Claims
- 1. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, and an insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member; then
- applying a secondary voltage to said insulating member of the screen; and applying an image light to said photoconductive member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 2. An electrophotographic process according to claim 1, wherein said image light application and said secondary voltage application are carried out substantially simultaneously.
- 3. An electrophotographic process according to claim 1, wherein said secondary voltage application is carried out after said image light application.
- 4. An electrophotographic process according to claim 1, wherein said primary voltage application is carried out using a DC voltage, and said secondary voltage application is carried out using a DC voltage.
- 5. An electrophotographic process according to claim 1, wherein said primary voltage application is carried out using a DC voltage, and said secondary voltage application is carried out using an AC voltage or an AC voltage to which a DC voltage is superposed.
- 6. An electrophotographic process according to claim 1, prior to said ion flow step, to increase the electrostatic contrast of the image formed thereon, wherein said primary voltage, said secondary voltage, said image light and said light are applied to the screen from the side thereof adjacent said exposed insulating member.
- 7. An electrophotographic process according to claim 1, wherein said ion flow application step is repeated to modulate the ion flow to make multiple copies in accordance with a single electrostatic latent image formed on the screen.
- 8. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, and an insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member and applying an image light to said photoconductive member of the screen; then
- applying a secondary voltage to said insulating member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 9. An electrophotographic process according to claim 8, wherein said primary voltage application is carried out using a DC voltage, and said secondary voltage application is carried out using a DC voltage.
- 10. An electrophotographic process according to claim 8, wherein said primary voltage application is carried out using a DC voltage, and said secondary voltage application is carried out using an AC voltage or an AC voltage to which a DC voltage is superposed.
- 11. An electrophotographic process according to claim 8, wherein said ion flow application step is repeated to modulate the ion flow to make multiple copies in accordance with a single electrostatic latent image formed on the screen.
- 12. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, and an insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member, and simultaneously applying an image light to said photoconductive member of the screen to form an electrostatic latent image thereon; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 13. An electrophotographic process according to claim 12, wherein the ion flow application step is repeated to modulate the ion flow to make multiple copies in accordance with a single electrostatic latent image formed on the screen.
- 14. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, and an insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member; then
- applying a secondary voltage to said insulating member of the screen; then
- applying a tertiary voltage to said insulating member of the screen, and applying an image light to said photoconductive member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 15. An electrophotographic process according to claim 14, wherein said image light application and said tertiary voltage application steps are carried out substantially simultaneously.
- 16. An electrophotographic process according to claim 14, wherein said tertiary voltage application step is carried out after said image light application step.
- 17. An electrophotographic process according to claim 14, wherein said primary voltage application is carried out using a DC voltage, and said secondary and tertiary voltage applications are carried out using DC voltages.
- 18. An electrophotographic process according to claim 14, wherein said primary voltage application is carried out using a DC voltage, said secondary voltage application is carried out using a DC voltage, and said tertiary voltage application is carried out using an AC voltage or an AC voltage to which a DC voltage is superposed.
- 19. An electrophotographic process according to claim 14, wherein said primary voltage application is carried out using a DC voltage, and said secondary and tertiary voltage applications are carried out using an AC voltage or an AC voltage to which a DC voltage is superposed.
- 20. An electrophotographic process according to claim 14, wherein said primary voltage application is carried out using a DC voltage, said secondary voltage application is carried out using an AC voltage or an AC voltage to which a DC voltage is superposed, and said tertiary voltage application is carried out using a DC voltage.
- 21. An electrophotographic process according to claim 14, wherein the ion flow application step is repeated to modulate the ion flow to make multiple copies in accordance with a single electrostatic latent image formed on the screen.
- 22. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, a top insulating member overlying the photoconductive member and extending from one side of said screen to the other side of said screen through the openings of said screen, and an additional conductive member attached onto said insulating member at one side of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to said insulating member; then
- applying a secondary voltage to said insulating member of the screen, and applying an image light to said photoconductive member of the screen; then
- uniformly exposing the screen to light to form a primary electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposite sides of said insulating member; and then
- applying a flow of ions to the screen from the side thereof at which said additional conductive member is attached to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said additional conductive member over one entire surface of the screen.
