DE972146C - TV receiver for large area image reproduction - Google Patents

Description

P. 17S)

ISSUED MAY 27, 1959

VIIIaI 21a ¹

Dusseldorf

The invention relates to an arrangement for storing very short by relatively long Rest intervals of separate electrical impulses in television receivers for large-area picture reproduction by means of a capacitor. Television receivers are used to generate an image on the screen been proposed to use an electro-optical element (German patent specification 967441). To feed such an element a network of horizontal and vertical ladders appears on the back of the screen attached and also the screen with a conductive layer covering the entire surface Mistake. In order to extend the effectiveness of the image pulses on the electro-optical elements, is has already been proposed, a delay by means of a storage capacitor and bleeder resistor to be provided. However, this method has proven itself due to the insufficient constancy of the voltage not on the electro-optical element.

According to the invention are therefore in a remote ■ visual receiver for large-area image reproduction with

909 522/26

a plurality of electro-optical elements, in which each electro-optical element has a storage capacitor is assigned and the image signal element by element by a rotating line frequency Distributor is distributed one after the other to the individual capacitors, each capacitor two normally: locked rectifier assigned and the capacitor through the one through a contact of a rotating ίο changeover switch unlocked by the rectifier Distributor loaded and unlocked via the other through another contact of this switch Rectifier discharged shortly before the next charge. The gradual discharge of the Storage capacitor is thus · replaced by a rapid discharge, which immediately before the The new image pulse arrives. For the dry rectifier used in this arrangement becomes an improved strip shape that easily attaches in the designated frame can be provided.

In Fig. Ι a circuit of the two rectifiers is shown, over the storage capacitors are alternately loaded and unloaded; Fig. 1 a and 1 b show omitting all unimportant parts the switching state when charging and discharging the storage capacitor, whereby the current course in question is strongly drawn;

Fig. 2 to 10 show the improved rectifier shape in their details.

In Fig. Ι the circuit network is shown, which feeds the video. The image pulses, which have an extraordinarily high frequency (e.g. the order of magnitude of 20MHz) flow in via connection 1. The impulses are on a large number of conductors 2 (the number matches that of the pixels per line, e.g. 1000, distributed. The pulses distributed by the distributor 3 to the conductors 2 correspond in their Successive image pulses for the successive points of an image line.

In order to transmit these impulses to the screen, the ones that run vertically are on the back of the screen Head 4 attached, which are connected to the conductors 2 and their mutual distance to the Corresponds to the distance between two neighboring pixels in each line. There are also on the back horizontal conductors 13 attached, the number of which corresponds to the number of lines of the reproduced images (e.g. 625) matches. Their mutual distance corresponds to the distance between two electro-optical elements of the screen. Everyone Conductor 13 is via an IC link with a lamella 6 of the stationary collector 7, the horizontal lines 13 are connected via the capacitors 14, 15 etc. are connected to the lines 5 leading to the slats.

It has already been proposed to discharge the storage capacitors to the electro-optical Elements to provide resistances. However, this method has great shortcomings because of the Impulse can only act for a short time if the time constant for the discharge is too small. As a result, the reproduced image loses its brightness and contrast. At slower Discharge, however, there is a risk that the pulses until the arrival of the pulses for the next image has not flowed off completely and therefore disturb and distort the new image. This deficiency is avoided by the arrangement according to the invention.

On the collector 7 two brushes 28 and 29 run around, which are connected to the two voltage sources via resistors opposite polarity 30 and 31 are connected. The one at the back of the screen attached, its entire surface covering conductive layer lies over the line 32 at one pole of the voltage source 31. The el ektroop ti see element is with 33, the associated Rectifiers are denoted by 35 and 36 and the storage capacitor by 34. The rectifier 36 is with its one pole on one of the vertical lines 4, which are used to supply the image pulses to serve. The other pole of this rectifier and one pole of the rectifier 35 are located at one pole of the storage capacitor 34. The second pole of the rectifier 35 is at the Voltage source 31. The connection point of the both rectifier is connected to the electro-optical element.

In the idle state, i.e. H. when none of the brushes 28 and 29 are connected to a collelitorial cell is, the horizontal line 13 is via the resistor 16 at the grounded connection point of the two voltage sources 30 and 31. The polarity and level of the voltage source 30 supplied voltage is selected so that no current flows through the rectifier 36 can. With the polarity shown, the voltage source 31 cannot use the rectifier 35 either Electricity flow.

If now the brush 29 touches the lamella 6, the line 13 and thus the one connected to it Pole of the capacitor 34 is connected to the line 32 via the resistors 12, 16 and 37.

If the capacitor was previously charged, it is now discharged via the rectifier 35 (cf. Fig. La). The voltage source31 is in this Moment ineffective. As the brush continues to rotate, the brush 28 then touches the Lamella 6, so that the voltage source 30 is ineffective, and the distributor 3 is via the

More easily 36 the capacitor 34 a pulse corresponding to the instantaneous image signal fed. A current through the rectifier 35 cannot flow at this moment because the The voltage source is now fully effective again and the brush 29 has separated from the lamella. The processes described above are then repeated as the brushes continue to circulate. Included the brushes 28 and 29 run at frame rate and the distributor 32 at line rate.

