DE825562C - Image pickup tubes for television broadcasting purposes - Google Patents

Description

P. 175)

ISSUED DECEMBER 20, 1951

Ei2? 7VIIIa / 2ia ¹

is used

The invention relates to image pick-up tubes for television broadcasting purposes or the like

In the case of television pick-up tubes, a remarkable advantage can be obtained if the optical Image of the object to be transferred not directly on that scanned by the electron beam Screen, but is projected onto a photosensitive electrode and what is generated there Electron image is then projected onto the screen. With a television pickup tube of this type, which can be counted as electron image type, the aim should be that the axis of the electron-optical System is perpendicular to the axis of the screen, so that structural and bundling difficulties are reduced to a minimum can be set. In tube structures with cathode potential stabilization such that im Operation of the electron beam that scans the screen, hits it at zero velocity, ao it is desirable that the ray approaches the screen with normal incidence, since the maintenance of the beam with precise focus is important. Since also usually the bundling with the help of a bundling coil that surrounds the tube and extends beyond the screen extends, so constructive difficulties would arise if the scanning beam obliquely on the Screen would be projected, as in some embodiments of electron image-type pick-up tubes *, who work with anode potential stabilization, d. H. with high-speed scanning

'diness. Therefore, it has recently been proposed to use a so-called double-sided screen in tubes of the electron image type which operate with cathode potential stabilization, the electron gun and the photosensitive electrode being arranged on different sides thereof. However, it has been found that double-sided screens have a number of disadvantages. The object of the present invention is to provide an improved image pickup tube for the purposes of television broadcasting or the like, namely an electron picture tube without using a double-sided screen, in which from one end ⁴ to the other successively a photoelectric cathode for converting an optical image into a Electron image, an electron gun and a screen which is scanned by an electron beam generated by the electron gun abao are arranged. According to the present invention, means are provided to generate oppositely directed deflection fields between the photoelectric cathode and the gun and between the gun and the screen, so that although the scanning beam generated by the electron gun is guided over the screen, the effect of the deflection voltages on that of the photoelectric cathode however, the electron image projected on the screen is canceled. The invention will now be explained as an example with reference to the drawings.

Fig. Ι shows an example of an inventive Image pickup tube;

FIG. 2 is a modified embodiment of the device shown in FIG.

The tube shown in Fig. 1 consists of an evacuated glass bulb 1, which is attached to a The end is provided with a window 2 on which a photoelectric cathode 3 is located. At the other end of the tube 1 is a screen, which consists of a thin layer of dielectric Material 4 and a conductive signal electrode 5 consists. The layer 4 lies on the photocathode 3 opposite and the electrode 5 behind it on the side remote from the photocathode 3. Between the photocathode 3 and the layer 4, an electron gun 6 is arranged, which consists of a hot cathode 7, modulation electrode 8 and anode 9. These electrodes are coaxial, and their common axis is transverse to the axis of the piston 1. The one shown in the drawing Location in the middle between the electron gun 6, between the electrode 3 and the Layer 4 is desirable, but not essential. Electrode 3, electron gun 6 and layer 4 are one behind the other, and the electrode 3 and layer 4 are perpendicular to Axis of the piston 1. The anode of the electron gun extends almost completely over the piston 1, and the diameter of the cannon 6 is chosen as small as possible in order to avoid the casting of shadows on the to make dielectric layer 4 minimal. In the drawing is the diameter of the electron gun shown enlarged for the sake of clarity. Opposite the layer 4 are im Area of the central axis of the piston 1, as shown, small circular openings in the modulation electrode 8 and anode 9 are provided, and on the hot cathode 7 is below these openings electron-emitting material applied. The cathode of the electron gun 6 is grounded, the anode 9 is connected to the positive pole 10 of a voltage source of about + 300 volts and the modulation electrode 8 is connected to a source 11 providing a suitable bias voltage. Between the electron gun 6 and the dielectric layer 4 is on the inner surface of the piston 1 a wall electrode 12 made of resistance material is provided. The wall electrode 12 is on her next to the cannon lying end with the mentioned voltage source 10 and close to the other of the layer 4 lying end connected to earth, so that along the wall electrode from left to on the right (in the drawing) a uniform voltage drop occurs, which serves to effectively flat equipotential surfaces perpendicular to the center axis of the piston 1 between the Gun 6 and the dielectric layer 4 to be erected. These equipotential areas slow down the from the electron beam emerging from the electron gun, so that it hits the screen with a approaching low speed. Between the cannon 6 and the electrode 3 there is a similar one Resistance wall electrode 13 on the inner surface of the piston provided. The wall electrode 13 is located next to the electron gun End to the voltage source 10 and at its other end to the negative pole of a voltage source of e.g. B. - 500 volts connected so that the Equipotential surfaces caused by the wall electrode as a result, the on the photoelectrode 3 Accelerate the electron image that is released in the direction of the electron gun 6. The photo, Cathode 3 is at the voltage source 15. At 14 an optical system is shown schematically, which has the task of the to be transmitted To image the object on the electrode 3.

