SU880809A1 - Method of converting alternative-current energy to direct-current energy and apparatus for performing same - Google Patents

Description

A bridge rectifier is connected to a chain of controlled valves, the midpoint of which is connected to the midpoint of the secondary winding of the transformer and connected through a forced: switching unit: with one of the monitors of the motor circuit, a separate capacitor is connected in parallel with each secondary winding of the transformer.

Figure 1 shows a device diagram; Fig. 2 shows timing diagrams of webs in the valves of the device in the pull mode.

Consider the method of converting AC energy to DC energy, taking the operation of the device for its implementation shown in FIG. 1 as an example.

To the output terminals of the controlled bridge rectifier, whose shoulders 1-2 represent pulse thyristor switches with forced commutation, and shoulders 3-4 are made on thyristors, a chain of thyristors 5 and b is connected, the middle point of which is connected to the midpoint the secondary winding of the transformer 7, and the load circuit 8. The secondary winding of the transformer is divided into two half windings 9 and 10, parallel to each of which capacitors 11 and 12 are connected. A forced switching unit 13 is connected between the connection point of half windings 9 and 10 and one of the output terminals of the rectifier.

At the beginning of the positive half-period of the voltage, the load circuit 8 is not connected to the transformer 7, and the current of the motors is closed through the shoulders 1 and 3 of the rectifier. At time 1 (Fig. 2), the thyristor b is turned on, thereby the load circuit 8 is connected to the half winding 9 of the supply transformer 7. At the time, the secondary half winding 9 abruptly increases to a value of 0, and in the half winding 10 to a value equal to 0.5 Over, where over-current in the load circuit. In the primary winding, the current increases smoothly according to the cosine law. After a time TO / 2 equal to the half-period of the natural oscillations of the LC circuit, where L is the transformer inductance, C is equivalent to the input capacitance, is equal to TD1 i, the current in the transformer primary winding reaches the value of igr corresponding to the steady state of converter operation. At this time point (ia), the valve arm 4 is turned on and the load circuit is connected to the entire secondary winding of the transformer 7. At time ii, the current in the secondary half winding 9 abruptly decreases by 0.53, and in the half winding 10 increases by

magnitude. In the primary winding of the transformer, the current changes smoothly and no current surges are observed, which reduces the interfering effect on the communication lines. At time tj, the current in secondary semi-winding 9 decreases abruptly to a value of 0.53d, and in half-winding 10 increases to a value equal to 1,. In the primary winding, the current decreases smoothly according to the cosine law. After a time equal to TO / 2, the current in the primary winding decreases to the value of the constrained component. At this point in time (4 using the forced switching unit 13, the valve arm 5 is turned off and the load circuit is disconnected from the secondary winding of the transformer 7. The load current at time interval t4 - tx | closes through the shoulders 2 and 4 The negative halftime of the network is similar.

The device provides the possibility of operation of traction engines in the regenerative mode.

Claims (2)

1. A method of converting alternating current energy into direct current energy, preferably for alternating current electric rolling stock, comprising alternately connecting and disconnecting a load circuit to sections of the secondary winding of a power transformer, characterized in that, in order to improve the switching power of the converter, the economic performance of the electrically moving composition, as well as reducing the interfering effect on the communication lines, in each half-period of the supply voltage initially connect a load circuit At the moment when the primary winding of the transformer reaches a full load current, the load is connected to the entire secondary winding of the transformer, then in the second part of this half-period of the supply voltage, the load is disconnected from one of the semi-windings, and at the moment I when the current in the primary winding of the transformer as a result of the oscillatory process drops to the magnitude of the forced current, the entire 06MOTKV secondary transformer from the load circuit. 2. A device for implementing the method of claim 1 j comprising a power transformer, the secondary winding of which is divided into two equal magnetowired half windings, controls a valve bridge, the two arms of which are made with forced switching, the output of which includes traction motors, characterized in that A chain of controlled gates is connected to the output terminals of the controlled bridge rectifier, the middle point of which is connected to the middle point of the secondary winding of the transformer and connected through a forced switching unit with one of the terminals of the traction motor circuit, parallel to each of the secondary half windings of the transformer, a separate capacitor is connected. Sources of information taken into account in the examination 1, USSR Author's Certificate 515674, cl. In 60 L 1976. ti tf g t, g fig .