SU1513598A1 - Self-excited bridge-type inverter - Google Patents

Abstract

The invention relates to electrical engineering and can be used in secondary power supply and automation systems. The purpose of the invention is to increase efficiency. The device contains four power transistors 1-4, connected by a bridge circuit. The saturating transformer 5 has four windings 8-11 positive feedbacks connected to the input circuits of the power transistors through the base resistors 12-15. To start the inverter, the starting resistors 23 and 25 are connected to the control circuit of two diagonal-located power transistors 1 and 4 through the closing contacts 24 and 26 of the starting relay 35. When the inverter is turned on, the output transistor 36 opens, the starting relay 35 is triggered through the starting resistors 23 and 25 connects the windings of the saturating transformer 5, providing self-excitation of the inverter. After starting under the action of the output voltage of the rectifier 27 by means of the optocoupler 33, the output transistor 36 is locked and the starting relay 35 is turned off. 1 il.

Description

The invention relates to electrical engineering and can be used in secondary power supply systems and automation.

The purpose of the invention is improving efficiency.

The drawing shows the proposed inverter.

A self-excited bridge inverter contains four power transistors 1-4, a saturable transformer 5 and an output transformer 6. A saturated transformer 5 with a primary winding 7 is connected to the bridge output, and four positive feedback windings 8-11 are connected to the base-emitter junctions of each power transistor 1- 4 through the limiting base resistors 12-15, respectively. A capacitor 16 is connected in parallel with the primary winding 7. The output transformer 6 is connected to the bridge output by the primary winding 17, and a resistor 22 is connected through the output rectifier 19 and the filter capacitor 20 to the load 21. Resistor 22 is connected in series with the primary winding 7 of the transformer 5. Two circuits are introduced. launch. The first trigger circuit, consisting of the resistor '23 and the relay 24 contact connected in series with it, shunts the base - collector transition of transistor 1 through the base resistor 12, The second trigger circuit, consisting of a resistor: 25 and relay contact 26, shunts the base - collector junction through base resistor 15 of transistor 4.

The control unit. Consists of a rectifier Y7, resistors 28-31, a capacitor 32, an optocoupler 33, a zener diode 34, a start relay 35 and an output transistor 36. A capacitive filter is connected in parallel with the input terminals of the optocoupler 33 through a limiting resistor 29, and a parallel through the limiting resistor 28 is connected the output of the rectifier 27, the input of which is connected to the output of the inverter. The output of the optocoupler 33 shunts a circuit consisting of a zener diode 34 and a resistor 31 connected in series with it. One output terminal of the optocoupler 33 connected to the zener diode 34 is connected to the relay coil 35 through the limiting resistor 30. Another output terminal of the optocoupler 33 is connected to the resistor 31 and the emitter of the transistor 36. The base of this transistor is connected between the resistor 31 and the zener diode 34, and the collector is connected to the other terminal of the relay coil 35.

The inverter operates as follows.

When a supply voltage is applied to the control unit, current begins to flow through the limiting resistor 30, the zener diode 34, the resistor 31, and the base – emitter junction of the transistor 36, causing it to open. When the transistor 36 is opened, the turnip 35 is triggered, which with its contacts 24 and 26 includes a start circuit, one of which consists of a resistor 23 and a relay contact 24, and the other of a resistor 25 and a relay contact 26. The current flowing through the starter circuits, the base resistors 12 and 15, causes the transistors 1 and 4 to open slightly. The current leading to the EMF in the windings 8-11 flows in the primary winding 7 of the transformer 5, thereby accelerating the process of opening the transistors 1 and 4 and closing the transistors 2 and 3. After saturation of the transformer, the EMF in the windings 8 · ^ II reverses its sign, causing the opening of transistors 2 and 3 and the closing of transistors 1 and 4. The process is repeated, and the source voltage is alternately applied to the primary winding 17 of transformer 6 ka, nutrition. The voltage removed from the secondary winding 18 through the diode bridge 19, the filter capacitor 20 is supplied to the load 21. At the same time, the alternating voltage supplied to the primary winding 17 of the transformer 6 is supplied to the input of the rectifier 27, the voltage from the output of the rectifier 27 through the resistor 28, the capacitor filter and the limiting resistor 29 is fed to the input of the optocoupler 33, causing it to open. By its output, the optocoupler 33 shunts the circuit consisting of a zener diode 34 and a resistor 31, thereby closing the transistor 36, which turns off the relay 35. Contacts 24 and 2.6 open, thereby disconnecting the two start circuits, which causes the inverter to operate symmetrically with low dynamic losses. If the oscillation fails, for some reason, the start-up process is repeated.

Claims (1)

Claim Self-excited bridge inverter _; containing four power transistors, a saturable transformer with four positive feedback windings, each of which is connected to the emitter of the corresponding power transistor by the first output, and to the base of this transistor through the base resistor, and two starting resistors connected respectively to the control circuits of two diagonally arranged power transistors, characterized in that, in order to increase the efficiency, a start relay is introduced with two make contacts, each of I, which is connected through a resistor between the second terminal of the positive feedback winding and the collector of the power transistor connected to it, and a control unit with an output transistor, through which 5 the coil of the starting relay is connected between the input terminals, and in the control unit of the starting relay, the emitter of the output transistor is connected to the second input terminal inverter, and the base through 10 series-connected zener diode and the first resistor is connected to the first input output of the inverter, and the zener diode and the input of the output transistor w are mounted by the output circuit of the optocoupler, the input circuit of which is connected through the rectifier to the output of the inverter.