- 23. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, a top insulating member overlying the photoconductive member and extending from one side of said screen to the other side of said screen through the openings of said screen, and an additional conductive member attached onto said insulating member at one side of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to said insulating member and applying an image light to said photoconductive member of the screen; then
- applying a secondary voltage to said insulating member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member; and
- applying a flow of ions to the screen from the side thereof at which said conductive member is attached to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said additional conductive member over one entire surface of the screen.
- 24. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, a top insulating member overlying the photoconductive member and extending from one side of said screen to the other side of said screen through the openings of said screen, and an additional conductive member attached onto said insulating member at one side of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to said insulating member, and applying an image light to said photoconductive member of the screen to form an electrostatic latent image thereon; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is attached to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said additional conductive member over one entire surface of the screen.
- 25. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member substantially covering the conductive base member, a top insulating member overlying the photoconductive member and extending from one side of said screen to the other side of said screen through the openings of said screen, and an additional conductive member attached onto said insulating member at one side of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to said insulating member; then
- applying a secondary voltage to said insulating member of the screen; then
- applying a tertiary voltage to said insulating member of the screen, and applying an image light to said photoconductive member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is attached to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said additional conductive member over one entire surface of the screen.
- 26. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a first insulating member covering the base member, a photoconductive member substantially covering the first insulating member, and a second insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the second insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen; said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member, and substantially simultaneously therewith, uniformly exposing the screen to light; then
- applying a secondary voltage to the screen, and an image light to said photoconductive member of the screen;
- uniformly exposing the screen to light to form an electrostatic latent image thereon, said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposite sides of said second insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 27. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a first insulating member covering the base member, a photoconductive member substantially covering the first insulating member, and a second insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the second insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member, and applying an image light to said photoconductive member of the screen; then
- applying a secondary voltage to said insulating member of the screen; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 28. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a first insulating member covering the base member, a photoconductive member substantially covering the first insulating member, and a second insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the second insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member, and applying an image light to said photoconductive member of the screen to form an electrostatic latent image thereon; then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to modulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 29. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a first insulating member covering the base member, a photoconductive member substantially covering the first insulating member, and a second insulating member overlying the photoconductive member, wherein the conductive member is exposed at one side of the screen and wherein the insulating member has first portions forming a top surface of the opposite side of said screen and second portions continuously extending from said first portions and forming top inner surfaces of the openings of said screen, said process comprising the steps of:
- applying a primary voltage to the screen to apply uniform charges to both of said first and second portions of said insulating member, and substantially simultaneously therewith, uniformly exposing the screen to light;
- applying a secondary voltage to said insulating member of the screen; then
- applying a tertiary voltage to said insulating member of the screen, and applying an image light to said photoconductive member of the screen; then
- uniforming exposing the screen to light to form an electrostatic latent image thereon, wherein said electrostatic latent image is formed with electric charges of opposite polarities disposed on opposed sides of said insulating member at both the first and second portions thereof; and then
- applying a flow of ions to the screen from the side thereof at which said conductive member is exposed to mudulate the ion flow in accordance with said electrostatic latent image, wherein surplus ions are simultaneously absorbed by said exposed conductive member over one entire surface of the screen.
- 30. An electrophotographic process for use with a screen having a number of openings therein, comprising the steps of applying a voltage to the screen, irradiating the screen with image light to form a primary electrostatic latent image thereon defining an electric field for accelerating ion flow of a first polarity and blocking ion flow of a second polarity in accordance with a pattern of the image light, applying a corona ion flow having positive and negative components, from a corona source, through the screen bearing the primary electrostatic latent image to a chargeable member, and applying a first electric field extending from the corona source to the chargeable member, and a second electric field extending from the chargeable member to the corona source in accordance with the polarity of a voltage applied to the corona source, thereby passing the ion flow to form a secondary electrostatic latent image, on the chargeable member, having corresponding dark and light areas which are of opposite polarity to each other.
- 31. An electrophotographic process according to claim 30, wherein said corona ion flow having positive and negative components in an AC corona ion flow.
- 32. An electrophotographic process according to claim 30, wherein said electric fields at the illuminated area and non-illuminated area are formed by electric charges of opposite polarity and are directed oppositely.
