DE560224C - Scanning device for television transmitters with spiral perforated disks - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
SEPTEMBER 29, 1932

REICH PATENT OFFICE

PATENT LETTERING

.CLASS 21 a ¹ GROUP

Television act. in Berlin-ZehlendorP) Scanning device for television transmitters with spiral perforated disks

Patented in the German Empire on April 16, 1931

In the light beam scanning transmission method, the object to be transmitted is known scanned point by point by a light beam. That the brightness values of the scanned The light reflected from the object falls on one or more photocells. The photocell currents then control the transmitter after appropriate amplification. So it becomes a certain part of the

ίο Nipkow disk, the so-called image section, mapped into the plane of the object to be transferred. So far, the procedure has always been that the image section on the Was completely illuminated, with the upper and lower edge of the In the image section, the pane itself acted as a screen, but the lateral boundaries by a special cover that can be attached in front of or behind the Nipkow disc can have been obtained. So there was always an area on the rotating disk that was at least the same, but mostly larger than the image section was, illuminated.

Because of the limited synchronizing power available, the Nipkow disc may have only a small moment of inertia. The disc therefore usually consists of a thin sheet of metal and is still in many cases left out. This way, once there is a small moment of inertia, then however

an absolutely even run in which the scanning holes are exactly in one plane, achieved because the disc is automatically aligned while running by centrifugal force will. In order to simplify the amplifier device or to obtain a sufficiently large photocurrent, is the image section is illuminated as brightly as possible.

This intense lighting and the strong warming associated with it, which is only local and, in relation to the entire circumference of the disk, occurs unevenly, now caused by the thin sheet metal of the Nipkow disks thermal stresses that cause the panes to flutter and sway. This disorder can e.g. B. be eliminated in that the heat rays emitted by the light source through a Filter (cooling cuvette) are absorbed '. However, since the photocells for light last longer If you are still sensitive to the wavelength, you lose a lot of energy in this way.

According to the present invention, the entire image section is not, as before illuminated at the same time, but only the scanning hole is illuminated, which just worried about scanning. The device that suppresses this bundle of light rays causes, of course, must be included

*) The patent seeker stated as the inventor:

Max Heim in Berlin-Zehlendorf.

the scanning openings are moved evenly. This is most conveniently done by placing a second (in the following heat protection disk) in front of the Nipkow disk called) with apertured disc sets. The openings are in exactly the same places as the actual ones Scanning openings, but have a slightly larger diameter, so that the »O the tactile hole can be well illuminated.

In Figs. Ι and 2 the arrangement is schematic in side view and top view shown. The Nipkow disk 1 sits on the shaft 2, on which also the Heat shield 3 is attached. The image section on the Nipkow disk, whose .Side edges are represented by 4 and 5, is by means of the light source 6 and the Condenser lens 7 illuminated. According to the invention is in front of the scanning hole 8, which may just be in the picture, an opening 9 in the heat shield 3, which is chosen so large that the marginal rays drawn to the outermost edges of the condenser lens 7 are just barely pass through the opening 9. If you would work without a heat shield, so would be the entire luminous flux passing through the image section (see the dashed rectangle in Fig. 2), contribute to the heating of the Nipkow disk. With the heat shield on the other hand, only the luminous flux that passes through the opening 9 comes into question. As can be seen without further ado, is the risk of heating is significantly reduced. It can of course happen that the heat shield, which almost all the energy in the form of heat rays picks up, in turn begins to flutter. However, this does not bother when the openings 9 in Fig. 2 can be made slightly larger than theoretically required, and between A sufficiently large distance is provided for the heat protection disk and Nipkow disk.

According to Fig. 3, the arrangement in Nipkow disks of small diameter can also be made so that two veins used several heat shields so that only a very small amount of heat is applied to the Nipkow disk. As Fig. 3 shows, the problem can be solved constructively so that both the two Heat protection disks as well as the Nipkow disk as circular rings on a wheel body 10 are fastened by means of intermediate rings 11.

You can work in the same way even if the image decomposition is not using a simple spiral perforated disc, but by other methods, e.g. B. with the help of two rotating disks with radial slots or with slot diaphragms in the form of endless belts etc., is made. According to the present inventive concept, in In these cases, the difficulties in illuminating the image area with high light intensities be eliminated by means of a heat shield or a moving one Heat protection tape only the slot required for scanning and not the entire image area is released.

Claims (1)

Claim: Scanning device for television transmitters with spiral perforated disks, characterized in that that in front of the scanning a heat shield is attached, which always only the part of the Lets pass the light emitted from the light source, which is used to illuminate the the spiral perforated disk opening is required for scanning. 1 sheet of drawings -. Berlin, printed in Der reichsdruckere!