SU1117776A1 - Automatic power transfer device - Google Patents

Abstract

An AUTOMATIC SWITCHING DEVICE FOR POWER SUPPLIES, main and backup, containing a frequency control unit, a voltage control unit and a backup source switch control unit, characterized in that, in order to simplify the circuit and increase reliability, five triacs and two keys are inserted into it, and the frequency control and voltage control units are combined and made on the first resonant parametric converter built on the first U-shaped ferromagnetic core, on the middle rod of which The first modulation winding, connected via a key to the main power supply, on the extreme rods of the first core is located the first contour winding, in parallel with which the first capacitor is connected, three output windings, two of which are connected to the main power source by one ends and the other ends - to the control inputs of the first and second triacs, the power terminals of which are connected to the load and to the main power source, one third of the output winding is connected to the control terminal in one One third triac, and another through a diode to one of the third triac power leads connected to the input of the control unit by the backup source switch, made on the second resonant-parametric converter built on the second U-shaped ferromagnetic core, on the middle core of which is located the second modulation winding L of the second converter, connected via a key to the backup power supply buses, on the extreme rods of the second core is located the second contour winding, parallel The second capacitor, the output of which is the input of the control unit of the backup source switch, and two output windings, a fourth and a fifth, one ends of which are connected via a diode to a backup | The power supply source, others to the control inputs of the fourth and fifth simulator, the power outputs of which are connected to the load and to the backup power source, respectively.

Description

The invention relates to electrical engineering and is intended for use in electric power installations, in particular, in ships. Automatic power supply switching devices are known, comprising a voltage control unit, a frequency control unit and a switching unit 1. The closest to the invention in its technical essence is a device containing a frequency control unit built on an RC circuit and a trigger loaded with an electromechanical relay, block control voltage on the resistors of the circuit and the trigger, and ignition on the electromechanical relay, the output unit in the form of storage capacitors and electromagnetic relay 2. The disadvantages of the known device You are the relative complexity of the circuit and the lack of reliability. The purpose of the invention is to simplify the circuit and increase reliability. The goal is achieved by the fact that the device automatically switches power sources, primary and backup. containing a frequency control unit, a voltage control unit and a backup source switch control unit, five triacs and two keys are entered, and the frequency control and voltage control units are combined and made on the first resonant-parametric converter built on an U-shaped ferromagnetic core, On the middle core of which is located the first modulation winding, connected via a key to the main power source, on the extreme terminals of the first core is located the first. the contour winding, in parallel with which the first capacitor is connected, three output windings, two of which are connected to the main power source by one ends and to the main inputs of the first and second triacs, the power leads of which are connected to the load and to the main power source, the third output winding is connected at one end to the control input of the third triac, and the other through a diode to one of the power pins of the third triac connected to the input of the switch control unit in standby mode A source made on the second resonant parametric converter built on the second W-shaped ferromagnetic core, on the middle core of which is located the second modulation winding of the second converter connected via a key to the backup power source buses, the second contour winding is located on the extreme cores of the second core, parallel to which a second capacitor is connected, the output of which is the input of the switch control unit of the backup source, and two output windings, the fourth Fifth and fifth, one ends of which are connected via diodes to the backup power source, others to the control inputs of the fourth and fifth triacs, the power terminals of which are connected to the load and to the backup power source, respectively. The drawing shows a schematic diagram of the proposed device. The voltage and frequency control unit is built on resonant-parametric converter 1, the control unit of the backup source commutator - on resonant-parametric converter 2. The first converter controls the switch 3, the second switch 4. The main source is 5, the backup source, 6 . The main nodes of the transducers 1 and 2 are parametric oscillatory circuits, built on modulated inductances formed by loop, windings 7 and 8, and capacitors 9 and 10. These windings are located on the outermost rods of the H-shaped ferromagnetic cores 11 and 12. output windings 13-17 are connected to the control circuit of a low-power triac 18, blocking the circuit 8-10 of the converter 2. Moreover, the output windings 13-16 are connected by their ends to power sources, which are also connected cheny one triacs its power terminals in the switches 3 and 4, through the diodes. Output winding 17 is also one of its ends connected to the power output of the triac 18 through the diode. Diodes in this case are included to eliminate the reverse voltage at the control transistor of the triacs, thus facilitating their working conditions. On the middle core of cores 12, there are modulation windings 19 and 20 that are connected respectively to the main 5 and reserve 6 sources using keys 21 and 22, respectively. The modulation windings 19 and 20 create variable fields, the magnetizing cores, and periodically vary their magnetic permeabilities. As a result, the inductance of the loop windings 7 and 8 is modulated. The circuit also has a load 23. The device operates as follows. When the contacts 21 to 22 are closed, the modulation windings 19 and 20 are energized and conditions are created for exciting parametric oscillatory circuits. When the circuit 7-9 is excited, a transformer EMF appears in the windings 13 and 15, with which the triacs of the switch 3 are unlocked and the load 23 is connected to the buses of the main power source. At the same time, a signal is applied to the control electrostimistor 18. The latter opens, blocking the circuit 8-10 from the excitation. The signals in the windings 14 and 16 are missing and the switch 4 is closed.

When the voltage of the main source decreases (or disappears), the magnitude of the modulating field voltage and the modulation depth of the inductance of the winding 7 decrease. As a result, oscillations in the circuit break down; 7–9 and the signals in the windings 13, 15 and 17 disappear. disconnecting the load 22 (from tires 5. Simistor 18 closes at the same time. Circuit 8-10 is unlocked, resulting in parametric oscillations.

Signals appear in the windings 14 and 16 that enable the triacs of switch 4. The load 23 is connected to the busbars 6 of the backup power source. As the frequency of the main power supply decreases or increases beyond the setpoint, oscillations in circuit 7-9 disappear due to its frequency selectivity.

The construction of the proposed device for automatic switching of power sources on two resonant-parametric converters distinguishes it favorably from the known one, since it simplifies the circuit by combining two blocks in one and makes it cheaper. This increases reliability both by reducing the number of elements and by non-contact action.

Claims (1)

AUTOMATIC POWER SWITCHING DEVICE, main and backup, containing a frequency control unit, a voltage control unit and a control unit for a backup source switch, characterized in that, in order to simplify the circuit and increase reliability, five triacs and two keys are inserted into it, and control units frequency and voltage control are combined and performed on the first resonant-parameter converter built on the first Ш-shaped ferromagnetic core, on the middle rod of which is located the first I am a modulation winding connected via a key to the buses of the main power source, on the extreme rods of the first core there is a first loop winding, in parallel with which the first capacitor is connected, three output windings, two of which are connected at one end through diodes to the main power source, the other ends to the control inputs of the first and second triacs, the power terminals of which are connected to the load and to the main power source, the third output winding is connected at one end to the control input of the third about the triac, the other through a diode to one of the power terminals of the third triac connected to the input of the control unit of the switch of the backup source, made on the second resonant-parametric converter, built on the second Ш-shaped ferromagnetic _{with a} core, on the middle rod of which there is a second modulation winding of the second converter connected via a key to the buses of the backup power source, on the extreme rods of the second core there is a second loop q winding, parallel to which under the “second capacitor, the output of which is the input of the control unit of the switch of the backup source, and two output windings, the fourth and fifth, are connected, one ends of which are connected through the diodes to the backup power source, the other to the control inputs of the fourth and fifth triacs, the power leads of which are connected to load and backup power, respectively. >