SU1473046A1 - Self-contained voltage inverter - Google Patents

Abstract

The invention relates to the field of electrical engineering, in particular, to converter technology, and can be used in AC drive systems. The purpose of the invention is to increase and decrease the installed power of the switching equipment. The goal is achieved in that the autonomous voltage inverter is equipped with low-frequency diodes 29, 30, separation thyristors 13, 14, additional diodes 15, 16. The anodes of the anode of the inverter distribution thyristors 7-9, the cathode of separation thyristor 13 and the cathode of the additional diode 15 are combined. The connection point is connected to the beginning of the secondary winding 26 of the switching transformer 25. The end of the winding 26 is connected to the anode of the low-frequency diode 29. The cathode of the diode 29 is connected to the anode of separation thyristor 13, the cathode of the additional diode 16 and the positive bus of the inverter. The cathodes of the cathode group of distribution thyristors 10-12, the anode of the additional diode 16 and the anode of separation thyristor 14 are combined. The common point is connected to the end of the secondary winding 27 of the switching transformer 25. The beginning of the winding 27 is connected to the cathode of the low-frequency diode 30, the anode connected to the cathode of the separation thyristor 14, the anode of the additional diode 15 and the negative bus. The transformation ratio of the switching transformer 25 is selected to be less than one. 2 Il.

Description

The invention relates to electrical engineering, in particular, to converter technology, and may also be used in AC electric drive systems.

The purpose of the invention is to increase the reliability and reduce the installed capacity of the switching equipment.

In FIGS, the circuit diagram of the proposed device is shown; figure 2 - temporary

diagrams explaining his work on the switching interval.

The autonomous voltage inverter contains a three-phase main thyristor bridge 1-6, an anodic and a cathodic group of distribution thyristors 7-9 and 10-12, most often the points of which are connected through the first and second separating thyristors 13, 14 to the positive (+) and negative (- ) the inverter buses, and through the first and second additional diodes 15, 16, respectively, to the negative and positive inverter buses. The inverter includes a single-phase bridge of switching thyristors 17-20, in the diagonal of the alternating current of which is connected a switching circuit of capacitor 21 and throttle 22, and a diagonal of direct current is connected in series with the first low-frequency diode 23 of the primary winding 24 of the switching transformer 25 having two the secondary windings 26 and 27. The thyristors 17 and 18 are anodes connected to the positive bus of the inverter, and the switching thyristors V9, 20 cathodes to the anode of the secondary thyristor 28 connected by the cathode to the negative bus inverter. The beginning of one secondary winding 26 of the switching transformer 25 is connected to a common point formed by the cathodes of the first separation thyristor 13, the auxiliary diode 15 and the anodes of the distribution thyristors 7-9. The end of the secondary winding 26 is connected to the anode of the second low-frequency diode 29, the cathode connected to the positive bus of the inverter. The end of the other secondary winding 27 is connected to a common point formed by the anodes of the second separation thyristor 14 of the additional diode 16 and the cathodes of the thyristors 10-12.

0

five

0

five

0

five

0

five

0

five

The beginning of the secondary winding 27 is connected to the cathode of the third low-frequency diode 30, an anode connected to the negative bus of the inverter.

The inverter works as follows.

Suppose that at the initial moment t the main thyristors 1, 3 and 5 are open, and the capacitor 21 is fixed with a positive potential on the right plate. At the time C, the thyristors 17, 20 and 13 turn on. The capacitor 21 begins to recharge along the oscillating circuit 21-22-20-24-23-17-21 (fig.2a), and the current i flowing in the indicated loop i (fig.2b) causes the accumulation of charge of minority carriers in the base of the low-frequency diode: 23. This current is transformed into a closed loop 26-29-13-26 of the secondary winding 26 of the switching transformer 25 (figv), the accumulation of charge 0, (fig.2g) in anode low-frequency diode 29. At the time t, preceding the moment of completion of the recharging process of the capacitor 21, control impulses are supplied lsy to thyristors 7 and 28, which causes the switching diodes 23 and 29 from the forward direction to the reverse. As a result of accumulation of charge of minority carriers in the bases of low-frequency diodes 23 and 29, they have a high inverse conductivity for a certain period of time, the duration of which is proportional to the accumulated charge and can be regulated over a wide range by changing the interval (t - t,).

