DE3826524C2 - Power feed circuit with suction throttle - Google Patents

Description

The invention relates to a power feed circuit with suction throttle according to the preamble of claim 1.

Such a power feed circuit with suction throttle is off the BBC silicon power converter manual, 1971, pages 158 to 161 known. The double star circuit described there with suction throttle can also be used as a six-pulse circuit for large outputs.

From etz Archis Volume 7 (1985), No. 7, pages 219 to 224 is a Double inverter system with three-phase inductor for one High-performance drive known, in which a six-strand Asynchronous motor via a three-phase inductor-coupled double inverter system (Pulse inverter) with DC link and feed converter from a three-phase network becomes. The construction work required for a Motor current smoothing compared to linear pre-chokes greatly reduced. Certain groups of harmonics of the motor current are completely or partially eliminated without the fundamental oscillation to influence.

DE 38 16 444 A1 describes a pulse width modulation control device for one powered by a DC voltage source Equalizing choke multiplex inverter known. Here are the Three-phase outputs of the two inverters via compensation chokes connected to each other so that at the centers of the compensating chokes parallel three-phase multiplex outputs for the Load current are formed.  

Power feeds from the three-phase network into a DC voltage intermediate circuit usually consist of a controlled or uncontrolled six-pulse feed converter that over Line chokes are connected to the three-phase network and an intermediate circuit capacitor. The line reactors serve as commutation and possibly as smoothing chokes, as well as together with the input fuses to protect the converter.

In order to make such a power feed network-friendly, d. H. the harmonic component of the feed currents of the converter To keep it small, the line chokes would have a very large inductance have, which worsens the dynamics of the feed very much. Load jumps on the DC voltage side lead to large dynamic Voltage changes in the DC link.

Proceeding from this, the invention is based on the object of a Power feed circuit with suction throttle of the input Specify the type mentioned, which is a great network friendliness and good dynamic Properties guaranteed.

This task is alternatively used in conjunction with the characteristics of the According to the invention, in the characterizing part of claims 1 and 4 specified features solved.

The advantages that can be achieved with the invention are in particular in that a good 12-pulse rectifier operation with comparative little additional effort (two magnetic components) the 6-pulse circuit is made possible. Doubling the Pulse count from six to twelve lowers the harmonic content of the Feed currents of the feed strongly and thus enables a Reduction of the line chokes, which improves the dynamics.

By further doubling the number of pulses to twenty-four by feeding two twelve-pulse power feeds with line-side suction throttle via a further line-side suction throttle (a total of four magnetic components) the harmonic component can be reduce the mains current further.  

The execution of the line-side suction throttle circuit can be created by interconnecting winding groups three single-phase cores to a three-phase inductor.

An advantageous embodiment is the integration of the three single-phase components to form a three-phase unit. Because of the flow curve given by the voltage curves, whose value in one leg is not equal to that Sum of the flows in the other two legs is the execution of the three phase core with more than three legs required, for example from Reasons for symmetry as a five-legged core.

According to an advantageous development of the invention can also use a current divider choke between the three-phase network and suction throttle circuit can be provided. Of the The advantage that can be achieved in this way is in particular that a good 18-pulse rectifier operation with comparative little additional effort compared to the 6-pulse Circuit is made possible. Tripling the number of pulses from six to eighteen lowers the harmonic content of the feed streams strongly from and enables a reduction of the line chokes, which improves the dynamics.

The 18-pulse rectifier circuit requires three magnetic ones Components for tripling the number of pulses. The harmonic content of the mains currents is lower than with the 12-pulse circuits, the effort is similarly cheap. The 18-pulse circuit is regarding the number of components and the effort cheaper than the 24-pulse circuits.  

The design of the current divider choke and the line-side Suction throttle can be created by interconnecting winding groups on three single-phase cores to one Three-phase suction throttle or a three-phase flow divider respectively.

An advantageous embodiment of the current divider choke exists in the integration of the three single-phase components to a three-phase unit. Because of the through the Voltage curves given flow pattern, its value in one leg is not equal to the sum of the flows in the other two legs is the execution of the Three-phase cores with more than three legs required for example, for reasons of symmetry as a five-legged core.

Further advantageous embodiments of the invention are characterized in the subclaims.

The invention is described below with reference to the drawing illustrated embodiments explained. It shows

Fig. 1, a power feed line-side with drainage coil circuit,

Fig. 2 shows the interconnection of the power supply of FIG. 1 with symbolic pointer image representation of the voltages at the network-side interphase reactor,

Fig. 3 shows the typical time courses of interest currents and voltages for the circuit of Fig. 1 and 2,

Fig. 4 shows a modified to Fig. 1 drainage coil circuit,

Fig. 5 is a simplified drainage coil circuit,

Fig. 6 a three Saugdrosselschaltungen arrangement,

FIG. 7 shows the connection of the power supply according to FIG. 6 with a symbolic pointer representation of the voltages at the suction throttle circuits

Fig. 8 is a circuit 6pulsigem Rückarbeits- inverter,

Fig. 9 shows a circuit with 12pulsigem Rückarbeits- inverter,

Fig. 10 shows a current divider with Leistungseinspeiseschaltung throttle and line-side interphase reactor,

Fig. 11, 12, the typical time courses of interest currents and voltages for the circuit of Fig. 10.

In Fig. 1 a Leistungseinspeiserschaltung is shown with mains-side drainage coil. A three-phase network 1 with its three phases L1, L2, L3 and the neutral conductor N can be seen, to which a converter 4 is connected via line reactors 2 and via a line-side three-phase inductor circuit 3 a. The line chokes 2 serve to absorb the distortion voltages. The converter 4 feeds a DC voltage load 5 represented by a resistor R and a capacitor C, preferably a DC voltage intermediate circuit with an intermediate circuit capacitor.

