RU2732193C2 - Three-phase alternating voltage converter (embodiments) - Google Patents

Abstract

FIELD: electrical equipment.SUBSTANCE: invention relates to electrical engineering and can be used for conversion of three-phase alternating voltage to 12-pulse rectified or three-phase alternating voltage with high-quality harmonic composition. First embodiment of the three-phase alternating voltage converter comprises a three-phase transformer with a secondary winding connected in a triangle, primary phase windings connected by the first group of terminal leads to the phase input terminals, each pair of intermediate leads to input and output terminals of one of main group of two-terminal network with parallel-connected valves and main windings of equalization reactor (Er), and second group of extreme leads - to group of additional valves, connected in pairs to outputs of primary phase windings by unlike electrodes and forming by free electrodes output leads of three-phase gate bridge, to output terminals of which are connected in parallel two connecting circuits, the first of which is made in form of smoothing reactor or/and additional load, and second - in form of two series-connected additional two-terminal devices, each with series-connected diode and said additional winding Er,common point of additional two-terminal devices is connected to extreme terminal of transformer winding connected to open “triangle”, the other extreme terminal of which is connected to zero input terminal,and additional valves and diodes of additional two-terminal networks form three-phase valve bridge arms. Second embodiment of the converter differs from the first one in that the first connecting circuit contains additional winding Er, and the second one - two additional diodes the common point of which is connected to the zero input terminal through the transformer connected to open "triangle". Third embodiment of the converter differs by the fact that the main valves form the arms of the three-phase valve bridge, and to its output the main winding Er is connected. Current and voltage shape is constant and does not depend on control angle. In the mode of intermittent currents, it is not deformed. Third embodiment is simpler than the others.EFFECT: technical result achieved in all embodiments of the device consists in improvement of power factor to its constant value, including, due to the effect of inverse diode, in the mode of intermittent currents.7 cl, 5 dwg

Description

The invention relates to electrical engineering and can be used to convert a three-phase alternating voltage into a 12-pulse rectified or three-phase alternating voltage with a high-quality harmonic composition.

All the analogs below are analogs for all variants of the proposed converter.

A three-phase AC voltage converter is known, the second version of which contains a three-phase transformer, the secondary windings of which are connected in a "triangle" and connected to the load, for example, according to the rectifier circuit, the primary phase windings are connected by one group of terminals to the phase input terminals and to the phase-to-phase current distributor, and another group of terminals - to the input terminals of a three-phase controlled valve bridge, each common terminal of which is connected to the extreme terminal of the winding of one of the two equalizing reactors, the other extreme terminals of which are connected to the first pair of opposite electrodes of the controlled valves, and the common terminal of the second pair of their opposite electrodes to the zero input terminal of the phase-to-phase current distributor, the intermediate terminals of the equalizing reactor windings are connected to each other, for example, through the winding of the smoothing reactor, and the number of turns of each of them is divided in the ratio 1: √3, counted from the zero input terminal (patent No. 2392728 from 17.09.2008).

The disadvantage of this converter is the need for two equalizing reactors. Three windings of two URs participate in the formation of voltage ripple, the function of one of the two (in the discreteness interval in which it is not balanced in ampere turns), closing the output terminals of the controlled bridge, consists in the smoothing procedure, which uselessly increases the inductive resistance, lowers the rectified voltage and increases power loss. However, one of the essential functions of these two windings is that they prevent the controlled bridge and the free-wheeling diodes from shunting apart from each other.

The totality of the reasons that prevent obtaining the required technical result consists in choosing a more complex concept of constructing a converter, while striving for its simpler design, in order to obtain a high-quality harmonic composition of currents and voltages.