When the thyristor 28 is disconnected, the winding 24 of the transformer 25 through the first low-frequency diode 23 conducting in the opposite direction is connected to the inverter power supply E.I. At the same time, a voltage pulse with an amplitude of E, -K appears in the secondary winding. transformation, which can be selected significantly less than one. The voltage of the secondary winding 26 is supplied through the reverse conducting second low-frequency diode 29 to the first separation thyristor 13 and causes it to be locked. At the moment when the thyristor 13 is de-energized, the distribution thyristor 7 starts conducting the locking and the voltage of the secondary winding 26 of the transformer 25 goes to the main thyristor 1. As a result, the load current of phase A is transferred from the main thyristor 1 to the second low-frequency diode 29 (time t in FIG. .2c), the main thyristor 1 de-energizes (moment t in fig. 2b) and restores the locking properties.,

The process of turning off the main I and separation 13 of the thyristors continues until time t (Fig. 2, e and e), when in the diode 29 the phase of dissolution of non-major carriers ends and the stage of restoring the reverse resistance begins. From the time ty on the indicated thyristors, the direct anodic voltage rises to the value of Ej with a limited speed due to the inertia of the process of restoring the reverse resistance of low-frequency diodes (interval t - t, Fig. 2c). Reagent

at about.

nt the load current of phase A passes from the second low-frequency diode 29 to

the first additional diode 15. When this current passes through zero, the thyristor 7 is turned off by c.

Simultaneously with the process of turning off the thyristors 1 and 13, when the thyristor 28 is unlocked, the process of charging the capacitor 21 along the circuit 21-22-20-28-EJ-17-21 begins. At time tj, the current i., 0 (Fig. 26) and the thyristors 17, 20 and 28 are turned off, after which the next main inverter thyristor can switch.

The next switching cycle for locking the next main thyristor, for example, 5, switches on the switching thyristors 18, 19 and the separation thyristor 14, and then, after a delay time t, gd t - t, required to accumulate charges in the low-frequency diodes 30 and 23, unlock the thyristor 28 and the corresponding distribution thyristor 11.

Yu

t5 20 25

thirty

35 0

five

0

Claims (1)

Invention Formula Autonomous voltage inverter j containing a three-phase main thyristor bridge, anodic and cathodic groups of distribution thyristors, a switching transformer, two secondary windings of which are connected to two fundamental thyristors of the inverter phase, a single-phase switching bridge thyristors with an LC-chain in the diagonal of an alternating current and a primary winding of the switching transformer connected in series with the first low-frequency diode to the diagonal of the direct current of a single-phase bridge, the anodic group of thyristors with a inverter bus with a positive inverter bus for connecting a power source, and a cathode bus with a negative bus through a triac thyristor, characterized in that, in order to increase reliability and reduce the installed power of the switching equipment, it is equipped with second and third low-frequency diodes, two separate thyristors and two additional diodes, anodes of the anode group of distribution thyristors, the cathodes of the first separation thyristor and the first additional diode are combined and connected to the beginning one secondary winding of a switching transformer connected by an end to the anode of the second low-frequency diode, the cathode connected to the anode of the first separating thyristor, the cathode of the second additional diode and the positive thyristor, the cathodes of the cathodic group of the thyristor and the second additional diode are combined and connected by the end of the other secondary winding of the switching transformer connected to the cathode of the third low-frequency diode, the anode is connected The second split thyristor, anode of the first additional diode and a negative busbar is coupled to the cathode, and the transformation ratio of the switching transformer is less than one.  - firf- KRG Fi.2