversion of the digital data to an analog high voltage output value Vout. - An advantage to the stage described hereinabove is that there is no cross-coupling between different channels, since all of the outputs reach their peak voltages at the same time.
- Typically, Vout is maintained constant across
conductive electrodes 912 during the EAPCS activation. Once the EAPCS is made non-active, Vref is reduced to zero, allowinghold capacitors 938 to discharge, thereby discharging the correspondingconductive electrode 912. The total charge accumulated on a given region of theconductive electrode 912 prior to discharge is determined by the data input to data latch 924 associated with thecorresponding output stage 928. After Vref rises back to its normal level, a conversion cycle for the next line of data is begun. - Reference is now made to Fig. 20 which illustrates a half-tone image pattern comprising a plurality of
pixels 950, delimited by dashed lines, along conductive electrodes 912 (Fig. 17A). The image pattern may be generated using pulsewidth modulation techniques and image writing techniques described hereinabove where an EAPCS is activated continuously during the image writing cycle. - Pulsewidth modulation includes controlling the fractional area to be charged in each
pixel 950 and micropositioning of the charged areas withinpixel 950. In the example shown, the charged areas of the pixel are shaded and the substantially uncharged areas appear unshaded. Typically, the charge density in charged areas is the saturation level corresponding to the voltage applied toconductive electrodes 912. - Reference is now made to Figs. 21A and 21B which illustrate an example of basic pulsewidth modulation imaging apparatus that can be used to perform pulsewidth modulation for imaging pixels generated on conductive electrodes 912 (Fig. 17A). Figs. 21A and 21B depict a further preferred embodiment of the apparatus of Fig. 17A which is particularly suitable for use in generating half tone images having multiple gray levels.
- The basic circuitry typically comprises one among a multiplicity of units which make up the cascade 917 (Fig. 17A). Typically, for half-tone images with multiple gray levels, 10 bit inputs to the data bus may be used. Eight of the ten bits represent 256 possible levels for the fill fraction of each pixel. The remaining two bits represent four possibilities for micropositioning of the fill area within the pixel. Alternatively, any other suitable multi-bit input data combination may be used, with certain bits representing the fill fraction and the remaining bits representing the positioning.
- Micropositioning of the fill area is used to achieve images having high spatial frequency. High spatial frequency enhances the appearance of toned images and enables simulation of continuous tone in half-tone images. Four possibilities for micropositioning represents a reasonable minimum necessary to ensure desirable variation in the fill location at adjacent pixels located on adjacent conductive strips as described in Fig. 6A - 6C above. For a fill area that is greater than half the pixel area, the location may be adjacent the leading or trailing edge of the pixel. For a fill area that is less than half the pixel area, the location typically begins or ends at the middle of the pixel and extends towards the leading or trailing edge.
- Conversion of input data to voltages on the
conductive strips 912 by means of pulse width modulation is preferably carried out as described hereinbelow:
Data is serially loaded from adata bus 952 and propagated at a high rate, typically usingloading clock 954 which operates at a few tens of MHz, into each data latch 956 of each unit incascade 917. Each data latch 956 corresponds to one secondary latch 958 comprising a converter and comparator and oneoutput stage 960. Once an entire line of data has been loaded into data latches 956, the line data is transferred in parallel from data latch 956 to secondary latches 958. - Transferring the data to secondary latches 958 allows new data representing the next line of the image to be loaded into data latches 956. Based on the above-described positioning bits, the data in secondary latches 958 is typically converted to two words describing the beginning and end locations of the fill region of the pixel.
- The outputs of secondary latches 958 are supplied to respective gate buffers 966. The outputs of gate buffers 966 are supplied to respective output stages 960. A
control unit 964 controls the timing and triggering of the subsystems in each device. - The conversion cycle begins by setting a
binary reference counter 962 on each device to 00000000. In predefined increments, a clock signal is sent fromcontrol unit 964 toreference counter 962, incrementingreference counter 962 by units of 1 until a maximum level of 11111111 is reached. Each increment is associated with one of 256 possible pulse width outputs. - Each time the value in
reference counter 962 is incremented, the two word digital information in secondary latch 958 associated with eachoutput stage 960 and the value inreference counter 934 are compared. Whenreference counter 962 reaches the value held by secondary latch 958 for the beginning location of the pixel fill area, a signal is sent from secondary latch 958 tooutput gate buffer 966 and the output stage voltage increases to VHV. Whenreference counter 962 reaches the value held by secondary latch 958 for the end location of the pixel fill area, a signal is sent from secondary latch 958 tooutput gate buffer 966 and the output stage voltage goes to ground. - Typically
output stage 960 comprises push-pull high voltage MOSFETS capable of sinking and sourcing current fromconductive electrodes 912 to which the output stages 960 are connected. - It is appreciated that half-tone color images can be generated by creating one half-tone image for each of the four printing colors.
- It is further appreciated that during half-tone printing using the pulsewidth modulation imaging techniques described hereinabove, relatively large numbers of grey levels are achieved without reducing spatial resolution. Typically, half-tone techniques using super-pixel and screening methods require a tradeoff between the number of gray levels and the spatial resolution.