The closest (prototype) to the proposed technical solution is a three-phase AC voltage converter, the first version of which contains zero and phase input terminals, a three-phase transformer with secondary phase windings connected to the output terminals, for example, according to the rectifier circuit, primary phase windings connected by intermediate terminals and one group of extreme terminals to the terminals, respectively, of the first and second groups of two-terminal devices, each with an anti-parallel connection of the controlled valves and two of the 12 windings of the equalizing reactor, the output terminals of the second group of two-terminal devices are connected to the extreme terminal additionally introduced and connected into an open "triangle" the windings of the mentioned three-phase transformer, the other end terminal of which is connected to the zero input terminal, while the windings of the equalizing reactor in different groups of two-terminal networks are connected to the same-name electrodes of the controlled valves with opposite terminals.

The second version of the prototype differs from the first in that it contains an equalizing reactor with 8 windings, one of which is connected to the common point of the anodes, and the other to the cathodes of the controlled valves, the free electrodes of which are connected to the extreme terminals of the primary phase windings, and the common point of these two windings are connected to the extreme terminal of the winding, connected in an open "triangle".

Both options may contain an interphase current distributor made on an additional three-phase transformer, the phase windings of which are connected by one terminals and a common point of the other terminals, respectively, to the phase and zero input terminals (application for invention No. 2020103506 of 01/27/2020, Bul. No. 11 of 20.04. 2020).

The disadvantage of this converter is that the operation of the converter in the region of the intermittent current mode requires a qualitative improvement, since the shape of the rectified voltage in this area may differ from its shape in the area of the continuous current mode. This can lead to some increase in the amplitudes of higher harmonics in the region of the intermittent current regime.

The set of reasons that prevent the desired technical result from being obtained is that in the region of the intermittent current mode, the zero-sequence current energy alone may not be sufficient for the constancy of the indicated form.

The problem to be solved by the proposed technical solution is to improve the quality of the harmonic composition of the consumed current, including in the field of intermittent currents.

This problem in the first version of the proposed device is solved by the fact that the three-phase AC voltage converter contains zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected to an open "triangle", the first end terminal of which is connected to a zero input terminal, with secondary phase windings connected to the output terminals with the main load, for example, according to the rectifier circuit, the primary phase windings connected by the first group of extreme terminals to the phase input terminals, each pair of intermediate terminals to the input and output terminals of one of the main group of two-terminal networks with counter-parallel controlled valves and the main windings of the equalizing reactor, and the second group of extreme terminals - to the group of additional controlled valves, connected in pairs to the terminals of the primary phase windings with opposite electrodes and forming the output terminals of the three-phase valve bridge with the possibility of connecting them to the terminals of the additional windings of the equalizing reactor, to the output terminals of the three-phase valve bridge, two connecting circuits are connected in parallel, the first of which is made in the form of a smoothing reactor or / and a load, and the second is in the form of two additional two-terminal devices connected in series, each with connected in series by a diode and the mentioned additional winding of the equalizing reactor, the common point of the additional two-terminal networks is connected to the second extreme terminal of the windings of the said open "triangle", while the windings in the additional two-terminal networks relative to the windings in the main group of two-terminal networks are connected to the same electrodes of the controlled valves with opposite terminals, and additional controlled gates and diodes of additional two-terminal networks form the arms of a three-phase valve bridge.

In the second version of the proposed device, this problem is solved by the fact that the three-phase AC voltage converter contains zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected in an open "triangle", the first end terminal of which is connected to a zero input terminal, with secondary phase windings connected to the output terminals, for example, according to the rectifier circuit, by the primary phase windings connected by the first group of extreme terminals to the phase input terminals, by each pair of intermediate terminals to the input and output terminals of one of the two-terminal group with counter-parallel controlled valves and the main windings of the equalizing reactor , and the second group of extreme terminals - to a group of additional controlled valves connected in pairs to the terminals of the primary phase windings with opposite electrodes and forming the output terminals of the three-phase valve bridge connected to the terminal by free electrodes an additional winding of the equalizing reactor, two connecting circuits are connected in parallel to the output terminals of the three-phase valve bridge, the first of which is made in the form of the mentioned additional winding of the equalizing reactor, and the second is in the form of two diodes connected in series, the common point of opposite electrodes of which is connected to the second extreme terminal windings of the said open "triangle", wherein said additional and main windings of the equalizing reactor are connected to the same electrodes of the controlled valves with opposite terminals, and additional controlled valves and diodes of the second connecting circuit form the arms of a three-phase valve bridge.

