DE1276381B - Cathode ray tubes for electrostatic printing units - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

G 06k

German KL: 42 m6 - 15/14

Number: 1276 381

File number: P 12 76 381.4-53 (St 23005)

Filing date: November 28, 1964

Opening day: August 29, 1968

The invention relates to a cathode ray tube for electrostatic printing units data technology, in which the radiation energy of the electron beam converted into light energy acts on photoconductive layers according to their intensity via light-conducting elements, which in turn are in contact with an electrically conductive transparent film, which is connected to a counter electrode via a voltage source of high potential, the one to be printed being Recording medium is located between this arrangement and the counter electrode.

The use of cathode ray tubes for electrostatic writing is known.

A high-speed printer specially set up for the evaluation of code combinations, as shown in "Electrical Computing Systems", 1959, issue. 1, pp. 41 and 42, sees a cathode ray tube before, in which a disk acting as a type mask is arranged in the beam path. By appropriate, code-controlled deflection of the electron beam is the type to be recorded scanned in such a way that the electron beam penetrating the disk has the shape of the type and causes a corresponding marking of the recording medium.

This tube has the disadvantage that it can only be used for the stated purpose and is an expensive one Represents special design.

Another embodiment known from U.S. Patent 2,928,973 sees a tube before, the piston crown penetrated by a large number of juxtaposed wire pins is. Via these pins, the charge of the incident electron beam is in direct action on transmit the recording medium located outside the tube.

However, tubes of this type have the disadvantage that the gain due to the secondary emission the wire pins is less than one. With the conventional tube types it is this Kind only about 0.4.

Another embodiment has become known from US Pat. No. 3 007 049, in which the piston head of the tube consists of a large number of light-conducting elements, each with a photoconductive layer of high dark resistance are surrounded. Through a transparent, electric conductive support on the inside of the piston, which in turn is coated with a phosphor layer the photoconductive layers are connected to a counter electrode via a voltage source of high potential

Cathode ray tube for on electrostatic
Path-working printing units

Applicant:

International Standard Electric Corporation,

New York, N.Y. (V. St. A.)

Representative:

Dipl.-Ing. H. Ciaessen, patent attorney,

7000 Stuttgart W, Rotebühlstr. 70

Named as inventor:
Lolure Gene Wolfgang,
Fort Wayne, Ind. (V. St. A.)

Claimed priority:
V. St. v. America November 29, 1963
(326 699)

the. With the action of the electron beam on the phosphor layer, light reaches the corresponding photoconductive layers via the light-conducting elements located under the light spot, the electrical resistance of which thereby drops to a fraction of the dark resistance. As a result of the change in the voltage distribution resulting therefrom, a static charge occurs at this point on the recording medium located between the tube bottom and the counter electrode.
Although this tube has the advantage of good efficiency, it has the disadvantage that it poses production and functional problems and is very expensive to manufacture. The measures of surrounding the individual light-conducting elements with a photoconductive layer and then fusing them to form a vacuum-tight unit represent a special design. The need to apply the transparent, electrically conductive film on the inside of the tube piston is another disadvantage .

All these disadvantages are avoided in the cathode ray tube according to the invention by the light-conducting elements through an insulation

809 598/260

layer-acting fiber optics are formed, which as a piston crown hermetically with the tubular piston neck is welded, and that the conversion on the inside of the fiber optics in a conventional manner the radiation energy is applied in light energy causing layer and that on the Outside with the interposition of the transparent, electrically conductive foot an extensive one Photoconductive layer is arranged.

This design permits the use of fiber optics such as those used in the relevant industry is offered as standard. In addition, the external coating of the fiber optics In terms of manufacturing technology, it is much cheaper and leads to a reduction in manufacturing costs without this Advantages have to be bought at the cost of a deterioration in efficiency.

On the basis of an exemplary embodiment, the invention is intended to be more detailed in conjunction with the drawings explained.