- 33. An electrophotographic process according to claim 30, wherein said accelerating and blocking fields formed by said image are formed by a bias voltage applied to said screen and electric charges forming the electrostatic latent image.
- 34. An electrophotographic process according to claim 30, wherein said corona ion flow having positive and negative components is applied by alternately applying a negative DC corona ion flow and a positive DC corona ion flow.
- 35. An electrophotograhic process for use with a screen having a number of openings therein, comprising the steps of applying a voltage to the screen, irradiating the screen with image light to form a primary electrostatic latent image thereon defining an electric field for accelerating ion flow of a first polarity and blocking ion flow of a second polarity in accordance with a pattern of the image light, and applying an AC corona ion flow from a corona source through the screen bearing the primary electrostatic latent image to a chargeable member, thereby selectively passing the ion flow of either of the first or second polarity due to an electric field formed between the corona source and the chargeable member so as to form a positive or negative secondary electrostatic latent image on the chargeable member.
- 36. An electrophotographic process according to claim 35, wherein said electric fields at the illuminated area and non-illuminated area are formed by electric charges of opposite polarity and are directed oppositely.
- 37. An electrophotographic process according to claim 35, wherein said accelerating and blocking fields are formed by a bias voltage applied to said screen and electric charges forming the electrostatic latent image.
- 38. The method of producing a developable image from a single graphic original having dark and light portions thereon by depositing a charge pattern on a receiving element for collecting charged particles thereon through the use of modulator means, said modulator means being adapted to selectively transmit charged particles therethrough comprising the steps of:
- 1. creating a charge distribution system on said modulator wherein said modulator comprises a transparent insulating layer overlying a photoconductive medium deposited on a conductive foraminated structure and which charge distribution resides on the surface of the insulating top layer to produce a first electrical field across the insulating layer of said modulator, said first electrical field being a dipole charge across the insulating layer occurring in certain zones of said modulator corresponding to portions of said graphic original;
- 2. establishing a second electrical field in the vicinity of the conductive screen for projecting charged particles in the direction of said modulator;
- 3. establishing a third electrical field in the vicinity of said insulating layer for controlling the charged particles that are transmitted through said modulator toward said receiving element.
- 39. The method of making a developable image from a graphic original by creating a charge pattern on a dielectric medium through the use of a modulator adapted to selectively transmit charged particles in the presence of an electric field comprising the steps of:
- 1. creating a charge distribution system on said modulator wherein said modulator comprises a transparent insulating layer overlying a photoconductive medium deposited on a conductive screen by carrying out the steps of:
- a. applying a blanket electrostatic charge to the insulating layer;
- b. projecting a pattern of light and shadow to the insulating layer;
- c. applying an AC corona charge to the insulating layer;
- d. illuminating the insulating layer overall with electromagnetic radiation,
- and which charge distribution system persists on the modulator in the presence of radiation in the visible portion of the spectrum;
- 2. directing charged particles of one polarity against the conductive screen while said screen is connected to a reference potential;
- 3. positioning an electrode on the side of the modulator opposite the side against which the charged particles are directed, said electrode being connected to a high voltage source which is opposite in polarity to said charged particles;
- 4. removably affixing said dielectric medium to said electrode whereby said charged particles are selectively transmitted through certain portions of said modulator to produce a developable image on said dielectric medium.
- 40. The method as claimed in claim 38 wherein said charge distribution system is of a polarity that is opposite to the polarity of said second field.
- 41. The method as claimed in claim 38 wherein said charge distribution system is of a polarity that is the same as the polarity of said second field.
- 42. The method as claimed in claim 38 wherein said third field is created by positioning a plate electrode a distance in the range from 0.5 to 1 centimeters from the insulating surface layer.
- 43. The method as claimed in claim 38 wherein said first field on said modulator corresponds to the dark portions of said original.
- 44. The method as claimed in claim 38 wherein said first field on said modulator corresponds to the light portions of said original.
- 45. The method as claimed in claim 43 wherein the second field is of a greater intensity than said third field.