In the third version of the proposed device, this problem is solved by the fact that in a three-phase AC voltage converter containing zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected to an open "triangle", the first end terminal of which is connected to a zero input terminal, with secondary phase windings connected to the output terminals, for example, according to the rectifier circuit, primary phase windings connected by the first group of extreme terminals to the phase input terminals, intermediate terminals to the main controlled valves connected in pairs by opposite electrodes, by the second group of extreme terminals to the pairwise connected opposite electrodes by additional controlled valves forming free electrodes the output terminals of the additional three-phase valve bridge connected to the output of the additional winding of the equalizing reactor, free electrodes of the main controlled valves form the output terminals of the main a separate three-phase valve bridge connected to the output of the main winding of the equalizing reactor, to the output terminals of the additional three-phase valve bridge are connected in parallel to the additional winding of the equalizing reactor two diodes connected in series, their common point of opposite electrodes is connected to the second extreme terminal of the winding of the said open "triangle", when In this case, the main and additional windings of the equalizing reactor are connected to the same-name electrodes of the controlled valves with opposite leads, and the additional controlled valves, together with the diodes, form the arms of an additional three-phase valve bridge.

In the first embodiment, in the first connecting circuit, the smoothing reactor and the load (the load is not shown in the drawing) must be connected in series.

In all versions, the converter can contain an interphase current distributor made on an additional three-phase transformer, the phase windings of which are connected by one terminals and a common point of the other terminals to the phase and zero input terminals, respectively.

The technical result achieved in all variants of the proposed device consists in improving the quality of the harmonic composition of the consumed current and output voltage, including in the region of the intermittent current mode, due to the effect of the reverse (shunt) diode. In the area of the intermittent current mode, the power factor improves to a constant value, since the shape of the current and voltage, due to the effect of the inverse diode, is even more constant and also does not depend on the control angle. The ripple shape in this mode is not deformed. The decrease in power losses remains, because in each discreteness interval, only two windings of only one equalizing reactor, balanced by ampere turns, are involved in the formation of rectified voltage ripple. The difference between turning on the reverse diode on the primary side and turning it on on the secondary side is in its effect through the equalizing reactor (UR) on the magnetic flux of the transformer.

The technical result, achieved in the second version of the proposed, is to simplify by combining the functions of the smoothing reactor and one additional winding Ur, while excluding the other from the circuit. In the third variant, the number of Ur windings is reduced to two.

FIG. 1 shows a schematic diagram of the first version of the converter of three-phase AC voltage to DC, 12-pulse voltage; in fig. 2 is a vector diagram of the converter voltages, where U _ab and U _0a are, respectively, the vectors of the line and phase voltages of the supply network, and on the closing vector, arrows show the vectors of equalizing voltages (with a dividing point "x") on the windings of the reactors, U _r is the vector of the resulting (rectified) voltage; in fig. 3 - timing diagrams of currents I ₀ , I _w0 , I _wA , I _{A (MPT)} (shown in the diagrams) and rectified voltage U _da ; in fig. 4 is a schematic diagram of the second version of the converter of three-phase alternating voltage to direct 12-pulse voltage; in fig. 5 is a schematic diagram of the third version of the converter of three-phase alternating voltage to direct 12-pulse voltage.

