SU1279035A1 - Self-excited inverter - Google Patents

Abstract

The invention relates to electrical engineering and can be used to power induction motors from a direct current source. The purpose of the invention is to increase reliability. The device contains a bridge of thyristors 1-6, a forced switching node (CPC) 10, consisting of a bridge distribution diodes 11-16, auxiliary thyristors 17, 18, chokes 19, 20, switching capacitors 21, 22, and shunt valves 23, 24 auxiliary thyristors 17, 18. In the UPC 10, the charge of the switching capacitors 21 and 22 is carried out immediately after connecting the power source, which eliminates the need to use a special start algorithm, simplifies the inverter :; and increases the reliability of his work. Auxiliary thyristors 17 and 18 are bridged by valves 23 and 24 (L provides an almost constant time to recharge capacitors, independent of the load current, which expands the control range in frequency and load current. 1 ill. O; o

Description

1-1279035

The invention relates to an electron cell of 21 other decks, which are generally co-opted with a C of the C of the type B, and fa on 7, and the same with gigi

technology, and more specifically to autonomous inverters designed to convert direct current to alternating current, and can be used to power induction motors from a direct current source.

The aim of the invention is to increase reliability by eliminating the need to use a special start algorithm.

The drawing shows a circuit of an autonomous inverter.

The autonomous inverter contains a thyristor bridge 1-6 connected through filter chokes 7 and 8 to the pole and minus terminals of the power supply. A load 9 is connected to the output pins. The forced switching node 10 consists of a bridge distribution diodes 11-16, the output pins of which are connected to the output pins of the bridge of thyristors 1-6, auxiliary thyristors 17-18 with serially connected drop switches 19-20 between the anodes of thyristors 1, 3, and 5, and diodes 11, 13, and 15, and cathodes of thyristors 2, 4, and 6, and diodes 12, 14, and 16, respectively, to switching capacitors 21 and 22, connected in parallel to the auxiliary thyristors together with the throttles. Parallel to the thyristors 17 and 18, the valves 23 and 24 are switched on, which shunt them in the opposite direction. Diodes can be used as gates 23 and 24, as shown in the drawing, or thyristors.

When the inverter is connected to a power source through chokes -7 and 8, the bridge distribution diodes 11-16 cause a charge on the capacitors 21 and 22 with the polarity indicated on the drawing. When you turn on two-core

thyristors, for example, 1 and 4 in the load current begins to flow through the circuit: positive output of the power source, choke 7, thyristor 1, load phases A and B, thyristor 4, choke 8, negative lead of the power source. To transfer current from phase A to phase C, a thyristor 17 is switched on. Pre-charged capacitor 21 is recharged along the thyristor 17 circuit, choke 19, capacitor 21 and, when the polarity changes on the capacitor backpoints, reversely applies to the thyristor 1 through diode 11

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voltage that causes it to turn off. In this case, the load current is closed along the circuit of choke 7, capacitor 21, diode 11, phases A and B, thyristor 4, choke 8, and power supply. The capacitor 21 is discharged by the load current, simultaneously across the circuit choke 19, valve 23, capacitor 21 oscillatingly discharging the capacitor, which causes the thyristor 17 to turn off. After a delay of the time required to restore the blocking properties of the thyristor 1 and charge the capacitor 21 to the voltage from uk-. bathroom in the drawing polarity, include the thyristor 5. In this case, the current in phase C begins to increase, and in phase A - to subside. When the current of phase C reaches a value equal to the value of the current of phase B, the current in phase A decreases to zero, and the current switching process in phase A of the load ends there. The load current is closed along a choke 7, a thyristor 5, a load phase C and B, a choke 8, a power source. The capacitor 21 is charged with the polarity indicated in the drawing. Turning off the thyristor 4 occurs in a similar way when turning on the auxiliary thyristor 18. As a result of the periodic switching on and off of the thyristors 1-6, an alternating current is formed in the load.

Essential in the device is that the charge of capacitors 21 and 22 is carried out immediately after connecting the power source, which eliminates the need to use a special start-up algorithm, simplifies the inverter, and increases its reliability, while reducing by one-third the number of capacitors and reducing installed capacity of capacitor equipment. The shunting of the auxiliary thyristors 17 and 18 with additional valves 23 and 24 ensures an almost constant recharging time for capacitors, independent of the load current, which expands the control range in terms of frequency and load current.