Fig. 1 shows the rear end view of the writing tube according to the invention;

F i g. 2 shows the in FIG. 1 mentioned tube in sectional view, according to the section plane 2-2 in

F i g. FIG. 3 is a partial cross-sectional view of a writing system associated with FIG Tube is equipped according to Figures 1 and 2;

F i g. 4 shows the basic structure according to which the device according to the invention works;

FIG. 5 shows a representation of FIG. 4 equivalent Circuit.

As can be seen from FIGS. 1 to 3, the writing tube designated by 10 consists of a funnel-shaped piston part 11 which merges at its narrower end into a neck piece 12 and which is closed at its other end by a piston head 13 consisting of several layers is. The space enclosed by the arrangement can be ventilated.

In the case of the cathode ray tube shown, the scanning movement is later in one direction as described in more detail executed by the own movement of the writing carrier, so that the electron beam to be deflected only in the direction perpendicular to the direction of movement of the writing medium needs. For this reason, the piston 11 has an elongated rectangular shape at its wide end Cross-section on how F i g. 1 can be seen in order to reduce the space required above all.

In the flask neck is the one consisting of the Wehnelt cylinder 15, the cathode 16 and the control grid 23 Arranged electron source, the electron beam 17 in a known manner on the control grid 23 pending time base signals is modulated. To focus the electron beam is on the neck of the flask 12, a focusing winding 18 is arranged, to which a deflection winding 19 is assigned which deflects the electron beam in the direction indicated by arrow 20 in FIGS will. The inner surface of the piston neck 12 and the piston 11 is in a known manner with a suitable conductive pad 22 coated, such as. B. graphite or aluminum.

The multilayer piston head 13 contains a fiber optic layer 24, which in the embodiment for a Lettering width of 216 mm has a rectangular shape of about 230 mm by 12.7 mm and with the protruding part 25 of the piston (Fig. 3) is hermetically fused.

The side of the fiber optic layer 24 that is the electron source is facing, is provided with a phosphor layer 26, high resolution, which is matched in its spectral characteristics to that of the photoconductive layer 27 to be described in more detail is. A P-2 or P-20-o · phosphor in combination with one made of cadmium sulfide is suitable here existing photoconductive layer, while red phosphorus, such as ζ B. P-22R, when using a Photoconductive layer made of cadmium selenite is suitable.

To increase the brightness of the electron beam 17 impinging on the phosphor layer 26 caused optical image and also to increase the mechanical resistance of this Layer against the stress caused by ion bombardment, the phosphor layer is in itself beao As is known, covered by an aluminum foil 28, which either extends to the inner surface of the piston at the same time represents the above-described support 22 or at least for making contact covered a piece. This now becomes dependent on the electron beam 17 in the phosphor layer 26 optical image caused by the fiber optic layer 24, to its outer surface transmitted with minimal loss of resolution. This outer side of the fiber optic layer 24 is with coated with a transparent electrically conductive film 29, e.g. B. with tin oxide or Nesa, the electrical can be connected. The photoconductive layer 27 is also arranged on this film.

The optical image, which is transmitted by the phosphor layer 26 over the fiber optic layer 24, thus passes is transferred through the transparent conductive film 29 to the photoconductive layer 27, which has a high Dark and has a low lightness resistance, so that their incremental resistance is dependent on of the incremental brightness of the phosphor layer 26 changes.

Directly from the outer side of the photoconductive layer 27, a roller 30 is arranged, which is made of conductive Material. The roller 30 is used to guide a paper or other suitable one dielectric material existing web-shaped recording medium 32, which is of a not shown Roll is withdrawn and is in the process shown in FIG. 3 on the photoconductive layer 27 moved past.