The converter (Fig. 1) contains a three-phase transformer 1 and Ur 2. Transformer 1 contains the primary phase windings 3, 4, 5, 6, 7, 8, a group of opposite leads of which is connected in pairs and forms intermediate leads 9, 10, 11 of these windings, and their free terminals are connected to the phase input terminals A, B, C, the secondary phase windings 12, 13, 14, connected in a "delta" and additional phase windings 15, 16, 17, connected in an open "delta". The converter also contains controlled valves on thyristors 18-29 (hereinafter referred to as valves everywhere), an interphase current distributor (MRT) on a three-phase transformer 30, the winding of which is connected to a "star", the beginning of which is connected to the phase input terminals A, B, C, and the generatrix of the zero input terminal 0 is the common point of the ends - to the end of the winding 17, the rectifier bridge on diodes 31 - 36, to the output terminals 37, 38 of which the load 39 is connected, and to the input terminals - the ends of the windings 12, 13, 14, Ur with windings 40 - 47, diodes 48, 49 and smoothing reactor 50. The ends (beginning) of the windings 40, 42, 44 (41, 43, 45) are connected respectively to the anodes (cathodes) of the valves 20, 24, 28 (21, 25, 29) ... The valve cathode 18 (22) [26] and the valve anode 19 (23) [27] are connected to the end of the winding 6 (7) [8]. Common points of opposite terminals of windings 40, 41 (42, 43) [44, 45] are connected, respectively, to intermediate terminals 10, 11, 9. Common points of opposite electrodes of valves 20, 21 (24, 25) [28, 29] are connected respectively to intermediate terminals 9, 10, 11. Smoothing reactor 50 is connected between the common point of the anodes of the valves 18, 22, 26 and the common point of the cathodes of the valves 19, 23, 27. The beginning (end) of the winding 46 (47) is connected to the common point of the cathodes (anodes ) of valves 19, 23, 27 (18, 22, 26). The end (beginning) of the winding 46 (47) is connected to the cathode (anode) of the diode 48 (49). The common point of the free dissimilar electrodes of the diodes 48,49 is connected to the beginning of the winding 15. In each pair, consisting of a valve and a winding Ur, the order of their serial connection with each other is indifferent.

The number of turns of each of the windings 40 - 45 is √3 times the number of turns of each of the windings 46, 47 Lv 2. This is necessary to shift relative to each other in phase by 30 el. hail, adjacent resulting (rectified) voltages U _r . The number of turns of each of the windings 6, 7, 8 of the transformer 1 is equal to the number of turns of each of its windings 3, 4, 5. This is necessary for the equality of the amplitudes of the voltages transformed into adjacent phase and separately for each phase secondary windings, connected in a triangle. The number of turns of each of the windings 15, 16, 17, connected in an open "triangle", is equal to one third of the sum of the number of turns, respectively, of windings 3 and 6, 4 and 7, 5 and 8. This is necessary for the free closure of the zero sequence current due to the equality of the sum of magnetomotive forces of windings 15, 16, 17 magnetomotive force of pairs of windings 3 and 6, 4 and 7, 5 and 8.

Diodes 48, 49 along the circuit of the smoothing reactor 50 perform the function of reverse (shunt) diodes. The smoothing reactor 50, creating an additional circuit for closing the current of the diodes 48, 49, thereby enhances the function of the open "triangle" on the windings 15, 16, 17 of the transformer 1 in the entire control range. This effect also occurs in the case of the connecting circuit in the form of an active load instead of the smoothing reactor 50. On this load (not shown in the drawing) a rectified voltage is formed, the frequency of which (m = 12) coincides with the frequency of the voltage across the load 39. This effect is provided by the mutual inductive coupling of the windings Ur 2 between the line and phase voltages of the network on the transformer 1. The inclusion of an active load in the cut of the connecting circuit with a smoothing reactor 50 makes it possible to obtain a rectified voltage on it without any ripples, ie in the form of an absolutely straight line parallel to the abscissa axis.