- Reference is now made to Fig. 22 which illustrates an example of circuitry of basic apparatus that can be used to generate an alternate type of half-tone image on
conductive electrodes 912. Fig. 22 depicts a further preferred embodiment of the apparatus of Fig. 17A which is particularly suitable for use in generating super-pixel half tone images based on screening methods. - The basic circuitry typically comprises one among a multiplicity of units which make up the cascade 917 (Fig. 17A). Typically, each such unit receives a one-bit input from a
data bus 970. Based on the binary information supplied by the data bit, eachconductive electrode 912 receives either high voltage or low voltage during the EAPCS activation. In this embodiment, the EAPCS can be activated in pulse mode or continuous mode. - Data is serially loaded from a
data bus 970 and propagated at a high rate, typically using aloading clock 972 which operates at few tens of MHz, into ashift register 974. Once all the data for one line has been loaded intoshift register 974 of all units in thecascade 917, the data is transferred in parallel tosecondary latches 976. A signal is sent from asecondary latch 976 to anoutput gate buffer 978 indicating whetheroutput stage 980 should apply high or low voltage toconductive strip 912. - Typically
output stage 980 comprises push-pull high voltage MOSFETS capable of sinking and sourcing current fromconductive electrodes 912 to which the output stages 980 are connected.Output stage 980 may be of the type shown in Fig. 21B. - Reference is now made to Fig. 23 which is a schematic illustration of printing engine apparatus which may be incorporated into a variety of printer and digital copy systems. The printing engine apparatus, which may be used for tandem or satellite systems, is based on use of a digital input electrostatic (D/E) imaging drum as described hereinabove and is characterized by its ability to provide high quality text, graphics, and images using continuous tone or half tone imaging techniques. These imaging techniques may include modulation of the optical density of each pixel or modulation of the pixel dimensions as described hereinabove or any other suitable technique that is capable of providing a large number of grey levels.
- The printing engine apparatus comprises an
imaging drum 1010, having a dielectricouter surface 1011, and a latentimage generation unit 1012 which creates electrostatic latent images on the dielectricouter surface 1011 ofimaging drum 1010 in accordance with the techniques and latent image generation methods and using the apparatus described hereinabove and/or in one or more of applicant's co-pending patents and patent applications including U.S. Patents 5,289,214 and 5,157,423 and U.S. Patent Applications 12939, 12466). - Typically, the printing engine apparatus further comprises subsystems for image developing, image transfer, image fixing and cleaning of residual toner from
imaging drum 1010. A step of electrostatic preconditioning of the dielectric outer surface of a drum prior to writing of a latent charge image, typically associated with standard electrostatic imaging techniques, is eliminated when using the latent image generating techniques described herein. - In Fig. 23, each subsystem is depicted as an individual unit with a developing unit being indicated by
reference numeral 1016, a transfer unit being indicated byreference numeral 1018, a fixing unit being indicated byreference numeral 1020 and a cleaning unit being indicated byreference numeral 1022. Developing, transfer, fixing and cleaning techniques may be selected in accordance with the printer or digital copy system being used and in accordance with the desired printing medium, print quality, and process speed. - Developing
unit 1016 is operative to develop an electrostatic latent image present on dielectricouter surface 1011 ofdrum 1010 to a visible toned image by application of liquid or dry toner. Developingunit 1016 may comprise one or several developing elements where each developing element applies a unique toning color. - The printing engine apparatus may be adapted for use with the differing developing voltage requirements of a multitude of toners. This is due to the fact that the image generating techniques which are used to create latent images on the dielectric
outer surface 1011 ofimaging drum 1010 can be adapted to a variety of apparent surface voltage ranges, as described hereinabove. - Either dry powder toner or liquid toner may be applied by developing
unit 1016, with the precise structure of developingunit 1016 being selected in accordance with the type of toner used and the specific printer requirements. - Types of dry powder toners which may be used in the developing
unit 1016 include monocomponent dry powder toners, of assorted size distributions. Specific types of toner may include both conductive and dielectric monocomponent toners such as those described in "Trends in Imaging Materials for Color Hardcopy", by D. Wilson, SPIE Vol. 1253 Hard Copy and Printing Materials, Media and Process (1990). Generally, when using dry powder toner, contact between developingunit 1016 and dielectricouter surface 1011 is required. - In place of monocomponent dry powder toners, dual component dry powder toners such as those described in the aforesaid SPIE article may be used. When dual component dry powder toners are used, the developing
unit 1016 may operate using non-contact developing techniques such as described, for example in U.S. Patent 4,746,589 entitled Developing Method in Electrophotography Using Oscillating Electric Field to Haneda et al. - According to a further alternate embodiment, electrostatic liquid toners may be used in the developing
unit 1016. Liquid toners having various types of colloidal dispersions with various size distributions, rheologic and fixing properties may be used. Primary fixing properties of the liquid toners may include drying by evaporation, heat and pressure fixing. -
Transfer unit 1018 is operative to transfer the visible toned image from the dielectricouter surface 1011 ofimaging drum 1010 to a print medium (not shown). A variety of techniques may be used to transfer the toned image fromimaging drum 1010 to the print medium. Examples of such techniques are briefly described hereinbelow:
A monochrome image (typically cyan, yellow, magenta, or black) is developed on the dielectricouter surface 1011 ofimaging drum 1010 in accordance with the steps described hereinabove. After developing, the monochrome image is transferred from the dielectricouter surface 1011 ofimaging drum 1010 directly to print medium. The transfer may be carried out electrostatically, mechanically, or through a combination thereof. - To generate color images, several monochrome images (such as cyan, yellow, magenta, or black) may be developed on
imaging drum 1010, one at a time, with each monochrome image then being directly transferred in precise registration to the same print medium, prior to generation of the subsequent monochrome image. In this case, the number of transfers to one print medium corresponds to the number of colors used in forming the composite color image. The necessary level of transfer registration between the monochrome images composing the composite color image on the print medium is achieved using a high-registration transport unit, not shown. The transport unit, which may comprise a carrier belt or an imaging drum, repeatedly and precisely brings the print medium into touching contact with the dielectricouter surface 1011 ofimaging drum 1010 for each necessary image transfer. - A monochrome image (such as cyan, yellow, magenta, or black) is developed on dielectric
outer surface 1011 ofimaging drum 1010 in accordance with the steps described hereinabove. The toned image is then transferred from dielectricouter surface 1011 to an intermediate transfer medium 1018 (belt, drum, etc.). The transfer may be carried out using mechanical means, electrostatically or through a combination thereof. Following cleaning byunit 1022 of the dielectricouter surface 1011 ofimaging drum 1010, subsequent monochrome images are created and developed on dielectricouter surface 1011 ofimaging drum 1010 with each monochrome image sequentially transferred to anintermediate transfer medium 1018. After all the monochrome images comprising a full color image have been transferred to the intermediate transfer medium, a single transfer is carried out to the print medium. - Alternately, each single monochrome image may be individually transferred from the intermediate transfer medium 1018 to the print medium creating the full composite color image on the print medium. Transfer from the intermediate transfer medium 1018 to the print medium may be carried out using mechanical means, a combination of mechanical and thermal means, or electrostatically. Using a heat and pressure combination unifies the steps of transfer and fixing. The material composition of the intermediate transfer medium and its surface energy are selected in accordance with the type of transfer desired.