The apparatus includes between the gun 6 and the dielectric layer 4 deflection coils (shown schematically at 16) n with sawing ₀ dental flow from line and frame frequency are energized to deflect the electron beam from the gun 6 in mutually perpendicular directions, so that the beam scans the dielectric layer 4 in a known manner. The part of the piston 1 lying to the right of the u ₅ cannon 6 is surrounded by a focusing coil 17 lying coaxially to the piston 1. The signal electrode 5 is connected to earth via a load impedance 18, from which the signals are picked up via the line. _ί20 between the gun 6 and the electrode 3 other deflection coils 20 are provided which are the coils 16 similar, but connected in the opposite sense. The coils 20 are fed with sawtooth currents which are identical to those applied to the coils 16. The one on the left

The part of the tube that lies next to the cannon 6 is, as shown, surrounded by a focusing coil 21 . As a result, when an optical image is projected onto the electrode 3, the electron image released at the latter is accelerated by the wall electrode 13 and, while it is focused by the coils 21 and 17, thrown past the gun 6 onto the dielectric layer 4 and fall there at a rate corresponding to about 500 electron volts, essentially with normal violence. As a result, abundant secondary electron emission is produced at the dielectric layer 4 and, in a known manner, a charge image corresponding to the optical image is generated on the screen by positive charging of the electrical capacitance of the screen. The deflection imparted to the image electrons by the coils 20 is opposite to the deflection caused by the coils 16, ίο whereby the first-mentioned coils serve to effectively cancel the deflections caused by the second, so that the electron image effectively without a resulting deflection on the dielectric Layer 4 is projected. In Fig. 1 two extreme deflections of the electron image in the vertical direction are shown in dotted or dash-dotted lines. However, since the electron beam from the cannon 6 only traverses the deflection fields generated by the coils 16, it scans the dielectric layer 4 and periodically stabilizes it at cathode potential in the usual manner, as a result of which signals corresponding to the charge pattern appear at the impedance 18. The focusing coil 17 serves to collect the scanning beam. .i5 Because the parts of the wall electrodes 12 and 13 in the vicinity of the gun and the anode 9 of the gun 6 are kept at the same potential, a distortion of the electron image due to the action of the anode 9 on the electrons is essentially prevented. In spite of everything, however, some electrons of the electron image are intercepted by the anode 9, so that effectively j a shadow of the gun sweeps over the dielectric layer 4, which is why it is desirable that the gun with respect to the axis of the KoI-! bens ι should be arranged symmetrically. Furthermore, in the arrangement shown in FIG. 1, it is necessary that the diameter of the glass bulb is at least twice as large as the length of the diagonal of the photocathode surface 3 onto which the optical image of the object to be transferred is projected.

