SU809574A1 - Multichannel switching device - Google Patents

Description

54) MULTICHANNEL SWITCH

one

The invention relates to a pulse technique and can be used in various automation devices, telemechanics, computer technology as a pulse distributor, a ring counter, a switch, etc.

A multichannel commutator containing photo thyristors, LEDs, resistors, diode 4, and electromagnetic relay C, locked in each channel, is known.

The disadvantage of this device is low speed,

This disadvantage is eliminated in another known device containing photo thyristors, LEDs, a diode and a resistor 2 in each chamber.

However, this device has low performance due to the use of a bipolar signal source as the trigger source.

Closest to the present invention is a multichannel switch containing photo thyristors, LEDs, diodes, and resistors D in each bit.

The lack of this device is low reliability.

The purpose of the invention is to increase reliability.

The goal is achieved by the fact that in a multichannel switch, containing one cell of the same type, each of them contains the first photo thyristor optically connected to the first LED of the previous cell, the cathode of which is connected through the first resistor shunted by the series-connected second resistors and the LED. to the first power bus, a second photo-thyristor is inserted into each cell, the second photo-thyristor and the first LED are connected in series and through I limit A first resistor is connected between the start up slots, the first LED is additionally optically connected to the photodiode, the second photothyristor is optically connected to the second LED and the first photothyristor is connected to the second power bus.

The drawing shows a diagram of a multi-channel switch.

The multichannel switchboard contains n 1-1-type cells of the same type, 1-n, filled on a lockable Lot-tristol. 2-1-2-n, the anode of which is connected to the power bus 3, the cathode is connected to the output bus 4-1 to 4-n cells and through a resistor 5-1 - 5-p connected to a different power bus b, and a control electrode with a cathode of a photodiode 7--1 - 7-p, the anode of which is connected to the power bus 6, each cell also contains an LED 8- 1 - 8-p, the cathode of which is connected to the bus 9 of the trigger circuit and the photo-thyristor 10-1 - 10-p whose cathode is connected to the anode of the LED 8-1 - в-п, and the anode through resistor 11 Connected to chain start 12. The LED 8-1 - 8-p is optically connected to the photodiode 7-1 - 7-p of this cell and the photo thyristor 2-2 - 2-p, 2-1 of the next cell. The photothyristor 10-1-10-n is optically connected to the LED 13-1-13-n, the cathode of which is connected to the bus b and the anode through the limiting resistor 14-1 to .14-n with the output bus 4-1 to 4-p. The anode of the led 8-p through the diode 15 is connected to the bus 16 of the initial installation.

The device works as follows.

After turning on the power, all photoresistor 2-1 - 2-n are locked. The initial state is established by applying voltage to busbars 9 and 16. At the same time, the opening LED 8-p emits light energy and turns on the photo thyristor 2-1. The current of the photothyristor 2-1, which flows through the resistor 5-1, creates a voltage drop across it, with the result that a voltage appears on the output bus 4-1 of cell 1-1, and the second LED 13-1, emitting light energy, lowers the threshold turning on the photothyristor 10-1. Channel switching is performed by supplying single-field pH1 pulses of arbitrary shape or sinusoidal voltage between Shingidi 9 and 12. When the voltage in the trigger circuit reaches the turn-on threshold of the photo thyristor 10-1, it turns on. The inclusion of photothyristors 10-2 - 10-n of the following cells 1-2 - 1-n is eliminated due to the fact that the second LEDs 13-2 - 13-n are emitting light energy, and, consequently, the threshold for switching on additional photothyristors 10-2 - 10 to 10 more significant than the additional 10-1 photo thyristor. The inclusion of an additional "toTOTHpHCTopa 10-1 causes the first LED 8-1

starts to emit light energy, which leads to the inclusion of the photothyristor 2-2 and the locking of the photothyristor 2-1, i.e. the second cell 1-2 turns on and the first one turns off

- After the end of the input pulse

in the trigger circuit (or the release of voltage from the trigger circuit), the photo thyristor 10-1 closes.

I.

When a second pulse is applied to the trigger circuit (or the secondary voltage supply is arbitrary forks), the photo thyristor 10-2 is turned on, since it is affected by the light flux from

the second LED 13-2 and its voltage for switching on at the moment, than with the remaining additional photo thyristors 10-1, 10-3 - 10-p, which leads to the inclusion of the third

cells 1–3 and turn off the second 2–2, etc.

Claims (3)

Invention Formula five A multichannel switchboard containing cells of the same type, each of which contains the first photo-thyristor, the cathode, optically connected to the first LED of the previous cell 0 through a first resistor, shunted by series-connected second resistors and an LED, and a control electrode are connected via a photodiode to a first power bus, characterized in that, for the sake of reliability, a second photothyristor is inserted into each cell, the second photothyristor and the first LED are connected , but also through the boundary of the resistor, the resistor is connected between the trigger buses, the first LED is additionally optically connected to the photodiode, the second photothyristor is optically connected to the second An LED, the anode of the first photo-torus, is connected to the second power supply. Sources of information taken into account in the examination 1. USSR author's certificate. 518002, cl. H 03 K 17/78, 07.27.74. O 2. USSR author's certificate  571907, cl. H 03 K 17/78, 08.08.73. 3. USSR author's certificate  5J1906, class H 03 K 17/78, 06.08,73 (prototype).