SU1012406A1 - Frequency converter - Google Patents

Description

f1 The invention relates to converter technology, is intended to irreversibly convert the electrical energy of an industrial network into alternating current energy of increased frequency and can be used as a power source for induction heating of metals and ultrasonic technology apparatus. High-frequency converters are known in which two valve bridges are connected in series and in parallel by them are two filter capacitors that are powered through a filter choke from a bridge rectifier connected to a three-phase network with zero. In these circuits, the load point is connected via a choke network zero, which ensures the same distribution of stresses across the bridges with a sharp change in the load of CO- However, in emergency conditions associated with the inversion failure in one of the bridges, A double overvoltage occurs, and this leads to the failure of the valves in this bridge. Closest to the present invention is a converter comprising two bridges connected to the power source through filter chokes, connected in series through switching chokes, two filter capacitors connected in series, shunting valve bridges, and diodes, two of which are connected in parallel to each bridge and both switching throttles and the other two are parallel to each filter capacitor and load. The circuit ensures that the inverter operates from idle to short circuit load. ki, but with a sudden change in load, it is possible to redistribute the voltage of the power source through the filter capacitors, as a result of which the valves of one of the bridges will operate under high voltage, and this can lead to their destruction. The purpose of the invention is to expand the range of permissible loads, as well as increase the output power when powered from a three-phase network with zero. The goal is achieved by the fact that a frequency converter containing a rectifier connected to the power source 6, to the DC terminals of which two filter cables are connected through the filter rods: the bridge bridges with switching capacitors and droplets in the diagonal AC currents and two filter capacitors connected in series, connected to a common point by switching their chokes, made with taps connected via counter diodes to the corresponding ohm chambers connecting capacitors with filter throttles, each bridge, together with two commutating throttles, is shunted by a reverse diode, and two additional diodes connected to the load circuit are equipped with an additional choke, a three-winding output transformer, the secondary winding of which is connected to the load, and each of the two primary windings connected between the positive terminal of series-connected filter capacitors and the anode group of bridge gates, as well as between the negative terminal m of the capacitors and the cathode of another group of valves, the bridge is provided with a booster windings, shunt via an additional sootvetstvuyui1y diode bridge and connected in series with the commutating reactor, and the point com- total. mutant chokes connected to the common point of the capacitors of the filter connected to zero three-phase network through an additional choke. The drawing shows a diagram of the frequency converter. . The frequency converter contains thyristors 1-6 rectifier, filter chokes 7 and 8 and inverter thyristors, the bridges of which are connected via switching chokes 17 and 18, switching diameters 19 and 20 and capacitors 21 and 22 are connected to the diagonal bridges through primary windings 23 and 2 of the output transformer and filter chokes 7 and 8 to the DC outputs of the rectifier, filter capacitors 25 and 26, reverse diodes 27 and 28, the secondary winding of the transformer with a load connected to it 29, additional choke 3flj, connected to the mains supply zero, additional diodes 31 and 32, connected between the midpoint of the capacitors of the filter 25 and .6, the commutating chokes 17 and 18 and the outputs of the primary windings 23 and 2 of the output transformer, counter-diodes 3.J and 3 connecting the positive side of the filter capacitor 25 with the tap of the commutating choke 1 and the negative capacitor 26 with the tap of the choke 18 18. The circuit works as follows. When thyristors 1-6 are turned on, rectifier charges filter capacitors 25 and 2b through filter chokes 7 and 8, then turn on thyristors 9 and 12 of one inverter bridge: current flows through the circuit: capacitor 25 - winding 23 - thyristor 9 choke 19 - capacitor 22 - thyristor T2 - choke 17 - capacitor 25 and forms a sinusoidal current pulse in the primary winding 23 of the output transformer and, therefore, in the load 29 during the half period of the natural frequency of the switching circuit. By alternately unlocking the thyristors 13, 16, 10, 11, 14, and 15, the current flows along circuits similar to that described above, with two periods of the output frequency being generated in the load. If the equivalent load resistance is low, i.e. the voltage at the inverter elements increases and, for example, at the tap of the droplets 17 exceeds the voltage of the filter capacitor 25, the diode 32 opens and the current begins to flow along the circuit: choke 17 - diode 3 g capacitor 25 choke 17, Thus, the voltage on the tap, the throttles 17. are rigidly limited, therefore, the rate of increase of the eye flowing through the commutating choke 17 and its amplitude are also limited. If the voltage across the choke 17 exceeds the voltage across the winding 2k and the filter capacitor .6, then the diode 28 is turned off and the recovery current of excessive electrical energy 1U64 switching chokes in the power supply is closed along the circuit: choke 17 - capacitor 7.6 - winding 2k diode 28 - choke 17. The buildup of the voltage on the elements of the other bridge is limited along a similar circuit. As the equivalent load resistance increases, the voltage on the primary windings 23 and 2 of the output transformer can reach and exceed the voltage on capacitors 25 and 26. In this case, the diodes 31 and 3 are unlocked and the current flows through the circuits, respectively: winding 28 is a diode 25 32 - winding 23 and winding 2.k..diode 31 - capacitor 26 - winding. 2. In the proposed scheme, when the equivalent load resistance decreases, the electromagnetic energy of the commutating chokes is recovered into the power source, i.e. the buildup of the voltage on the bridge elements occurs. The circuit allows to limit the rate of current rise through the commutating chokes,. and, consequently, its amplitude, as a result of which overvoltage on bridge elements is reduced; such protection of circuit elements from overvoltage is a reliable research institute. In contrast to the known proposed scheme, a front discharge is used, which limits the buildup of voltage on the bridge elements, therefore, it is possible to obtain higher power at the output of the converter. With an increase in the equivalent load resistance, the circuit maintains the voltage on each primary winding of the output transformer at a level equal to the voltage on one filter capacitor, as a result of which the recovery time of the bridge valve controllability is maintained and the converter reliably operates at idle.

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Claims (1)

A FREQUENCY CONVERTER, comprising a rectifier connected to a power source, to the DC terminals of which, through filter reactors, two valve bridges connected in series through switching reactors with switching capacitors and reactors in alternating current diagonals and two filter capacitors connected in series, connected to a common point of switching reactors, made with solders connected through counter diodes to the corresponding connection points of the filter capacitors and with filter chokes, each bridge together with two commutating chokes shunted by a reverse diode, as well as two additional diodes connected to the load circuit, with the exception of the fact that, in order to expand range to allowable loads and increase output power when powered from a three-phase network with zero, it is equipped with an additional inductor, a three-winding output transformer, the secondary winding of which is connected to the load, and each of the two primary windings connected between the positive terminal of the last of the connected filter capacitors and the anode group of the bridge valves, as well as between the negative clamp of the same capacitors and the cathode group of valves of the other bridge, is equipped with voltage boost coils, shunting the corresponding bridge and a switching choke connected to it in series, the common point of switching chokes connected to the common point of the filter capacitors, connected to zero three-phase network through an additional inductor .. 90Sh01 1 1012406