DE229916C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 21 a. GROUP

MICHEL SCHMIERER in CHARLOTTENBURG.

are embedded in parallel and vertical rows.

Patented in the German Empire on April 30, 1910.

All apparatus for the electrical remote transmission of images require a device which converts changes in light into changes in current. There are two ways to do this: 1. The light is converted directly into electricity, which could be achieved with so-called photoelectric elements, if the excessively low voltage of at most 0.5 volts with the enormous resistance of several 10,000 ohms was not a practical implementation would exclude; 2. the light is allowed to act on substances that change their resistance through irradiation, see above. that a current flowing through these substances undergoes changes. Among these substances, gray-crystalline selenium is characterized by a high level of electrical light sensitivity. The resistance of selenium decreases through exposure to almost the same extent for the rays of all wavelengths, which enables transmission in natural brightness values for all parts of the spectrum. Selenium has the unpleasant property of great "inertia" in common with all other light-sensitive substances. The resistance does not decrease at the moment of exposure or increases at the moment of darkening, but requires a time of about ¹ ₂₀ to a second.

Since the electric current can only undergo changes in succession, here but not only the light changes of a single

individual point, but rather an entire area, it is necessary to split the image to be transmitted into individual light elements and to transmit the brightness values of the individual light points one after the other. If you use a single light-sensitive element at the transmitter and let the light points act one after the other through some optical or mechanical device, the transmission of the entire image requires a fairly long period of time, since the light-sensitive element, the selenium cell, as a result its inertia can be exposed to exposure only ten times per second. Real optical images of living beings or moving objects cannot be transmitted with the aid of a single selenium cell, and the construction of a television with a single selenium cell is also impossible. For the latter, it is absolutely necessary to transmit the entire image at least ten times per second so that the eye should receive the impression of a continuous image of the transmitted object _{(due to the property of the retina to retain a light stimulus for about 10 seconds).} Since about the same time is required for the "recovery" of the selenium, a special selenium cell must be used for each point of light. It has been proposed to arrange the selenium cells on the edge of a rotating disk and the individual light points through an optical device

Ii

to project one after the other onto the selenium cell located at a certain point, which is then switched on alone in the circuit at the same time. Is easier it is to arrange the cells in a plane, on this by means of a lens combination the image to project the object to be transmitted in a greatly enlarged scale and the Selenium cells one after the other in the circuit

ίο to be switched on. So far, a single Commutator used so that from each selenium cell a wire to a lamella of the commutator had to be led. The number of revolutions of the commutator was relatively small, namely 10 per second, on the other hand the number of commutator bars and lead wires was extremely large.

According to the invention one comes with a much smaller number of commutator bars and lead wires by using two commutators; then is the number of lamellas and lead wires for each of the two commutators equal to the square root of the selenium cell count or that of the old arrangement required number of lamellar and feeder wires.

The principle of commutation can be seen from the schematic FIG. 1. There are 36 points of light to be transmitted. Two contact pieces are required for each light point. These are indicated by concentric circles. indicates between which one has to think of selenium. The six large circles of one of the vertical rows α to f are conductively connected to one another and to one of the contacts of the commutator ι. Likewise, the six small circles of a horizontal row g to m are conductively connected to one another and to one of the contacts of the commutator 3. Then only a single cell can be switched on in the circuit, namely the one whose large circle is in the row switched on by commutator 1 and whose small circle is in the row switched on by commutator 3. In the position shown, the contact lever 2 and 4 flows z. B. the current from the positive pole of the battery 5 through the lever 4 to the circles located in the row k , but can only continue through the hatched cell, the large circle of which is in the row c just turned on by the lever 2 Long-distance line to the receiver and from there back to the negative pole of the battery.

Now imagine the levers 2 and 4 rotating, namely the lever 2 with six times that large number of revolutions like the lever 4. While the lever 4 slides on one of the contacts, the lever 2 then makes six contacts one after the other. Be through the lever 4 all horizontal rows switched on one after the other. During a number turned on remains, the lever 2 switches on all cells of this row one after the other, so that when the Hebei 4 one, the lever 2 has made six turns, one after the other all cells the plate 6 are turned on.