Charge and discharge of the storage capacitor now only need a fraction of the

the amount of time available for each image. Thus every electro-optical Element energized practically all the time, so that a high degree of efficiency is achieved and that Flickering of the picture is avoided.

An example implementation of the rectifier and the storage capacitor for the individual electro-optical elements is: shown in the following figures. These elements ίο are two each along the horizontal. Rows attached. The screen can be made of soft Consists of fabric that can be rolled up around a horizontal shaft. The shot (vertically guided Thread) of this fabric is formed by tapes t5 made of a soft alloy, corresponding to the molds 51 and 52 are formed alternately. The chain of this fabric is through perforated and insulated bands are formed, which extend over the entire width of the screen and in, their Recesses 66 engage the hooks of the weft threads 51 and 52. The rectifiers will be on flat metal plates with bent edges mounted. Two soldier plates are placed, 55 and 56 along their edge and separates them by a sheet 57 of insulating material. Against the bent Area of the plate, 55 and 56 are each supported by two further rectifiers, 62 and 63. The Opposite surface of this rectifier rests on a metal foil 64, which contains all elements of a row conductively connects with each other. The entire arrangement is held by the angle piece 65. The rear sides of the platelets 55 and 56 are covered with a thin insulating film 58. This slide is held by a second metal surface 59 (corresponding to the metal band 64). The metal strip 61 is covered with a thicker insulating plate 60, which protects the entire assembly against the Elbow 65 is supported and isolated.

During production, the individual parts 65, 60, 59, 58, 55, 56, 53, 54, 63, 62 and 64 are put together and dipped together in a plastic mass, which solidifies in the cold state, so that a single piece called a block is made. Each horizontal line of the The screen consists of a large number of such pieces, which are connected to one another by the metal bands 59 and 64 are connected. To assemble the umbrella yourself, it is enough to put the consecutive Hook pieces into the angle strips 51 and 52. The electro-optical elements are glued to the surface immediately in front of the angle pieces 55 and 56.

Fig. 9 shows a different type of mounting, according to which four electro-optical elements be attached directly next to each other. The whole arrangement can be made with a structure Dominoes are compared. This consists of a square frame, its side surfaces consist of the four angle pieces 88, 89, 82 and S3; a central support67 is also present. The attachment of the individual parts can be seen in the illustrations. At the central Support 67 four rectifiers 68, 69, 70 and 71 are attached. The corresponding electro-optical Elements are attached to metal plates 72, 73, 74 and 75 which are suitably bent at an angle so that they rest on rectifiers 68, 69, 70 and 71.

The plates 72 and 73 are separated from one another by the insulating surface 76; likewise 74 and 75 are isolated from one another by J ¹ J. Four more rectifiers 78, 79, 80 and 81 are attached to the rear surfaces of the holders 72, 73, 74 and 75, and the metal frame members 82 and 83 are pressed against the edges of these holders. A metal strip 84, which is insulated from the foil 88, lies on the back surfaces of the rectifiers 68 and 70. Likewise, the foils 85 and 89 with the intermediate layer 87 of insulating material are arranged on the rear sides of 69 and 71.

Instead of using dry rectifiers to charge and discharge the storage capacitors, you can also get a peak current rectifier according to the description in the main patent serve. Fig. 10 shows a version with which it is possible to charge the capacitor as well as to discharge. Two tips are used in 113 and 113, each of which is connected to a voltage source are switched; the two supply voltages 112 and 114 are polarized in opposite directions. Before Tips are grid 115 and 116, which by a flat electrode 117 are separated from each other. 117 is connected to the electro-optical element, which is represented here by an electrometer. Should the peak currents through the image alternating voltages are amplitude modulated, a further control grid is connected in front of the collecting electrode.

The grid 116 is at rest by the Battery 124 biased and connected to this via series resistor 120. The series resistor for the grid 115 is designated by 123. at short-term positive bias of one of the grids, e.g. B. the grid 116, by closing the Switch 121 current flows and the electrometer is charged. It is reversed by closing of switch 122 discharged. When using the rectifier in the television receiver will be switches 121 and 122 by brushes 28 and 29 replaced.

Claims (3)

PATENT CLAIMS: i. TV receiver for large area picture reproduction with a variety of electro-optic elements, each of which is electro-optic Element is assigned a storage capacitor and the image signal element by element by a rotating at line frequency Distributor is distributed one after the other to the individual capacitors, characterized in that that two normally blocked rectifiers are assigned to each capacitor and the capacitor across the one through a contact of one rotating at frame rate Changeover switch unlocked rectifier ter loaded from the distributor and via the other through another contact this Switch unlocked rectifier is briefly discharged before the next charge. 2. Arrangement according to claim i, characterized in that the switching elements are put together in individual groups, switched and molded with a suitable insulating material to form a block. 3. Arrangement according to claim 1, characterized in that that to charge or discharge the storage capacitors dry or so-called Peak current rectifiers can be used. ■ Considered publications: Austrian patent specification No. 158 180; British Patent No. 434 905. 1 sheet of drawings © 909 522/26 5.59