- A monochrome image (such as cyan, yellow, magenta, or black) is developed on dielectric
outer surface 1011 ofimaging drum 1010 in accordance with the steps described hereinabove. Subsequent latent images are superimposed on each previous developed image and then developed. After a composite color image is created on the dielectricouter surface 1011 ofimaging drum 1010, a single transfer either directly to the print medium or alternately, to the intermediate transfer medium is carried out using any of the techniques mentioned above, and dielectricouter surface 1011 is cleaned. In order to effect the superimposition of latent images onto developed images, the toner used must exhibit dielectric properties in order that the surface conductance of the developed image be sufficiently low to prevent charge leakage and to preserve high resolution. An example of this type of toner is described in U.S. Patent 3,337,340 to Matkan. - Fixing
unit 1020 is operative to fix the transferred image onto the print medium. The structure of fixingunit 1020 is determined by the specific toner used in developingunit 1016. When dry toner is used, the toner is fused and fixed to the print medium using heat and pressure rollers or alternately using flood radiation heating. When some types of liquid toner are used, the toner may be fixed to the print medium upon spontaneous or induced evaporation of the liquid carrier. Fixing other types of liquid toner may require fusing of the toner particles onto the print medium by heat, pressure or a combination thereof. - When using an intermediate transfer medium as described hereinabove, the fixing of the image onto the print medium may occur simultaneous with the transfer, i.e. transfixing, thereby eliminating the need for fixing
unit 1020. -
Cleaning unit 1022 is operative to remove residual toner remaining on the dielectricouter surface 1011 ofimaging drum 1010 after each transfer of toned images fromimaging drum 1010. The structure of fixingunit 1022 is determined by the specific toner used in the developingunit 1016. When dry toner is used, removal of residual toner is typically carried out using mechanical means, using a scraping blade, rollers, brushes and/or a combination which may also comprise a vacuum. - Additionally, the cleaning stage may include a pre- cleaning step whereby dielectric
outer surface 1011 ofimaging drum 1010 is electrostatically treated. When liquid toner is used, the cleaning stage may comprise mechanical or chemical means or a combination thereof. Chemical means may include a local rinse with the carrier component used in the liquid toner or intergradients. - The relative positioning and engagement of any of the subunits surrounding digital
electrostatic imaging drum 1011 may be selected in accordance with the desired print cycle, internal configuration and space considerations of a printer/copier. For example, in accordance with an alternate embodiment of the present invention, latentimage generation unit 1012 may be positioned intermediate developingunit 1016 andcleaning unit 1022. - Reference is now made to Fig. 24 which shows a structural illustration of a printing engine apparatus representing an example of a specific embodiment of the present invention. The printing engine apparatus shown in Fig. 24 is characterized by its ability to create a high quality composite color image on the imaging drum surface and to transfer the image in one step to a final print medium. The apparatus is also suitable for monochrome images.
- A conventional printing engine, taken from a Konica 90-28 Digital Color Copy Machine, from which the conventional drum, was removed was employed by the inventor. This printing engine is specifically configured for color prints in formats up to standard paper size A3. A digital
electrostatic imaging drum 1030 of the type described hereinabove and particularly shown in Fig. 15C and having an outer diameter of 7.2" (182 mm) was employed for latent image generation and developing in place of the conventional drum which was removed from the printing engine. - A dielectric
outer surface 1032 ofimaging drum 1030 comprises an imaging area and a non-imaging area where the non- imaging area subtends a 5.5" (140 mm) arc. The specific structure of the inner electronics ofimaging drum 1030 and of the imaging regions ofimaging drum 1030 may be generally as described hereinabove, particularly with reference to Fig. 16B. - The printing engine of Fig. 24 further comprises an edge-defined elongate alternating
polarity charge source 1034,developer units transfer unit 1044, and acleaning unit 1046. Furthermore, the printing engine may comprise afixing unit 1047. - During printing, a print medium (not shown) , typically paper, is fed to the printing engine using a
feed unit 1048. A toned image, which may comprise one or many monochrome images, that was developed onouter surface 1032, is transferred to the print medium in accordance with the techniques described hereinabove. After transfer, the print medium is output via atransport unit 1060 to fixingunit 1047, where the toned image is fixed to the final print medium. - Alternating
polarity charge source 1034, capable of achieving a spatial edge accuracy consistent with the desired resolution, is typically of the type described hereinabove or as described in one or more of applicant's co-pending patent applications mentioned above. - In the example shown in Fig. 24, each of
developer units - Development of a latent image on
outer surface 1032 ofimaging drum 1030 may be carried out using non-contact development techniques. Using non-contact development apparatus enables a composite color image to be created onouter surface 1032 without mixing of color toners which could adversely affect the quality of the final image. - During each development cycle, one of the four developer units is activated. AC voltage with a DC bias is applied to a developing
roller developer unit outer surface 1032 by causing toner particles to oscillate in the space betweenouter surface 1032 and the developing roller of the activated developer unit. This results in developing conditions relatively similar to those found in powder cloud development, a technique characterized by the provision of a high number of grey levels. - An electrostatic attracting field, caused by the net difference between the apparent surface voltage, as defined hereinabove, of each pixel location of the latent image and a biased developing
roller outer surface 1032 ofimaging drum 1030. The amount of toner electrostatically adhering toouter surface 1032 ofimaging drum 1030 at each pixel location is a function of the magnitude of the electrostatic attracting field and determines the optical density of the toner at that location -