Claims (1)

1-12 The invention relates to electrical engineering, and more specifically to autonomous inverters designed to convert direct current to alternating current, and can be used to power an asynchronous electric motor from a direct current source. The aim of the invention is to increase reliability by eliminating the need to use a special start algorithm. The drawing shows a circuit of an autonomous inverter. The autonomous inverter contains a thyristor bridge 1-6 connected through filter chokes 7 and 8 to the pole and minus terminals of the power supply. A load 9 is connected to the output pins. The forced switching node 10 consists of a distribution diode bridge 11-16, the output pins of which are connected to the output pins of the bridge thyristors 1-6, auxiliary thyristors 17-18 with successively connected droplets 19-20, connected between the anodes of thyristors 1, 3, and 5, and diodes 11, 13, and 15, and cathodes of thyristors 2, 4, and 6, and diodes 12, 14, and 16, respectively, of switching capacitors 21 and 22 connected in parallel to the auxiliary thyristors together with the throttles. Parallel to the thyristors 17 and 18, the valves 23 and 24 are switched on, which shunt them in the opposite direction. Diodes can be used as gates 23 and 24, as shown in the drawing, or thyristors. When the inverter is connected to a power source through chokes -7 and 8, the bridge distribution diodes 11-16 cause a charge on the capacitors 21 and 22 with the polarity indicated on the drawing. When two-main thyristors are turned on, for example, 1 and 4, a current begins to flow through the circuit: the positive output of the power source, the choke 7, the thyristor 1, the load A and B phases, the thyristor 4, the choke 8, the negative lead of the power source. To transfer the current from phase A to phase C, a thyristor 17 is switched on. A pre-charged capacitor 21 recharges the thyristor 17, the choke 19, the capacitor 21 and when the polarity changes on the voltage of the capacitor opposite to the thyristor 1, diode 11 applies reverse voltage causing it to turn off. In this case, the load current is closed along the circuit of choke 7, capacitor 21, diode 11, phases A and B, thyristor 4, choke 8, and power supply. The capacitor 21 is discharged by the load current, simultaneously across the circuit choke 19, valve 23, capacitor 21 oscillatingly discharging the capacitor, which causes the thyristor 17 to turn off. After a delay of time required to restore the blocking properties of the thyristor 1 and charge the capacitor 21 to from uk-. the bathroom in the drawing is polar, turn on the thyristor 5. At the same time, the current in phase C begins to increase, and in phase A it decreases. When the current of phase C reaches a value equal to the value of the current of phase B, the current in phase A decreases to zero, and the current switching process in phase A of the load ends there. The load current is closed along a choke 7, a thyristor 5, a load phase C and B, a choke 8, a power source. The capacitor 21 is charged with the polarity indicated in the drawing. Turning off the thyristor 4 occurs in a similar way when turning on the auxiliary thyristor 18. As a result of the periodic switching on and off of the thyristors 1-6, an alternating current is formed in the load. Essential in the device is that the charge of capacitors 21 and 22 is carried out immediately after connecting the power source, which eliminates the need to use a special start-up algorithm, simplifies the inverter, and increases its reliability, while reducing by one-third the number of capacitors and reducing installed capacity of capacitor equipment. The shunting of the auxiliary thyristors 17 and 18 with additional valves 23 and 24 ensures an almost constant recharging time for capacitors, independent of the load current, which expands the control range in terms of frequency and load current. Claims of the invention A stand-alone inverter containing connected to the input terminals via. filter chokes three-phase bridge ti-resistor, the AC output of which is connected to the output of the,. The anode group of the bridge is connected to the anode of the first auxiliary thyristor, and the cathode to the cathode of the second auxiliary thyristor, as well as switching capacitors and a three-phase distribution diode bridge, differing in that. that, in order to increase reliability by eliminating the need to use a special algorithm. start-up, it is equipped with two non-return valves shunting auxiliary thyristors and two throttle switches included, first, with the anode group of the distribution diode bridge and the cathode of the first auxiliary thyristor, and the second between the cathode group of the specified bridge and: the anode of the second auxiliary thyristor The AC pins of the same bridge are connected to the vy-. the ac waters of the thyristor bridge, and the auxiliary thyristors together with the throttles are shunted by switching capacitors.