- 46. The method of making a developable image from a graphic original by creating a charge pattern on a dielectric medium through the use of a modulator adapted to selectively transmit charged particles in the presence of an electric field comprising the steps of:
- 1. creating a charge distribution system on said modulator wherein said modulator comprises a transparent insulating layer overlying a photoconductive medium deposited on a conductive screen by carrying out the steps of:
- a. applying a blanket electrostatic charge onto the insulating layer;
- b. projecting a pattern of light and shadow on the surface of the insulating layer of the modulator simultaneous with the application of AC corona charge; and
- c. illuminating the insulating layer overall with electromagnetic radiation, and which charge distribution system persists on the modulator in the presence of radiation in the visible portion of the spectrum;
- 2. directing charged particles of one polarity against the conductive screen while said screen is connected to a reference potential;
- 3. positioning an electrode on the side of the modulator opposite the side against which the charged particles are directed, said electrode being connected to a high voltage source which is opposite in polarity to said charged particles;
- 4. removably affixing said dielectric medium to said electrode whereby said charged particles are selectively transmitted through certain portions of said modulator to produce a developable image on said dielectric medium.
- 47. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member overlying the conductive base member, and an insulating member overlying the photoconductive member, said process comprising the steps of:
- applying a primary DC voltage to the screen to apply uniform charge onto said insulating member; then
- applying, to the screen, a secondary voltage effective to reverse the polarity of the surface potential of the insulating member of the screen, and applying image light to said photoconductive member of the screen; and then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, whereby an electric field for accelerating an ion flow of a certain polarity is provided at the portions not exposed to the image light of the image and an electric field for blocking an ion flow of said certain polarity is provided at the portions which are exposed to the image light; and
- applying a flow of ions to said base member of said screen to moderate the ion flow in accordance with said electrostatic image.
- 48. An electrophotographic process according to claim 47 wherein said secondary voltage is a voltage having both positive and negative components.
- 49. An electrophotographic process according to claim 48, wherein said voltage having both positive and negative components is an AC voltage to which a DC voltage is superimposed.
- 50. An electrophotographic process according to claim 47, wherein said secondary voltage is a DC voltage.
- 51. An electrophotographic process according to claim 47, wherein said image light application and secondary voltage application are carried out substantially simultaneously.
- 52. An electrophotographic process according to claim 47, wherein said secondary voltage application is carried out after said image light application.
- 53. An electrophotographic process for use with a screen having a number of openings, said screen comprising a base member of conductive material having a number of openings therein, a photoconductive member overlying the conductive base member, and an insulating member overlying photoconductive member, said process comprising the steps of:
- applying a primary DC voltage to the screen to apply uniform charge onto said insulating member; then
- applying a secondary voltage to the screen which is effective to reverse the polarity of the surface potential of the insulating member of the screen, and applying image light to said photoconductive member of the screen; and then
- uniformly exposing the screen to light to form an electrostatic latent image thereon, whereby the surface potential at the portions not exposed to the image light is of the same polarity as that of said primary DC voltage while the surface potential at the portions exposed to the image light is of a polarity opposite to that of said primary DC voltage; and
- applying a flow of ions to said screen, to moderate the ion flow in accordance with said electrostatic image.
- 54. An electrophotographic process according to claim 53, wherein said secondary voltage is a voltage having both positive and negative components.
- 55. An electrophotographic process according to claim 54, wherein said voltage having both positive and negative components in an AC voltage to which a DC voltage is superimposed.
- 56. An electrophotographic process according to claim 53, wherein said secondary voltage is a DC voltage.
- 57. An electrophotographic process according to claim 53, wherein said image light application and secondary voltage application are carried out substantially simultaneously.
- 58. An electrophotographic process according to claim 53, wherein said secondary voltage application is carried out after said image light application.