Transfer unit 1044 comprises adielectric transfer belt 1052, a printmedium charging device 1051, atransfer corona unit 1056, and a print medium neutralizingAC corona unit 1058. After a final toned image comprising one or several superimposed monochrome images is developed and toned onouter surface 1032 ofimaging drum 1030, transfer from thesurface 1032 to a print medium takes place as follows:
A print medium (not shown) such as plain paper is fed to transferunit 1044 fromfeed unit 1048. A printmedium charging device 1051 then electrostatically adheres the print medium to the top side of atransfer belt 1052. Once adhered, the print medium is carried bytransfer belt 1052 to atransfer location 1055 where the print medium is brought into contact withsurface 1032 ofimaging drum 1030. The final toned image present onouter surface 1032 ofimaging drum 1030 is then electrostatically transferred directly onto the print medium. - During imaging drum revolutions during which no transfer from
outer surface 1032 ofimaging drum 1030 to a print medium takes place,transfer belt 1052 is moved out of contact withimaging drum 1030. - Transfer of the final toned image from
imaging drum 1030 to the print medium takes place by activating atransfer corona unit 1056 which bombards the backside oftransfer belt 1052 with charges of a polarity opposite to the polarity of the toner particles. This bombardment of thetransfer belt 1052 causes the toner to be attracted to the print medium. - The print medium, bearing the final toned image, is then transported to a print medium neutralizing
AC corona unit 1058 where the print medium is neutralized and detached from thetransfer belt 1052. After detachment, the print medium is fed to atransport unit 1060 and is then transported to fixingunit 1047 where the final toned image is fixed to the print medium. -
Cleaning unit 1046 preferably comprises anadjustable blade 1062, typically made of polyurethane, and atoner disposal roller 1064. After transfer of the final toned image to the print medium atlocation 1055, cleaningunit 1046 is brought into operative contact withouter surface 1032 ofimaging drum 1030 to remove residual toner fromouter surface 1032. The toner is then collected bytoner disposal roller 1064 and is removed to a toner reservoir (not shown) using an Archimedes'screw 1066. - The imaging cycle may comprise the following steps:
Digital data representing an image pattern to be generated is serially input to the inner electronics (not shown) ofimaging drum 1030 via rotary connectors (not shown). A latent image corresponding to the electronic signals input to the imaging drum is created on the imaging region ofouter surface 1032 ofimaging drum 1030 using edge-defined elongate alternatingpolarity charge source 1034. In the example illustrated in Fig. 24, an A3-size latent image corresponding to one toner color may be generated during one revolution ofimaging drum 1030. - A second revolution of
imaging drum 1030, during which one developer unit is activated, tones the latent image, thereby developing a monochrome image onouter surface 1032. For color prints, subsequent latent image generation and development cycles are carried out, with each new latent image being superimposed on the developed image. When all the monochrome images comprising the composite color image have been developed onouter surface 1032 ofimaging drum 1030, a single transfer of the composite color image to the print medium is carried out atlocation 1055. - After the composite color image has been transferred to the print medium, the print medium is transported via
transport unit 1060 to fixingunit 1047 where the composite color image is fixed to the print medium. - Alternately, the imaging cycle may comprise one transfer from
imaging drum 1030 for each individual monochrome image. In this case,transfer unit 1044 requires modifications and may include a carrier belt (not shown) or carrier drum (not shown) and other mechanisms which are capable of handling the print medium and ensuring precise registration between the monochrome images of the composite color image. An example of a carrier drum and its associated mechanisms may be found in Figure 6 of U.S. Patent 5,105,280, assigned to Minolta Camera Kabushiki Kaisha of Osaka, Japan. A further example of a carrier drum and its associated mechanisms may be found in Fig. 5A of U.S. Patent 5,111,302, assigned to Hewlett-Packard of Palo Alto, California. - Reference is now made to Fig. 25 which is a schematic illustration of digital color copier apparatus implemented using the print engine and imaging techniques and apparatus described hereinabove. The digital color copier apparatus preferably is composed of three main subunits: a
scanning subunit 1098, acontroller 1099 and aprinting subunit 1100. -
Scanning subunit 1098 scans the images to be copied and creates digital data corresponding to the RGB separations of the scanned image. Thesubunit 1098 may comprise standard color or monochrome scanning components including a generally flatscanning support surface 1101 on which an original image is placed prior to copying, alight source 1102,scanning optics 1104, includinglens system 1105, CCD arrays and associatedoptical color filters 1106, andelectronics 1108 which carry out analog to digital transfer of scanned data. -
Controller 1099 receives data from the scanning subunit and carries out image processing and memory functions and transfer of the scanned data from the RGB format used in scanning to the CMYK format necessary for printing. -
Printing subunit 1100 receives image data on a CMYK format and produces a hard copy of the image on a final print medium, typically cut-sheet paper. Theprinting subunit 1100 comprises aprint engine 1112 which may be of the type described hereinabove with reference to Fig. 23 and Fig. 24. Paper is fed intoprint engine 1112 from apaper storage tray 1114 by apaper feed 1116. - Image data may be input to the
controller 1099 from thescanning subunit 1098. Alternately, any other source that can provide electronic image data, for example a computer or a fax modem, can be used to provide input data to theprinting subunit 1100 via thecontroller 1099. - It is appreciated that when using the print techniques described hereinabove to create print copies of a scanned image, printing of an image may be carried out in a line-by-line fashion. Since scanning of an image to create electronic data for printing may also be carried out in a line-by-line fashion, scanning and printing may occur simultaneously thus allowing conservation of memory resources.