Gates 18-29 conduct primary current in pairs in the following order: 22-21, 21-19, 19-28, 28-26, 26-25, 25-23, 23-20, 20-18, 18-29, 29- 27, 27-24, 24-22. At the same time, in the same discreteness intervals, diodes 31-36 conduct a secondary current of three in the following order: 36-33-32, 36-33-32, 33-32-35, 33-32-35, 32-35-34, 32 -35-34, 35-34-31, 35-34-31, 34-31-36, 34-31-36, 31-36-33, 31-36-33. As you can see, the conduction angle of each diode in the bridge is 180 el. hail.

In each discrete interval, the geometric difference between the line and phase voltages of the network is alternately applied to a pair of windings Ur 2, for example, 41.47 when the valves 19, 21 are turned on. The resulting voltage U _r , transformed into the secondary phase windings 12 and 13 of the transformer 1, is determined according to the vector the diagram in FIG. 2. In this diagram, the vector connecting points a and b corresponds to the equalizing voltage of the reactor, and point l divides this vector, i.e. the sum of the numbers of turns of windings 47, 41 in a ratio equal to 1: √3. Then the phase shift between the voltage vectors U _r and U _0a is equal to 15 el. hail. Similarly, the vector of the resulting voltage U _{r is formed} in the next one after 15 el. hail. the discreteness interval in accordance with the sequence of switching on the controlled valves, determined by the natural alternation of line and phase voltages of the network.

When the current I _{0 is} closed through the windings 15, 16, 17 and one of the primary phase windings connected in an open "triangle", the sum of the ampere-turns of these windings is equal to zero, and their magnetomotive forces are directed oppositely. Compensation of the variable component of the rectified voltage occurs, the shape of which remains unchanged with any change in the valve control angle. Voltage regulation is carried out only by changing its amplitude, and without a phase shift relative to the ordinate axis. All processes in the converter take place under the dominance of the third harmonic frequency. This suppresses the manifestation of the second harmonic in the form of a rectified voltage.

In an additional three-phase transformer 30 MRT, the current I ₀ is divided into three equal currents I _w0 , which are closed through the phase input terminals A, B, C and one of the primary phase windings of transformer 1. This protects the network from multiple three harmonics of the primary phase current, and , due to the closure of a third of the current I ₀ between the MRT and one of the primary phase windings of the transformer 1, the load on the network decreases.

The converter allows the possibility of connecting a three-phase load to the output terminals of the secondary winding of the transformer 1, which provides in the voltage regulator mode a piecewise sinusoidal form of phase voltage and load current, with a duration of 360 el. hail. The voltage and current on each phase of the active load coincide in shape with the primary line current I _{A (MPT) of the} converter (Fig. 3). On the secondary side of the transformer 1, a 6-phase rectifier circuit with a midpoint can also be performed.

The converter in FIG. 4 differs from the converter in FIG. 1 in that it contains only one additional winding 47 Ur 2, replacing the missing smoothing reactor 50 in the first connecting circuit. This winding provides an inter-inductive connection between the line and phase voltages of the network, and together with the diodes 48, 49 - a circuit for closing the reactive current, contributing power factor stabilization.

The converter in FIG. 5 differs from the converters in FIG. 1 and FIG. 4 in that Ur 2 contains only two windings 41, 47, each of which is connected to the output terminals of the corresponding valve bridge. Windings 41, 47 Ur, in contrast to the windings of Ur in the well-known 6-phase single-ended circuit, are located on the primary side of the transformer and have unequal numbers of turns with a ratio of 1: √3 to form a 12-pulse mode of operation as a rectifier or voltage regulator.