Of course, other commutation devices can also be used; The only condition is that the commutation takes place faster in one of the devices should than with the second, and so much times faster than selenium cells in each with the former connected series are present.

The same commutation principle can also be applied to the receivers for the image transmission use. The individual light-generating elements, such as Geissler tubes, 'spark lines or mechanical devices, are attached to a board in rows and the feed and discharge wires in the manner described with two commutators tied together.

In reality, the contact pieces in selenium cell panels will not be designed as circles, because it would increase costs; also the attachment would cause difficulties Prepare and leave too much space empty between the circles, which is also beneficial could be filled with selenium.

The best utilization of space with simple and inexpensive manufacture should be achieved with that shown in FIG to 6 shown embodiment of the selenium cell plate.

Instead of the vertical rows of circles, there are copper bars 7 of somewhat smaller size Length than the side of the plate 6, which is made of insulating, fire-resistant material, such as porcelain, Slate, marble or the like., Is made. The copper bars are halfway up in grooves in the porcelain plate and can be attached in any way. In the The fields of the porcelain plate formed by the copper bars are each a series of openings provided, which latter from the copper bars and from each other equal distances to have. Screws 8 are inserted through these openings and into the rear The copper bars 9 lying on the porcelain plate are screwed in: The copper bars 7 are perpendicular to those 9. The appropriately rectangular heads of the screws 8 are like this high that their upper edges are in the same plane with those of the copper bars 7, ng and they are so long that they can be easily rotated. The space between the Screw heads and copper bars are smeared with melted selenium and the like finished plate heated in a known manner to about 2io ° so that the selenium changes to the light-sensitive state. The approaches

13 on the porcelain plate are used to hold the selenium in place. The power supply to the copper bars 7 is mediated by twist te 12, which is inserted through the plate 6 will. The current is supplied to the copper bars 9 by means of cap screws 10 or the like attached wires 11. In this embodiment, the selenium cell plate forms each time that between the corresponding part of a copper bar 7 and one on the right and one on the left of which the screw head present selenium is a single cell.

To bring about a particularly sharp reproduction, the selenium can be placed between neighboring Screw heads' are scraped out.

This arrangement of the selenium cell table has the advantage that relatively very few Power supplies are required. For example, a plate with 10,000 selenium cells only requires 200 feeds; the same plate in the previous version would have 20,000 feeds require. If a rectangular plate is used, the number of Contact pieces of a row be equal to the number of rows der.anderen contact pieces; in in this case the savings in lead wires are not quite as great as with square ones Plates.

In addition, this arrangement has the advantages that the attachment of the individual selenium cells poses no technical difficulties and that the electrical resistance of all Cells are the same size because they are made of the same material and exactly the same Have undergone treatment. Should the resistance be different in spite of all this, so it can be increased in the cells of lower resistance by scraping out selenium will.

Claims (2)

Patent Claims: ι. Commutation method for remote image transmission, in which the individual light-sensitive or light-generating elements, such as selenium cells, Geissler tubes, cathode ray tubes o. B. magnet armatures, galvanometer needles o. The like., For more or less strong dimming of already existing light rays are expediently embedded in parallel and vertical rows, characterized in that of the individual rows (a to in) of the supply and discharge contact pieces to the horizontal and vertical rows (g to m and a to f) of the elements, the individual feed contact pieces (g to m) each with a lamella of a commutator (3) and the individual discharge contact pieces (a to f) each with a lamella of a second commutator (1) conductive are connected, the number of revolutions of one commutator (1) is so much greater than that of the second (3), as there are contact pieces in each individual row (a to f) connected to the first commutator, for the purpose that, while the slowly rotating commutator (3) moves one after the other over a lamella belonging to a certain row - (e.g. g) through the faster rotating commutator (1) all rows of elements (a to f) connected to its lamellas are switched on, so that during one complete revolution of the slower rotating commutator all elements of the board are supplied with power one after the other. 2. Commutation method according to claim i, in which selenium cells are used, characterized in that the contact pieces of one type of row (α to f) of the selenium layer dividing contact rails (7) or the like. And the contact pieces of the other type of row (g to h) are formed by bodies (8), the latter being carried by pins inserted into the plate (6) and conductively connected in rows. 1 sheet of drawings.