- Reference is now made to Fig. 26 which is a schematic illustration of print laminator apparatus implemented using a version of the D/E imaging drum and modified imaging techniques and apparatus. The print laminator apparatus preferably comprises a D/
E imaging drum 1120, which may be constructed in accordance with techniques and apparatus described hereinabove, typically having a dielectricouter surface 1121, a latentimage generation unit 1122, a drumsurface conditioning unit 1124, a dielectric filmmedium feed unit 1126, afilm attachment unit 1128, a developingunit 1130, and afilm detachment unit 1132. - The print laminator apparatus is characterized in that it creates composite color images directly on a thin, typically transparent, dielectric film, such as PET polyester, which has been attached to
outer dielectric surface 1121 ofprinting drum 1120. Alternatively, the film may replace theouter dielectric surface 1121, provided that suitable dielectric connection is maintained with the remainder of the drum. After developing the composite color image, the film may be detached from theouter dielectric surface 1121 ofimaging drum 1120 and laminated to a final substrate, thus creating a laminated print. Print laminator apparatus further comprises alaminating unit 1134 and may also comprise acutting unit 1136. - A thin dielectric film, preferably having a thickness of 8-12 microns, is fed into the print engine using dielectric film
medium feed unit 1126. Typically thin dielectric film may be either hazy or glossy. Preferably, the dielectric film is fed intofeed unit 1126 in cut sheets. Alternately, dielectric filmmedium feed unit 1126 may contain cutting apparatus so that the dielectric film output to the print engine apparatus is in cut sheet format. - As the dielectric film is being fed, drum
surface conditioning unit 1124 preconditionsouter dielectric surface 1121 ofimaging drum 1120. Preconditioning ofouter dielectric surface 1121 prepares theouter dielectric surface 1121 for attachment of the dielectric film thereto. Preconditioning and attachment may comprise any steps that enable good temporary adhesion between the dielectric film and theouter dielectric surface 1121 while maintaining dielectric uniformity across the dielectric film. - For example, when a liquid toner is used to develop the latent image, pre-conditioning may be carried out by rinsing and wetting the outer dielectric surface of the imaging drum with a dielectric liquid, such as the carrier component, typically Isopar, of the liquid toner. In this case,
film attachment unit 1128 comprises apparatus which presses the dielectric film against the wet outerdielectric surface 1121 with a squeezing motion to remove the air between theouter dielectric surface 1121 and the dielectric medium. The necessary level of attachment is achieved by a vacuum that is then created between the two surfaces. - Once attachment of the dielectric film has been carried out, the dielectric film serves as the imaging surface for latent image generating and color development. Following attachment of the dielectric film, a color composite image is generated on the film surface, generally in accordance with image generating techniques described hereinabove, with a color composite image built up on the film from latent images which are superimposed on each previous developed image and then developed.
- Since developing does not take place directly on the
outer dielectric surface 1121 ofimaging drum 1120, no toner cleaning unit is necessary. - Once the color composite image is fully developed,
film detachment unit 1132 is activated, thereby removing the dielectric film from theouter dielectric surface 1121 ofimaging drum 1120.Film detachment unit 1132 may detach the film by attracting and grabbing the leading edge of the dielectric film. Once the film has been detached, it is fed tolaminating unit 1134 by transport apparatus (not shown). - At
laminating unit 1134, the thin dielectric film may be laminated to asupport medium 1135 which may be paper, transparencies, etc. Typically, the dielectric film is laminated to the support material such that the side of the film containing the composite color image is placed in contact with thesupport medium 1135, protecting the image. Thesupport medium 1135 may contain adhesives, such as thermoplastics. Alternatively a typically thermoplastictransparent film 1137 may be sandwiched between the dielectric film and thesupport medium 1135 prior to the lamination. -
Laminating unit 1134 preferably uses a combination of pressure and heat to adhere the dielectric film to thesupport medium 1135, thus creating the final print.Optional cutting unit 1136 may be used to define the precise edges of the final print. When cuttingunit 1136 is used, high registration between the dielectric film and the support medium is not necessary. - It is appreciated that a print laminator apparatus as described herein could be used to generate high quality glossy or hazy (matte) continuous tone images on a variety of media including durable transparencies.
- Generating and developing the toned image on the dielectric film, which then becomes a part of the final print, eliminates the step of transferring of a toned image and the resulting degradation of the image quality. Thus, the final print may be of a higher quality than images generated through ordinary print techniques.
- Furthermore, during lamination the dielectric film encapsulates the toned image. Therefore, the image is protected from environmental sources and durability of the image is increased.
- Reference is now made to Fig. 27 which is a schematic illustration of printing apparatus implementing the imaging techniques and apparatus described hereinabove and in applicant's co-pending patent applications mentioned hereinabove, to provide very high speed one-sided or duplex printing. The printing engine apparatus and associated methods may form the base of a digital color press or alternately of other print devices where high speed, high quality, continuous tone printing is desired.
- For duplex printing, the printing engine apparatus typically comprises four individual color imaging units, such as cyan, magenta, yellow and black 1150, 1152, 1154 and 1156 for imaging one side of the print medium and an additional four color imaging units, such as cyan, magenta, yellow and black, 1158, 1160, 1162 and 1164 for imaging the second side of the print medium. It is appreciated that the exact number of color imaging units employed in the printing engine apparatus may be selected in accordance with the type of printing and the number of colors desired. For example, single sided printing may require only four color units. Alternately, five color units may be used whereby silver, gold, magnetic or other special-purpose inks or coatings may be added to the four process colors. All color units in the printing engine apparatus may be operated simultaneously to achieve high throughput speeds which are unaffected by the number of colors used or by duplex printing.
- Each color imaging unit preferably comprises a D/E imaging drum having a dielectric outer surface, a latent image generating unit, a developing unit, and a cleaning unit, all of which may be of the type described hereinabove with particular reference to Fig. 24.
- A duplex color printing image may be generated as follows:
Color separation data representing an image to be printed on one side of a print medium is input to each of the color units distributed along one side of the print medium. Simultaneously, color separation data representing a second image to be printed on the opposite side of the print medium may be input to each of the color units distributed along the second side of the print medium. After an image has been transferred to the print medium from one developing unit, the print medium is transported to the next imaging unit to receive a subsequent color separation image. This continues until a composite color image has been developed on both sides of the print medium. - The color units are activated in time synchronization, with the specific timing sequence of each latent image generation, development and transfer step being determined in accordance with the particular configuration of the imaging drum.
