SU1599980A1 - Switching device - Google Patents

Abstract

The invention relates to a pulse technique and can be used to control a two-wire line with various loads with several modes of operation. The purpose of the invention is simplification. The switching device contains supply busbars 1.2, loads 3.14, a photoimistor 4 and an optocoupler LED 13, switch contacts 5, capacitors 6 and 9, diodes 7 and 10, resistor 8 and resistors 11, 12 of the voltage divider. Turning on the LED 13 between the connection point of the diode 7 with the capacitor 6 and the midpoint of the divider formed by resistors 11, 12, reduces the number of key elements in the circuit. 1 il.

Description

The invention relates to a pulse technique and can be used to control over a two-wire line various loads with several modes of operation.

The purpose of the invention is to simplify by reducing the number of key elements used.

The drawing shows a circuit diagram of a device.

The switching device contains a supply bus 1 and 2 of an alternating current, to which a load is connected (group (5 lamps) 3 through a photistor 4 optocouplers and contacts 5 of the switch, a first capacitor 6 connected through the first diode 7 and a resistor 8 in parallel to the serial circuit from load 3 and a photo-resistor 4, a second capacitor 9, connected through a second diode 10 in parallel with a diode 7 and a capacitor 6 connected in series, resistors 11 and 12 of a voltage divider connected in parallel with a capacitor 9, and an optocoupler LED 13, connected as diode 7 between the connection point of the diode 7 to the condenser 6 and the midpoint of the divider formed by resistors 11 and 12. The feeding network directly via pins 5 is turned on, another group of lamps 14.

The switching device operates as follows.

With open contacts, the entire circuit is de-energized. When the contacts 5 are closed, the lamps 14 are turned on, and the capacitors 6 and 9 through the resistor 8 and diodes 7 and 1Θ begin to charge to a voltage determined by the ratio of the resistances of the resistors 12 and 8. In the steady state, the resistor 11 shunts the LED 13.

The resistance of the resistor 11 is selected so that, with permissible changes in the supply voltage, the current through the LED 9 is less than the turn-on current of the photosimistor 4 (usually 5-10 times less than the resistance of the resistor 12). In this case, the photosimis is strained during short-term detours or transitions. Since the capacitance of con6 is chosen much more, then, as the torus 4 and load 3 remain in the off state.

When the contacts 5 are opened, the lamps 14 are de-energized, and the capacitor 9 begins to discharge. In this case, a voltage drop is created on the resistor 12, directed towards the voltage of the charged capacitor 6 and prevents the current from increasing through the LED through the capacitor capacitor 9, the discharge of the latter, the voltage across the resistor 12 is reduced to a value sufficient for the photosimistor 4 to be turned on by the discharge current of the capacitor 6.

If during this period the contacts 5 are closed again, then in addition to load 14, load 3 is turned on through the photo-transistor 4. After the capacitor 9 is charged, the on-state of the photo-transistor is maintained by a small current through the LED 13, which is determined by the voltage drop across the resistor 11. The claims

Claims (1)

A switching device that lives on the AC bus, the load is connected through the optocoupler photomistor and the switch contacts, the first capacitor connected through the first diode and resistor in parallel to the serial circuit from the load and the optocoupler, the second capacitor connected through the second diode in parallel to the serial circuit from the first capacitor and a diode, a resistive voltage divider connected in parallel with the second capacitor, and an optocoupler LED, connected in accordance with the first diode and connected m is the first output to the connection point of the first diode with the first capacitor, characterized in that, for the sake of simplicity, the second output of the optocoupler LED is connected to the midpoint of the resistive voltage divider.