SU936306A1 - Self-sustained voltage inverter - Google Patents

Description

(5) AUTONOMOUS VOLTAGE INVERTER

The invention relates to electrical engineering and can be used for any variant of a thyristor voltage inverter with single-phase and three-phase load. Autonomous voltage inverter circuits are known with galvanic separation of the main thyristors and a common switching node using a switching transformer. The invention is closest to the technical essence of the invention: three-phase autonomous voltage inverter circuits containing three-phase main thyristors and reverse diodes, as well as switching transformer having primary and secondary windings, the opposite ends of which form a common point and are connected to a positive input terminal, and the other ends s are respectively connected to the cathode bus Nogo one-phase bridge commutating thyristor and to the anode main bus-phase thyristor bridge. The ac diagonal of the indicated single-phase bridge includes a parallel-connected switching capacitor and a chain of two chokes and two metering thyristors, the cathodes of which form a common point and are connected to the negative input terminal. In each phase of the inverter between two points, one of which is formed by connecting the main thyristor to the anode group of the inverter with a reverse diode of the cathode group, and the second - connecting the main thyristor of the cathode group to the reverse diode of the anodic group, linear chokes with average outputs are connected to which the corresponding phase load. In this inverter circuit, the realization is the sequential switching of the main thyristors, which ensures their quick disconnection, and the same time, the rigidity of the output characteristic and the linearity of the regulating characteristic of the inverter. The disadvantage of the known inverter is the relative complexity of its circuit and unsatisfactory for large-scale cases of mass and size indicators. The purpose of the invention is to simplify the device while improving its weight and size parameters. The goal is achieved by the fact that the inverter containing three-phase bridges of the main thyristors and non-return valves connected through the secondary winding of the switching transformer to the positive input terminal connected to the primary winding of the specified transformer connects. wired to the switching valve. supply

Claims (3)

A diode shunting the secondary winding of the switching transformer connected to the primary winding of the ends of the same name, the latter being connected to the negative input terminal through a switching valve, which uses a two-step thyristor, and thyristors are used as non-return valves. FIG. Figure 1 shows the proprietary circuit of an autonomous voltage inverter in a three-phase bridge version; in fig. 2 - time diagrams explaining the operation of the device on the switching interval. The three-phase bridge inverter of FIG. 1 with main, 1-6 and inverse 7-12 thyristors operates on a three-phase load 13 and contains a switching transformer 14, the primary winding 15 of which is connected via a switching dual-operation first thyristor 16 to a negative input terminal, and the secondary winding 17 is bridged by a diode 18 The inverter works as follows. Let the primary thyristors 1, 3 and 5 be open at the initial time instant to. At time t. The switching process of the thyristor 1 begins. To turn off thyristor 1, unlocking control pulses are applied to thyristors 16 and 10. Turning on thyristor 16 provides voltage supply Units of the inverter power supply to the primary winding 15 of the switching transformer 14. On secondary volt-time t, the anode transition of the thyristor 1 restores blocking properties, after which the reverse the current in the thyristor 1 decreases, reaching the circuit 17, while the voltage K – f – E is induced, where K is the transformer transformer ratio. If the number of turns of the winding 17 is greater than the number of turns of the winding 15 /, then the thyristor 10 is under direct voltage IT (Kur-1) and is unlocked. A current begins to flow along the circuit 10-1-17-E-10, which is direct for thyristor 10 and reverse for thyristor 1. In the interval t - t, a rapid increase in current occurs, limited mainly by the small and inductances of the transformer urb windings. At the time ti, then the anode current in thyristor 1 P - IK reverses direction (Fig. 2c) and the load current of phase A Od switches to the reverse thyristor 10 completely. At the instant C, the reverse anode voltage is set at the thyristor 1 (Fig. 26), whose value is EJ (1). It is maintained until, at time t, a locking pulse of the control current is applied to the dual-operation thyristor 16. At time t /, the process of turning off along the control circuit of the thyristors 16 is completed, the direct anode voltage Ej is established on the thyristor 1 and the switching step is completed. An important advantage of the proposed inverter in a number of cases of its practical use is the possibility of locking at one switching stage any number (from one to) of the conducting main thyristors, whereas in the known inverter simultaneous locking of all is carried out simultaneously, which limits the possible algorithms for switching them and consequently, it reduces the possibilities of the inverter to form an output voltage curve and to regulate it with pulsed methods. In this case, the number of lockable main thyristors is determined by the inclusion of the corresponding thyristors from the numbers, which, besides the functions of non-return valves, also perform the functions of distribution thyristors, i.e. when turned on, the reverse anode voltage pulses are applied to those main thyristors that need to be locked at this stage of switching. For example, if you need to simultaneously turn off all the main thyristors 1, 3 and 5, then three thyristors 10 and 8 unlock, and if you need to turn off thyristors 1 and 5, then two reverse thyristors 10 and 8 will be unlocked. a voltage inverter containing three-phase main and return valve bridges connected through the secondary winding of a switching transformer to a positive input terminal connected to the Primary winding of the specified transformer connected to a switching valve, characterized in that In order to simplify while simultaneously improving mass and size parameters, it is equipped with a diode shunting the secondary winding of a switching transformer connected to the primary winding of the same ends, the latter being connected to the negative input terminal through a switching valve, which uses a two-step thyristor as a reverse valves used thyristors, History | 1Miki information taken into account during the examination 1. USSR author's certificate ff 57288, cl. H 02 M 7/515, 1975, 2. US patent number 5731b 5, cl. 1973. 3. USSR author's certificate for application No. 2912U3, cl. H 02 M 7/515, 17.0if.80. wi 17 I, L t: j 15 if f "Tf.f Ik a .one f ff-lS Mr. Q.g