- 59. A process for forming a latent image on a recording member by means of a photosensitive screen having a number of openings therein, said screen comprising a conductive base, a photoconductive layer exhibiting p-type or n-type semiconductivity substantially covering said base, and an insulating layer overlying said photoconductive layer, said conductive base being exposed on one side of said screen and carrier charge of a polarity corresponding to the conductivity type of photoconductive layer being injectable from said base into said photoconductive layer to be bound in the region of the interface between said insulating and photoconductive layers, said process comprising the steps of:
- applying an initial charge of a polarity opposite to the conductivity type of said photoconductive layer substantially uniformly onto said insulating layer thereby injecting said binding carrier charge in the region of the interface between said insulating and photoconductive layers;
- then simultaneously applying an alternating current corona discharge onto said insulating layer and exposing said photoconductive layer to a pattern of image light; then
- uniformly exposing said photoconductive layer to activating light to form a latent image thereon, said latent image being formed with electrical charges of opposite polarity disposed on opposite sides of said insulating member; and then
- applying a flow of corona ions to said screen from said one side toward said recording member positioned on the other side of said screen to modulate the ion flow in accordance with the latent image on said screen to form a latent image on said recording member in accordance with the ion modulation.
- 60. A process according to claim 59, wherein a direct current bias voltage of a polarity opposite to that of the initial charge is superimposed on said alternating current corona discharge whereby in areas exposed to the light portions of the image pattern said initial charge is neutralized and replaced with a charge of a polarity opposite to that of the initial charge and in areas exposed to the dark portions of the image pattern said initial charge is not completely neutralized and upon uniform exposure to activating light a high contrast latent image having areas of opposite polarity corresponding to the light and dark regions of the light pattern is formed.
- 61. A process according to claim 60, wherein the flow of corona ions to said screen is produced with a direct current voltage.
- 62. A process according to claim 60, wherein the flow of corona ions to said screen is produced with an alternating current voltage.
- 63. A process for forming a latent image on a recording member with a photosensitive screen having a number of openings therein, said screen comprising a conductive base, a photoconductive layer exhibiting p-type or n-type semiconductivity substantially covering said conductive base, a top insulating layer overlying said photoconductive layer and extending from one side of said screen to the other side through the openings therein, and an additional conductive member attached to the surface of said insulating layer at said one side of said screen, carrier charge of a polarity corresponding to the conductivity type of photoconductive layer being injectable from said base into said photoconductive layer to be bound in the region of the interface between insulating and photoconductive layers, said process comprising the steps of:
- applying an initial charge of a polarity opposite to the conductivity type of said photoconductive layer substantially uniformly onto said insulating layer thereby injecting and binding carrier charge in the region of the interface between said insulating and photoconductive layers;
- then simultaneously applying an alternating current corona discharge onto said insulating layer and exposing said photoconductive layer to a pattern of image light; then
- uniformly exposing said photoconductive layer to activating light to form a latent image thereon, said latent image being formed with electrical charges of opposite polarity disposed on opposite sides of said insulating member; and then
- applying a flow of corona ions to said screen from said one side toward said recording member positioned on the other side of said screen to modulate the ion flow in accordance with the latent image on said screen to form a latent image on said recording member in accordance with the ion modulation.
- 64. A process according to claim 63, wherein a direct current bias voltage of a polarity opposite to that of the initial charge is superimposed on said alternating current corona discharge such that in areas exposed to the light portions of the image pattern said initial charge is neutralized and replaced with a charge of a polarity opposite to that of the initial charge and that in areas exposed to the dark portions of the image pattern said initial charge is not completely neutralized and upon uniform exposure to activating light a high contrast latent image having areas of opposite polarity corresponding to the light and dark regions of the light pattern is formed.
- 65. A process according to claim 63, wherein the flow of corona ions to said screen is produced with a direct current voltage.
- 66. A process according to claim 63, wherein the flow of corona ions to said screen is produced with an alternating current voltage.
Priority Claims (6)
Number |
Date |
Country |
Kind |
48-69343 |
Jun 1973 |
JPX |
|
48-87068 |
Aug 1973 |
JPX |
|
48-87069 |
Aug 1973 |
JPX |
|
48-87070 |
Aug 1973 |
JPX |
|
48-123670 |
Nov 1973 |
JPX |
|
49-12412 |
Jan 1974 |
JPX |
|
Parent Case Info
This is a continuation, of application Ser. No. 480,280, filed June 17, 1974 now abandoned.
US Referenced Citations (13)
Foreign Referenced Citations (1)
Number |
Date |
Country |
13063 |
Apr 1973 |
JPX |
Continuations (1)
|
Number |
Date |
Country |
Parent |
480280 |
Jun 1974 |
|