SU27405A1 - Device for automatically achieving the synphasic rotation of Nipkoff disks - Google Patents

Description

A device is proposed for achieving the synphasic rotation of NipK9v discs in installations for transmitting images.

According to the invention, there is a special opening in the transmitting disk, through which a corresponding light signal is fed to the photocell, and on the receiving disc there are a number of openings closed by multi-colored light filters followed by a light relay controlled by the photocell from the transmitting disk, due to which synphase occurs at the appearance of a glow in the corresponding hole with a previously known color.

In FIG. 1, 2 and 3 schematically depict the proposed device; FIG. 4 and 5 other forms of its implementation.

On the Nipkov disk 1 (Fig. 1), located at the transmitting station, a small additional hole 2 is made so that it lies outside the image 3 projected onto the disk. From a special light source, the rays pass through this hole and fall onto the photocell behind the disk. The passage of a hole through the hole 2 occurs only in those moments when the rotating disk occupies the position shown in the drawing, i.e., when the hole lies on

verticals 4 (at these moments, none of the holes 5 and 6, which are the first and the last in a series of holes that decompose the image), hits the image 3.

The Nipkov 7 disk located at the receiving station (Fig. 2) differs from only the NTO described by the fact that it is bordered with a glass rim 8 colored differently in some part of it. For example, h; 9, red 10 and yellow 11. There is a light relay near the head of the disc, which flashes from electrical impulses coming from the transmitting station and received when a beam passes through the aperture 2 on the photocell.

Thus, if both disks 1 and 7 rotate at the same speed and maintain, therefore, respectively the same position, then each passage of the beam through the opening 2 will correspond to the passage of the beam also through the same glass, for example, through red glass ten.

The disk 7 is mounted on the axis of the electric motor 13 (FIG. 3), mounted on the stand 14 so that when the handle 15 is turned to the left or the right, it rotates together with the electric motor and the salg disk to one side or the other.

When the transmitter is operating, light flashes come to the receiver from the transmitted image 3, when it is decomposed into elements, and from the action of the light beam passing through the opening 2.

If you know the pre-speed of the disk, the electric motor 13 is started, giving it the same speed, and follows the upper stripe of the rim 8. If the phases of the discs do not coincide, then the eye 16 sees the yellow illuminated AND or the blue 9 stripe. In order to obtain an identity in the positions of both disks, turn the disk 7 to the right or left and so that the rays pass through the glass in advance of a known color, for example, through red glass 10.

For this purpose, another embodiment of the device can be applied. The Nipkov disk located on the receiver may consist of a disk 17 and a ring 18 (FIG. 4), wherein the ring 18 carrying the analyzing image on itself, i.e. the holes located in a spiral, may rotate around the disk 17.

The rotation of the ring 18 can be accomplished, for example, by the help of the gears 19 and 20 and the mechanism 21 which drives them, which acts when the electrical contacts included in the wires 22 are closed (Fig. 5).

Thus, if the phases of the disks are shifted, for example, instead of red, at which the phases coincide, the glass is illuminated with a different color, then the contacts are closed and the mechanism 21 is actuated by this, and during rotation of the electric motor 23, the disk 18 is moved so that the beam passes just through the red glass.

The device can be made in such a form that it is possible to reach the same frequency of rotation of the discs of the transmitter and receiver automatically. In this case, the bezel 25 is opaque except for a small strip 24 on it, through which the flared beam passes and falls onto the photocell. The mechanism 21, which sets in motion the teeth, is designed so that it is in operation as long as the ray of light is not puff. AT.

gives to the photocell, and the current that has arisen in this last does not open the contacts and does not stop its operation. Thus, while there is no coincidence in the phases, i.e. until the flashing rays pass through the rim strip, until the mechanism 21 drives the gear, but as soon as the light passes through the transparent strip 24, the photocurrent caused by it immediately interrupts the circuit and the mechanism 21 stops, thereby automatically fixing the desired position disk 18.

The subject matter of the invention.

Claims (3)

1. A device for automatically achieving the synphasic rotation of the Nipkov disks, characterized in that the transmitting disk has a special opening 2 through which a corresponding light signal is fed to the photocell, and on the receiving disk there are a number of holes 9, 10, 11 closed by multi-colored light filters The light relay is placed behind it, controlled by the photocell from the transmitting disk, due to which the phase response occurs when a luminescence appears in the corresponding hole with a previously known color. 2. The form of the apparatus according to claim 1, characterized in that in order to correct the phase difference between the receiving and transmitting Nipkova disks, the receiving disk is made in the form of a ring 18 rotated on a rotating disk 17 with a toothed inner edge 20 blinding with a toothed wheel 19, mounted on the disk 17 and turned by an electromagnet on one or several teeth, when receiving a signal of non-phase response, wherein the electromagnet is powered through contact rings on the engine axis. 3. The form of the device according to paragraph.n. 1 and 2, characterized by the nf / naming of the photocell placed behind the receiving disk and controlling the electromagnet acting on the gear wheel 19. in order to automatically correct for in-phase variance. to the author's certificate IL L | 27405 A. Adamian aig