Claims (7)

1. A three-phase AC voltage converter containing zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected to an open "delta", the first end terminal of which is connected to a zero input terminal, with secondary phase windings connected to the output terminals with the main load , for example, according to the rectifier circuit, the primary phase windings connected by the first group of extreme terminals to the phase input terminals, by each pair of intermediate terminals to the input and output terminals of one of the main group of two-terminal networks with counter-parallel controlled valves and the main windings of the equalizing reactor, and by the second group extreme terminals - to a group of additional controlled valves, connected in pairs to the terminals of the primary phase windings with opposite electrodes and forming free electrodes the output terminals of a three-phase valve bridge with the possibility of connecting them to the terminals of additional windings current of the equalizing reactor, characterized in that two connecting circuits are connected in parallel to the output terminals of the three-phase valve bridge, the first of which is made in the form of a smoothing reactor or / and an additional load, and the second is in the form of two series-connected additional two-port networks, each with a series-connected diode and the mentioned additional winding of the equalizing reactor, the common point of the additional two-terminal networks is connected to the second extreme terminal of the windings of the said open "triangle", while the windings in the additional two-terminal networks relative to the windings in the main group of two-terminal networks are connected to the same electrodes of the controlled valves with opposite terminals, and additional controlled valves and diodes additional two-pole connections form the arms of a three-phase valve bridge. 2. The converter according to claim 1, characterized in that in the first connecting circuit the smoothing reactor and the load are connected in series. 3. The converter according to claim 1, characterized in that it contains an interphase current distributor made on an additional three-phase transformer, the phase windings of which are connected by some terminals and a common point of the other terminals to the phase and zero input terminals, respectively. 4. A three-phase AC voltage converter containing zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected in an open "delta", the first end terminal of which is connected to the zero input terminal, with secondary phase windings connected to the output terminals, for example, according to the rectifier circuit, by the primary phase windings connected by the first group of extreme terminals to the phase input terminals, by each pair of intermediate terminals to the input and output terminals of one of the two-terminal group with counter-parallel controlled valves and the main windings of the equalizing reactor, and by the second group of extreme terminals to a group of additional controllable valves connected in pairs to the terminals of the primary phase windings with opposite electrodes and forming free electrodes the output terminals of the three-phase valve bridge connected to the output of the additional winding of the equalizing reactor, characterized in that that two connecting circuits are connected in parallel to the output terminals of the three-phase valve bridge, the first of which is made in the form of the said additional winding of the equalizing reactor, and the second is in the form of two diodes connected in series, the common point of opposite electrodes of which is connected to the second extreme terminal of the winding of the said open " triangle ", while the mentioned additional and main windings of the equalizing reactor are connected to the same electrodes of the controlled valves with opposite leads, and additional controlled valves and diodes of the second connecting circuit form the arms of a three-phase valve bridge. 5. The converter according to claim 4, characterized in that it contains an interphase current distributor made on an additional three-phase transformer, the phase windings of which are connected by one terminals and a common point of the other terminals to the phase and zero input terminals, respectively. 6. A three-phase AC voltage converter containing zero and phase input terminals, an equalizing reactor, a three-phase transformer with a winding connected in an open "delta", the first end terminal of which is connected to the zero input terminal, with secondary phase windings connected to the output terminals, for example, according to the rectifier circuit, the primary phase windings connected by the first group of extreme terminals to the phase input terminals, intermediate terminals to the main controlled valves connected in pairs by opposite electrodes, by the second group of extreme terminals to the additional controlled valves connected in pairs by opposite electrodes, forming the output terminals of the additional three-phase valve bridge connected to the output of the additional winding of the equalizing reactor, characterized in that the free electrodes of the main controlled valves form the output outputs of the main three-phase valve bridge, connected to the output of the main winding of the equalizing reactor, to the output terminals of the additional three-phase valve bridge are connected in parallel to the additional winding of the equalizing reactor two according to series-connected diodes, their common point of opposite electrodes is connected to the second end terminal of the winding of the said open "triangle", while the main and additional winding of the equalizing of the reactor are connected to the same-named electrodes of the controlled valves with opposite leads, and the additional controlled valves together with the diodes form the arms of an additional three-phase valve bridge. 7. The converter according to claim 6, characterized in that it contains an interphase current distributor made on an additional three-phase transformer, the phase windings of which are connected by one terminals and a common point of the other terminals to the phase and zero input terminals, respectively.

Images