- Latent images preferably are generated on the D/E imaging drum of each color unit using the latent image generation techniques and apparatus described in applicant's co-pending patent applications mentioned above. The development unit then generates a visible monochrome image on the imaging drum. Each developed monochrome image is then transferred to the print medium in registration. After transfer, any residual toner remaining on the imaging drum of each color unit is removed by the color unit's respective cleaning unit.
- The print medium may be web roll-fed paper. Alternately, a carrier may be used to transport cut sheets between each of the color units.
- After a composite color image has been created on the print medium, the image may be fixed to the print medium at fixing
units - Reference is now made to Fig. 28 which is a schematic illustration of an alternative printing apparatus implementing the imaging techniques and apparatus described hereinabove and in applicant's co-pending patent applications mentioned hereinabove, to provide very high speed printing. The printing engine apparatus and associated methods may form the base of a digital color press or alternately of other print devices where high speed, high quality, continuous tone printing is desired.
- The printing engine apparatus typically comprises four individual imaging units, 1170, 1172, 1174 and 1176. Each imaging unit may correspond to one of the four process colors, that is cyan, magenta, yellow and black. Alternately, each imaging unit may be multi-color.
Imaging units -
Imaging units outer surface 1180, a latentimage generating unit 1182, and adevelopment unit 1184, all of which may be of the type described hereinabove with particular reference to Fig. 23 and Fig. 24.Development unit 1184 may further comprise a cleaning sub-unit (not shown).Development unit 1184 may comprise single or multi-color developing subunits. - Each D/E imaging drum 1178 typically comprises imaging regions and non-imaging regions as described hereinabove with particular reference to Fig. 15C. Latent
image generating unit 1182 is positionedintermediate development unit 1184 and transfer region 1190. The specific placement of latentimage generating unit 1182 anddevelopment unit 1184 is selected in accordance with the specific width of the non-imaging region of D/E imaging drum 1178. In order to achieve a print cycle of D/E imaging drum 1178 using only two rotations of D/E imaging drum 1178, it is desirable that the distance between transfer region 1190 anddevelopment unit 1184 span a length that is approximately twice the width of the non-imaging region. - In accordance with one embodiment of the invention, the diameter of D/E imaging drum 1178 is 7". This provides an imaging region with an axial length of 12" suitable for formats up to A3. For larger formats, a D/E imaging drum with a larger diameter or a longer axial length, or a combination thereof, can be used.
- Visible images are created on D/E imaging drum 1178 as follows:
During a first rotation of D/E imaging drum 1178, an electrostatic image is developed on dielectricouter surface 1180 using latent image generation techniques and apparatus described in applicant's co-pending patent applications mentioned above. During a second rotation of D/E imaging drum 1178,development unit 1184 develops a visible image on dielectricouter surface 1180 of D/E imaging drum 1178. Following developing, the visible image is transferred from dielectricouter surface 1180 of D/E imaging drum 1178 to an intermediate transfer belt 1186 by a combination of electrical and pressure means applied bytransfer element 1192, as is known in the art. - Intermediate transfer belt 1186 is preferably a flexible dielectric belt comprising multiple layers. Typical desirable properties of intermediate transfer belt 1186 include appropriate dielectric properties, resilience, and surface energy suitable for accepting toner from a drum and releasing toner during transfer to a final print medium. The flexible dielectric belt may be continuous, or alternatively may comprise a plurality of flexible dielectric sheets. When a plurality of flexible dielectric sheets is used, intermediate transfer belt 1186 further comprises a rotating chain and grippers for clamping each of said sheets to the rotating chain.
-
Rollers 1194 are operative to transport and rotate intermediate transfer belt 1186. After a visible image has been transferred from dielectricouter surface 1180 of D/E imaging drum 1178 to intermediate transfer belt 1186, any residual toner remaining on dielectricouter surface 1180 of D/E imaging drum 1178 may be removed by cleaning sub-unit (not shown). A composite color print is created as follows:
Color separation data representing an image to be printed on a print medium is input to imaging units, 1170, 1172, 1174 and 1176 distributed along intermediate transfer belt 1186. - Operating in time synchronization, each
imaging unit imaging units - After a composite color image has been fully built up on intermediate transfer belt 1186, the built-up image is carried by intermediate transfer belt 1186 to a fixing
drum 1200. Fixingdrum 1200 typically comprises an inner heating element (not shown) which is operative to heat the outer surface thereof. Alternately, an externalradiant heating element 1202 may be used. An example of an externalradiant heating element 1202 may be found in U.S. patent No. 3,893,761 to Buchan et. al. - Composite color images from intermediate transfer belt 1186 are impressed on an output print medium as follows:
A print medium which may be cut sheet paper or any other print media including plastics, stickers, vinyl, etc. is fed overimpression cylinder 1206. - As intermediate transfer belt 1186 rotates over fixing
drum 1200, the pigmented toner particles present in built-up images carried by intermediate transfer belt 1186 are heated, bringing said particles to a molten state. - As print medium is transported between intermediate transfer belt 1186 and
impression cylinder 1206, a combination of the heat from fixingdrum 1200 and pressure fromimpression cylinder 1206, causes the molten particles to be impressed and fused on output media creating a composite color image thereon. - After a composite color image has been impressed onto a print medium, intermediate transfer belt 1186 is cleaned with
cleaning unit 1204. - The exact number of imaging units employed in the printing apparatus may be selected in accordance with the type of printing, printing speed, and the number of colors desired. For example, high-speed highlight printing using one pass-development of two colors as described herein with particular reference to Fig. 6B - 6C, may be carried out by an alternate embodiment of the apparatus comprising two imaging units, each of which has two-color development units, preferably with the same two print colors.
- The specific orientation of the imaging units and intermediate transfer medium shown in Fig. 8 is presented to offer an example of possible configurations for the system and is not intended to be limiting.
- In accordance with some embodiments of the present invention, eight imaging units may be used, with each set of four imaging units being associated with an intermediate transfer medium. In accordance with this embodiment, duplexing (perfecting) is preferably carried out simultaneously with each intermediate transfer medium transferring an image to an opposite side of a page to be printed.