As in Fig. 4, the transparent conductive support 29 and the roller 30 are electrically connected to one another via a direct voltage source 33 of, for example, 400 volts. 5 shows, in the form of a circuit diagram, the resulting electrical relationships that develop between the conductive support 29 and the roller 30. The parallel connection of the capacitance 27 c and the resistor 27 r represents the photoconductive layer 27, while the parallel connection of the capacitance 32 c and the resistor 32 r in series with it corresponds to the recording medium 32. Here, the resistance 27 r of the photoconductive layer 27 is variable between a very high value in the dark state and a significantly lower value depending on the incident light, the resistance 32 r of the recording medium 32 being comparatively very large. If there is an extremely high level of darkness

resistance 27 r of the photoconductive layer 27 and with a movement of the web 32 indicated by the arrow 34, the charge of the capacitance 32 c of the recording medium 32 will not change perceptibly if there is no incidence of light on the photoconductive layer 27. With the impingement of light on the photoconductive layer 27, however, its resistance 27 r drops to a low value, whereby almost the entire voltage of the current source 33 hests on the resistor 32 r , so that the charge of the capacitance 32 c increases accordingly. As the recording medium 32 moves in the direction of the arrow 34, it is marked on it in the form of a charge image as a function of the optical image generated by the phosphor layer 26 and transferred to the photoconductive layer 27. As a result of the continuous advancement of the recording medium 32, new, uncharged parts of the recording web continuously arrive at the point between the photoconductive layer 27 and the roller 30, the capacity of the recording medium leaving this point having a certain state of charge. Of course, a reverse mode of operation is also possible, in which the recording medium 32 is first charged to a predetermined potential and then the corresponding recording medium portions are discharged via the photoconductive layer 27 as a function of the optical image produced.

The required straight-line course of the recording process is made at right angles to one another running movement of the recording medium 32 in the direction of arrow 34 and the deflection of the cathode ray 17 in the direction of arrow 20, as shown in FIG. 1, ensured.

The recording medium 32 provided with a charge image then runs through a device 35 and then by a device 36, whereby he according to the usual xerography technique in the former is dusted with a suitable colored powder, that in the latter mentioned Device is fixed on the recording medium.

The movement of the recording medium 32 in the direction of the arrow 34 takes place, for example, via a transport roller 37 driven by a motor 38.

To reduce the abrasion of the surface of the photoconductive layer 27 caused by the with her in The recording medium 32 standing in contact with it or being passed in its immediate vicinity is the The surface of the photoconductive layer is provided with relatively small metal layers, as shown in FIG. 1 to 3 represent schematically. The surface of the photoconductive layer 27 and / or that of the metal supports 39 are designed as surfaces with a high degree of accuracy. However, this requires that the fiber 5 Optical layer 24 has a ground surface of high quality.

In the particular embodiment of the invention, the fiber optic layer 24 has a thickness of approximately 4.2 mm, while the photoconductive layer 27 has a thickness that is between a few millionths and fluctuates a few thousandths of a centimeter, according to the particular properties of the one used Photoconductive material.

Claims (2)

Patent claims: 1. Cathode ray tube for data technology printing units that work electrostatically, at which the radiation energy of the electron beam converted into light energy so acts on photoconductive layers according to their intensity via light-conducting elements, which in turn are in contact with an electrically conductive, translucent film, which is connected to a counter electrode via a voltage source of high potential, wherein the recording medium to be printed between this arrangement and the counter electrode is located, characterized in that the light-conducting elements by an insulating layer acting fiber optics (24) are formed, which is hermetically welded as a piston head to the tubular piston attachment (25), and that on the inside of the fiber optic (24) in a conventional manner the conversion of the Radiant energy in light energy causing layer (26) is applied and that on the Outside with the interposition of the transparent, electrically conductive film (29) an areal formed photoconductive layer (27) is arranged. 2. Cathode ray tube according to claim 1, characterized in that the photoconductive layer (27) at the contact surface or plane with the recording medium (32) with small, against each other spaced metal supports (39) is provided. Considered publications:
German Patent No. 970 457;
U.S. Patent Nos. 2,928,973, 3,007,049;
"Electronic Computing Systems", 1959, Issue 1, pp. 40, 41; "Electronics", 1958, No. 2, p. 48. 1 sheet of drawings