In order to avoid the risk of an undefined electron image as a result of unequal deflections on the opposite sides of the gun 6, it may appear desirable to carry out the scanning of the electron image in an electrically field-free space. According to FIG. 2, this can be achieved by replacing j the resistance wall electrodes 12 and 13 with wall electrodes 22 and 23, which effectively have no j resistance, at a certain distance from the electrode 3, as shown in FIG and ends the dielectric layer 4 and conductively connects highly straight, permeable mesh electrodes 24 and 25 to the outer ends of the wall electrodes 22 and 23, the meshes of which are perpendicular to the central axis of the piston 1. Otherwise, the embodiment of the tube shown in FIG. 2 is similar to that of FIG. 1, and the corresponding parts are provided with the same reference numbers.

In order to reduce the amplitude of the scanning movements for the electron image, a further Focusing coil may be provided coaxially to the piston, which extends over the area of the cannon 6 extends. This further coil has the task of generating an axial magnetic field that is twice is as strong as that of the coils 17 and 21 on the dielectric layer 4 and on the electrode 3 generated. This would also make it possible to determine the diameter of the tubular piston ι to decrease.

The one here with regard to devices with pick-up tubes, those with cathode potential stabilization work, explained invention can also be used for devices with other types use of pickup tubes.

Claims (7)

PATENT CLAIMS: ι. Image pick-up tube for television broadcasting purposes o. The like. In which from one end to the other successively a photoelectric Cathode for converting an optical image into an electron image, an electron gun and a screen, which from an electron beam generated by the electron gun is scanned are, characterized in that means are provided to switch between photoelectric Cathode (3) and cannon (6) and opposite between cannon (6) and screen (4) to generate directed deflection fields, so that while the deflection fields from the electron gun (6) generated scanning beam is guided over the screen (4), the effect the deflection fields on the projected by the photoelectric cathode (3) on the screen (4) Electron image is canceled however. 2. Image pickup tube according to claim 1, da- n ₀ characterized in that the electron gun (6) has an anode (9) which surrounds the other electrodes (7 and S) of the gun (6) and which has a tubular shape and is perpendicular and substantially symmetrically at 1.15 with respect to the central axis of the tube. 3. Image pickup tube according to claim 1 or 2, characterized in that between the photoelectric cathode (3) and cannon (6) i _ao and between the cannon (6) and screen (4) conductive electrodes (12, 13) are provided, which the areas , in which deflection fields are generated, and that at least the parts of the conductive electrodes (12 and 13) in the vicinity of the gun (6) at the potential the electrode of the cannon (6) having the strongest positive voltage. 4. image pickup tube according to claim 3, characterized in that the conductive elec- · Troden (22, 23) !! insignificant resistance are so that they establish a substantially uniform potential in their areas. 5. Image pick-up tube according to any one of the preceding claims, characterized in that that it is arranged so that the screen (4) when scanned by the in the Electron gun (6) generated electron beam, is stabilized at a potential, which is substantially equal to the potential of the cathode of the electron gun. 6. image pickup tube according to claim 4 and 5, characterized in that the conductive Electrodes (12, 13) made of resistance ao material and extend at their outer ends up to the vicinity of the screen (4) or the photoelectric cathode (3) and that the outer end of the conductive electrode (12) between the cannon (6) and the screen (4) essentially at the potential the cannon cathode (7) and the outer end of the other conductive electrode (13) on the Potential of the photoelectric cathode (3) is held, which is significantly more negative than the potential of the cannon cathode (7), so that a generated at the photoelectric cathode (3) Electron image on the screen (4) causes a positive charge image. 7. Image pick-up tube according to any one of the preceding claims, characterized in that that means for focusing are provided to between photoelectric Cathode (3) and cannon (6) and between cannon (6) and screen (4) to generate an axial magnetic field, and that further means are provided to increase the field strength in the area of the cannon, so that the influence of the on the electron image between the photoelectric cathode (3) and Screen (4) acting deflection amplitude is reduced. 1 sheet of drawings I 2557 12.