- It is appreciated that any suitable paper handling system may be used. Moreover, in accordance with an alternate embodiment of the present invention, a paper handling system utilizing a web as the media input may be used, in place of cut sheet apparatus. When using a web as the media input, cutting of pages to the desired size may occur before imaging or after imaging, as is known in the art.
- The paper handling system may include an inverting assembly to invert the print medium so that images may be impressed on a second side thereof, thus providing a duplex printing function.
- Reference is now made to Fig. 29 which shows a structural illustration of a printing apparatus representing a further example of a specific embodiment of the present invention. The printing apparatus shown in Fig. 29 is characterized by its ability to create high speed images for use as a digital offset press.
- Printing apparatus of Fig. 29 comprises
drum assemblies drum assembly drum assembly 1250 withreference numerals drum assembly 1251 withreference numerals E imagingng drums E imaging drums - The print cycles of D/
E imaging drums - Preferably, the two D/E imaging drums of a single drum assembly are operated in time synchronization. While one D/E imaging drum is in a writing cycle, the second D/E imaging drum is developing an image written thereon and transferring the developed image to an
intermediate transfer drum 1256. Transfer of the visible image from D/E imaging drum tointermediate transfer drum 1256 is effected using a combination of electrical and pressure means, as is known in the art. Fromintermediate transfer drum 1256, images are impressed on a print medium which is present on animpression cylinder 1258. Transfer may be carried out using a combination of heat and pressure, or by any other alternate suitable means.Cleaning unit 1257 may be used to remove any residual toner particles remaining onintermediate transfer drum 1256. -
Intermediate transfer drum 1256 typically comprises an outer flexible layer. Typical desirable properties include appropriate electrical resistivity, resilience, abrasion-resistance and surface energy suitable for accepting toner particles from a D/E imaging drum through a combination of pressure and electrical means.Intermediate transfer drum 1256 further comprises a heating element (not shown) which heats the outer surface ofintermediate transfer drum 1256 thereby transforming the toner particles into a molten state. Images are transferred fromintermediate transfer drum 1256 to a final print medium through impression of molten toner particles thereon. An example of a suitable intermediate transfer drum is as described in US Patent No. 5,335,054 to Landa et. al. - After a visible image has been transferred to
intermediate transfer drum 1256, any residual toner remaining on dielectric outer surface of D/E imaging drums may be removed by cleaning sub-units (not shown). - It is appreciated that a drum assembly as described herein provides enhanced print speed due to the fact that an image may be impressed onto a print medium during every rotation of
intermediate transfer drum 1256. - A composite color print is created as follows:
Color separation data representing an image to be printed on a print medium is input to each of thedrum assemblies - A print medium which may be cut sheet paper or any other print media including plastics, stickers, vinyl, etc. is transported from a
media storage area 1259 to afeed roller 1260.Feed roller 1260 then transfers the output medium toimpression cylinder 1258. - Operating in time synchronization, D/E imaging drums of each drum assembly successively and repeatedly create visible images in accordance with the techniques described hereinabove and transfer said images to an
intermediate transfer drum 1256. Fromintermediate transfer drum 1256, images are impressed on a print medium present onimpression cylinder 1258 as described hereinabove. - In accordance with a simplex mode of operation, one set of images, typically comprising one image which was created on each D/E drum, is sequentially impressed in register onto a print medium. Subsequently, an output medium, bearing the two color image, is transported by
transport roller 1262 to asecond transport roller 1263.Transport roller 1263 carries print medium to transportroller 1264 where it is transported to asecond impression cylinder 1266. - An additional set of images is then created by
drum assembly 1251 on a secondintermediate transfer drum 1267, which are then impressed on print medium viaimpression cylinder 1266 in accordance with the techniques described herein, thus creating a composite full color image thereon.Cleaning unit 1268 may be used to remove any residual toner particles remaining on secondintermediate transfer drum 1267. - In accordance with an alternate embodiment of the present invention, printing may be carried out in duplex mode. In this embodiment, the set of images impressed onto a print medium comprises two single color images from each D/E drum. Thus, a full four color image is created on a first side of output medium at
impression cylinder 1256. In this case, each D/E imaging drum will typically have a developing unit that is capable of multi-color development. After creation of a full four color image, output medium is transported bytransport roller 1262 to transportroller 1263.Transport roller 1263 is operative to invert the print medium. Following inversion,transport roller 1264 carries output medium tosecond impression cylinder 1266, where a full color impression may be created on a second side thereof. - Typically, after a composite color image has been impressed on one or both sides of a print medium, the output medium is transported from
impression cylinder 1266 to amedia output assembly 1270. Typically,media output assembly 1270 comprisespaper transport rollers chain delivery 1276 and amedia output tray 1278.Media output assembly 1270 may be of the type typically used in offset printers. - The exact number of drum assemblies employed in the printing apparatus may be selected in accordance with the type of printing, printing speed, and the number of colors desired.
- It is appreciated that paper handling components described herein including
media storage area 1259,feed rollers 1260,impression cylinders transport rollers media output assembly 1270, may be of the type commonly used in offset printing machines. - It will be appreciated by persons skilled in the art that the present invention is not limited to what has been particularly shown and described hereinabove. Rather the scope of the present invention is defined only by the claims which follow:
Claims (21)
- Imaging apparatus comprising:
a dielectric substrate with at least two generally opposite surfaces;
a plurality of elongate electrodes underlying a first surface of said dielectric substrate;
imaging circuitry for application of voltage signals to said plurality of electrodes;
a charge source operative to supply a flow of charges to a second surface of said dielectric substrate not beyond a generally linear boundary disposed along said second surface of said dielectric substrate and transversing said plurality of elongate electrodes. - Apparatus according to claim 1 and wherein said charge source includes an edge of an elongate shield which defines said generally linear boundary.
- Apparatus according to claim 2 and wherein said elongate shield comprises an electrostatic shield.
- Apparatus according to claim 2 and wherein said elongate shield comprises a physical barrier.
- Apparatus according to claim 2 and wherein said charge source comprises a corona ion source.
