SU1457110A1 - Triac control device - Google Patents

Abstract

The invention relates to a converter technique and can be used as an AC converter or regulator. The aim of the invention is to enhance the functionality and reduce the power of control. Under the action of the control signal, the symistor 1 is turned on and a current begins to flow through the ej-o power circuit. Depending on the magnitude of the flowing current, the intensity of the optical radiation of the LEDs 9 and 10 and, consequently, the resistance value 6, changes. Moreover, as the power current increases from zero to the confining one, the resistance value of 6 atm minimum to maximum increases. Thus, the control current of the triac 1 flows in the event of a decrease in the power current less than its current in the precise state, and its magnitude is such as to ensure that the triac 1 is kept in the on state even with an insufficient power current. 2 hp f-ly, 1 ill. (L

Description

The invention relates to a conversion technique and can be used as a converter ^; A or AC voltage switch.

The purpose of the invention is the expansion of functionality and reduction of control power.

The drawing shows a circuit diagram of the device.

The device for controlling the triac 1 contains a gate bridge, executed on diodes 2-5, a controlled resistance (MOS transistor) 6, the control terminals of the triac 1 are connected to the buses 7 and 8 of the control signal source through the diagonal of the alternating current of the diode bridge.

Anti-parallel connected LEDs 9 and 10 are included in the power circuit of the triac 1, the photothyristors 11 and 12 of which, according to the reference, are connected between the gate and the source of the transistor 6.

The device operates as follows.

In the absence of control voltage on buses 7 and 8 or its small value, the current of the control input of the triac is insufficient to turn it on. The current of the power circuit is small, therefore, the optical emitter 9 and 10 is not excited, its output signal is small. Resistance 6 in the absence of a control signal (optical) at its input is small.

When a control signal is received on buses 7 and 8, a control current flows through the control input of the triac, which is determined by the relatively low resistance 6 and the maximum value. Under the action of a control signal, the triac turns on and current flows through its power circuit. Depending on the magnitude of the flowing current, the intensity of the optical radiation of the optical emitter 9 and 10 changes (at one polarity, the LED 9 emits, at the opposite - LED 10). Depending on the instantaneous value of the current, the value of resistance 6 included in the diagonal of the direct current of the diode bridge also changes.

Moreover, with an increase in the instantaneous current from a zero value to a holding one, the value of resistance 6 increases from minimum to maximum, and vice versa.

Thus, the control current of the triac flows if the power current is less than the current of its holding in the on state, and its value is such that the triac is held in the on state (even if its load current is insufficient to hold).

Thus, the proposed device has advanced functionality, as it will automatically adjust the control current depending on the power current of the triac, which will also reduce the control power.

Claims (3)

Claim 1. A device for controlling a triac containing a valve bridge, one AC terminal of which is connected to a control signal source, and the other is intended for connecting to a triac control electrode, characterized in that, in order to expand the functionality and reduce the control power, a current sensor is introduced and controlled resistance included in the control circuit of the triac, and the terminals of the controlled resistance are connected to the DC terminals of the valve bridge, and the control input is connected nen with a current sensor designed to be included in the power circuit of the triac. 2. The device according to claim 1, characterized in that the controlled resistance is made in the form of an MIS transistor, the drain and source of which are the output and input of the controlled resistance, the substrate is connected to the source, and the gate is connected to the source, through the resistor is connected to the drain and is control input of controlled resistance. 3. The device according to claims 1 and 2, characterized in that the current sensor is made in the form of two oppositely-connected thyristor optocoupler LEDs, the photo-thyristors of which are connected in parallel between the gate and the source of the MOS transistor.