CS201765B1 - Connection of the pulse convertor - Google Patents

Description

CZECHOSLOVAKCASOCIALISTREPUBLIC (19) DESCRIPTION OF THE INVENTION CERTIFICATE 201765 (11) (Bl) (22) Registered 30 08 78 (21) (PV 5598-78) (51) Int. Cl.3 H 02 M 3/135 H 02 P 7/28 (40) Published 31 03 80 OFFICE AND DISCOVERY OFFICE (45) Issued 15 08 82 (75)

Author of the invention REJENT JAN ing., ČAPEK MILOSLAV ing., PRAHA and SOVA JlRl ing., KARLOVY VARY (54) Pulse converter connection

BACKGROUND OF THE INVENTION The present invention relates to a pulse converter circuit, particularly for high voltage applications. The output voltage of this pulse converter can be used to solder the traction vehicle auxiliaries, such as traction motors, auxiliary drives, and the like.

The hitherto known simplest forms of pulse converter connection for supplying traction vehicle auxiliary circuits from a DC network have several disadvantages: (a) a high transformation ratio of the input and output DC voltage levels, b) a large input current ripple that c) increasing the number of phases of the pulse converter, c) increasing the number of phases of the pulse converter results in a disproportionate increase in the number of semi-conductor valves, weight and volume pulse converter. All the above-mentioned disadvantages of removing the pulse converter according to the invention, the fact that the first-diode switch is connected to the positive-pole of the direct-current source, whose cathode, connected to the cathode of the first zero-diode, is connected to a load-carrying pole whose negative pole is connected to a second thyristor switch anode connected to the anode of the second null diode. The cathode of the second thyristor switch is coupled to the negative pole of the uniform source, and the anode of the first null diode and cathode of the second null diode are coupled to the middle point of the two filter capacitors connected to the screen and connected in parallel to a DC source. The advantage of integrating a pulse converter according to the invention is the possibility of a deep degree of output voltage controllability with a minimum of controlled valves by the simplest control method. The design, weight and volume are more favorable than known transducers. The inverter does not require particularly fast semiconductor elements and is suitable for smaller power and small pulse converter relative openings.

The pulse converter wiring according to the invention is illustrated in the accompanying drawing, wherein FIG. 1 is a schematic diagram of a pulse converter and FIG. 2 shows a circuit diagram of a pulse converter with a typical thyristor switch wiring example. Fig. 3 shows the waveforms of some pulse converter quantities.

The pulse transducer consists of an output filter capacitor formed from two capacitors connected to capacitors 1 and 2 (center condenser filter capacitor). The filtering capacitors 1 and 2 are connected to a uniform supply source 7. In parallel to the first filter capacitor 1, a first thyristor sensor 3 is connected, in 201765

Claims (1)

2 is connected in series with the opposite polarized first zero diode 5. In parallel to the second filter capacitor 2, a second thyristor switch 4 is connected in series with the opposite polarized second zero diode 6. A positive load pole 8 is connected to a common first thyristor the switch 3 and the first null diode 5 and the negative pole of the load 8 are connected to the common point of the second thyristor switch 4 and the second null diode 6. The first thyristor switch 3 in the diagram of FIG. and commutating chokes 3,4, connected in series with antiparallel thyristor 3.1 and diode 3.2. The second thyristor switch 4 is connected in the same way. The load pole 8 is connected between the cathode resistor 3.1 and the cathode of the first zero diode 5a the negative pole of the load 8 is connected between the anodutyristor 4.1 and the anode of the second zero diode 6. In FIG. there are drift and tension on vertical axes and time is drawn on horizontal axes. Curve 9 depicts the waveform of load 8, waveform 10 curve current and parallel thyristor 3.1 and diode 3.2. Curve 11 shows the waveform of the antiparameter The pulse converter wiring, consisting of at least two thyristor switches, null diodes and input filter capacitors, characterized in that a first thyristor switch (3) is connected to the positive pole of the DC source (7), the cathode connected to the lead of the first neutral diode (5) is connected to a loading pole the load (8), the negative pole of which is connected to the anode of the second thyristor parallel pair of thyristor 4.1 and the diode 4.2 curve 12 to the current flow through the first zero diode 5, and the curve 13 shows the current flow through the second zero diode 6. the finding is: the thyristor 3.1 of the first thyristor switch 3 is closed by the control pulse. a diode 5 to the thyristor 3.1 begins to oscillate the action, in the circuit a co-mutation capacitor 3.3 and a commutating choke 3,4. This produces a sinusoidal current pulse in the LC circuit, which is added to the load current 8 in the commutating choke 3.4 and the antiparallel pair of thyristor 3.1 and diode 3.2 - after the current in the first thyristor switch 3 is extinguished by the reverse of the commutation condenser 3 3 through the diode 3,2, the current load 8 again takes over the pair of zero diodes 5 and 6. The control pulse closes the thyristor 4.1 of the second thyristor of the switch 4, and the entire process proceeds completely in the same manner as before in the first switch 3. Turning off the pulse converter 1 at any time by blocking the control pulses of the two thyristor switches 3 and 4. EMERGENCY LEVER (4) connected to the anode of the zero diode (6), wherein the cathode of the second thyristor switch (4) is connected to the negative pole of the DC source (7) and the anode of the first null diode (5) and the cathode of the second null diode (6) are coupled to the midpoint of the two filtering capacitors (1, 2) connected to series and connected in parallel to DC source (7) · 3 drawings