- Apparatus according to claim 1 and wherein said charge source comprises:
a liquid which exhibits electrical conductivity;
an applicator which is operative to apply said liquid to said second surface of said dielectric substrate;
a termination electrode; and
a physical barrier which defines said generally linear boundary. - Apparatus according to claim 7 and wherein said applicator is operative to rinse said second surface of said dielectric element with said liquid, thereby also providing a cleaning function.
- Apparatus according to claim 6 and wherein said physical barrier comprises a dielectric blade.
- Apparatus according to claim 8 and wherein said termination electrode comprises a conductive coating on one surface of said dielectric blade.
- Apparatus according to claim 1 and further comprising;
a developing unit operative to produce a developed image on said dielectric substrate. - A method of imaging comprising the steps of:
providing a dielectric substrate with at least two generally opposite surfaces;
providing a plurality of elongate electrodes underlying a first surface of said dielectric substrate;
applying voltage signals to said plurality of electrodes;
supplying a flow of charges to a second surface of said dielectric substrate not beyond a generally linear boundary disposed along said second surface of said dielectric substrate and transversing said plurality of elongate electrodes. - A method according to claim 11 and wherein said step of supplying a flow of charges comprises the step of:
applying a liquid to said second surface of said dielectric substrate;
providing a termination electrode; and
providing a physical barrier which defines said generally linear boundary. - A method according to claim 12 and wherein said step of applying a liquid is further operative to rinse said second surface of said dielectric element with said liquid, thereby providing a cleaning function.
- A method according to claim 13 and further comprising the step of producing a developed image on said dielectric substrate
- A method according to claim 11 and further comprising the step of displacing said generally linear boundary relative to said dielectric substrate.
- Digital printing apparatus comprising:
an intermediate transfer medium;
at least one imaging unit disposed about said intermediate transfer medium and comprising:
imaging drum having an outer dielectric surface;
a plurality of elongate electrodes underlying said outer dielectric surface;
imaging circuitry for application of voltage signals to said plurality of elongate electrodes;
a charge source operative to supply a flow of charges to said outer dielectric surface not beyond a generally linear boundary disposed along said outer dielectric surface of said imaging drum and transversing said plurality of elongate electrodes;
a developing unit operative to apply toner to said outer dielectric surface, producing visible images thereon; and
a transfer element operative to transfer said visible images to the intermediate transfer medium;
and
a secondary transfer unit operative to transfer said visible images from said intermediate transfer medium to a print medium. - Apparatus according to claim 16 and wherein each of said developing units of said plurality of image printing units utilizes a distinct toner color.
- Apparatus according to claim 16 and wherein said intermediate transfer medium comprises a drum.
- Apparatus according to claim 16 and wherein said intermediate transfer medium comprises a belt.
- Digital copy apparatus comprising.
an image scanning unit;
electronics operative to carry out image processing, memory and controller functions on an output of the image scanning unit;
an image printing unit comprising:
an imaging drum including a latent image receiving and retaining substrate;
a plurality of electrodes underlying said latent image receiving and retaining dielectric substrate;
imaging circuitry for application of voltage signals to said plurality of electrodes;
an elongate charge source operative to apply a flow of charges to said latent image receiving and retaining substrate, thereby creating a latent image thereon; and
a developing unit operative to apply toner to said latent image receiving and retaining substrate, thereby producing a toned image according to said latent image.
a transfer unit operative to transfer said toned image to a print medium. - Apparatus for pattern generation on a dielectric film comprising:
a relatively thin dielectric film;
an imaging drum including an outer dielectric substrate;
a plurality of electrodes mounted underlying said outer dielectric substrate;
imaging circuitry for application of voltage signals to said plurality of electrodes;
an elongate charge source operative to apply a flow of charges to said relatively thin dielectric film;
a drum preconditioning unit which is operative to prepare said imaging drum for attachment of said relatively thin dielectric film;
an attaching unit which is operative to place said relatively thin dielectric film in dielectric contact with said outer dielectric substrate of imaging drum;
a detaching unit which is operative to separate said relatively thin dielectric film from said outer dielectric substrate of said imaging drum;
a developing unit which is operative to apply toner to said relatively thin dielectric film; and
a laminating unit which is operative to laminate said relatively thin dielectric film to a support medium.
Applications Claiming Priority (8)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
IL11128194 | 1994-10-13 | ||
IL11128194A IL111281A0 (en) | 1994-10-13 | 1994-10-13 | Apparatus and method for non-impact imaging and marking |
IL11362295A IL113622A0 (en) | 1995-05-05 | 1995-05-05 | Apparatus and methods for pattern generation on a dielectric subtrate |
IL11362295 | 1995-05-05 | ||
IL11380195 | 1995-05-21 | ||
IL11380195A IL113801A0 (en) | 1995-05-21 | 1995-05-21 | Apparatus and methods for image generation on a dielectric substrate |
US487416 | 1995-06-07 | ||
US08/487,416 US5777576A (en) | 1991-05-08 | 1995-06-07 | Apparatus and methods for non impact imaging and digital printing |
Publications (2)
Publication Number | Publication Date |
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EP0706891A2 true EP0706891A2 (en) | 1996-04-17 |
EP0706891A3 EP0706891A3 (en) | 1998-05-06 |
Family
ID=27452446
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP95305603A Withdrawn EP0706891A3 (en) | 1994-10-13 | 1995-08-11 | Apparatus and methods for non impact imaging and digital printing |
Country Status (2)
Country | Link |
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EP (1) | EP0706891A3 (en) |
JP (1) | JPH08179598A (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0876918A3 (en) * | 1997-05-08 | 1999-08-04 | Heidelberger Druckmaschinen Aktiengesellschaft | Electrostatic writing head for an electronic printing machine |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0876918A3 (en) * | 1997-05-08 | 1999-08-04 | Heidelberger Druckmaschinen Aktiengesellschaft | Electrostatic writing head for an electronic printing machine |
Also Published As
Publication number | Publication date |
---|---|
EP0706891A3 (en) | 1998-05-06 |
JPH08179598A (en) | 1996-07-12 |
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