The suction throttle circuit 3 a consists of twelve suction throttle windings 6 to 17 in magnetic and electrical operative connection, four windings each forming a winding group and arranged on a common, magnetizable core 18 to 20 . Specifically, the windings 6, 7, 13, 17 (first winding group) are on the core 18 , the windings 8, 9, 14, 15 (second winding group) are on the core 19 and the windings 10, 11, 12, 16 ( third winding group) on the core 20 . The mains supply of the suction throttle circuit 3 a takes place at the three network-side connection terminals (taps) U3, V3, W3, U3 being the common connection point of the windings 6, 7 , V3 the common connection point of the windings 8, 9 and W3 the common connection point of the windings 10, 11 correspond. The outer terminals U1, U2, V1, V2, W1, W2 of these windings 6 to 11 are connected to the other windings 12 to 17 such that the terminals U1, U2, V1, V2, W1, W2 of the windings 6 to 11 one Core in each case cyclically interchanged and connected in opposite directions to the terminals U21, U12, V21, V12, W21, W12 of the windings 12 to 17 on the two other cores and the other terminals U11, U22, V11, V22, W11, W22 of the windings 12 to 17 , the six load-side terminals to which AC connections of the converter 4 are guided.

Specifically, the terminal U1 of the winding 6 is connected to the terminal W21 of the winding 12 . The further terminal W22 of the winding 12 forms the first AC connection. Terminal W1 of winding 10 is connected to terminal V21 of winding 14 . The further terminal V22 of the winding 14 forms the second AC connection. Terminal V1 of winding 8 is connected to terminal U21 of winding 13 . The further terminal U22 of the winding 13 forms the third AC connection. The terminal W2 of the winding 11 is connected to the terminal U12 of the winding 17 . The further terminal U11 of the winding 17 forms the fourth AC connection. Terminal U2 of winding 7 is connected to terminal V12 of winding 15 . The further terminal V11 of the winding 15 forms the fifth AC connection. Terminal V2 of winding 9 is connected to terminal W12 of winding 16 . The further terminal W11 of the winding 16 forms the sixth AC connection. The number of turns of windings 6 to 11 is WA and the number of turns of windings 12 to 17 is WB.

With a twelve-pulse circuit, the number of turns ratio WB / WA has the value WB / WA = 0.366. The windings with the smallest number of turns WB must be designed for 12-pulse operation for a sinusoidal voltage of about U _WB = 0.0457 U _N with the mains frequency f, where U _{N is} the voltage of the three-phase network and U _{WB is} the voltage on the winding with the Number of turns WB.

The converter 4 is designed as a six-phase three-phase rectifier in a bridge circuit with twelve rectifier valves D1 to D12. The rectifier valves D1. . . D12 can be controllable or uncontrolled.

FIG. 2 shows the connection of the power feed circuit according to FIG. 1 with the symbolic pointer image representation of the voltages at the line-side suction throttle circuit 3 a. In particular, the arrangement of the windings on the three magnetizable cores 18, 19, 20 , the supply of the suction choke circuit via the line chokes 2 and the connection of the suction choke circuit 3 a to the converter 4 can be seen. The connections between the windings of different cores are not shown. The same direction of windings means that the windings are arranged on the same core.

Due to the special arrangement of the windings 6 to 17 on the cores 18 to 20 of the suction throttle circuit 3 a, the currents flowing in the windings are transformed such that the mains current between the zero crossings of the mains voltage and very small load currents is a non-zero value at all times Has.

The relative magnitude of the currents in the windings of the induction choke circuit 3 a can be set via the number of turns WA / WB of the windings and thus the current in the supply lines, with a suitable choice of the relative short-circuit voltage of the line chokes, can be optimally adapted to the sinusoidal shape. The differential voltage between the line voltage and the AC voltage at the rectifier load 4 is applied by the suction throttle circuit 3 a and the line reactor 2 .

FIG. 3 shows the typical time profiles of the currents and voltages of interest for the circuit according to FIGS. 1 and 2. It is the mains voltage (star voltage) UL1-N (solid line), the voltage at the connection terminal U3 of the suction throttle circuit UU3-N (star voltage, dashed line), the mains current iL1 (solid line) and the currents i 6 (dashed line) and i 7 (dash-dotted line) shown in the windings 6 and 7 (suction throttle currents, see Fig. 1). The fundamental vibrations of the inductor currents i 6 , i 7 have a phase difference of 30 ° to one another. The mains current iL1 is made up of these two inductor currents i 6 , i 7 . The arrangement of the line chokes 2 in the line feed lines results in a smoothing of the line current and thus an improved approximation to the sinusoidal shape.

By using the three-phase suction throttle circuit on the mains side becomes a 12-pulse load current (Direct current) achieved, d. H. the ripple of the Load current is greatly reduced by the suction throttle.

A suction throttle circuit modified to FIG. 1 is shown in FIG. 4. The suction throttle circuit 3 a consists of twelve windings 6 to 17 , the windings 6, 7, 13, 17 (first winding group) on core 18 , the windings 8, 9, 14, 15 (second winding group) on core 19 and the windings 10 , 11, 12, 16 (third winding group) are arranged on core 20 , as already described under FIG. 1. The terminals U3 or V3 or W3 of the windings 6/7 or 8/9 or 10/11 in turn form the taps for the power supply (line-side connection terminals). Terminal W1 of winding 10 is connected to terminal U22 of winding 13 . The further terminal U21 of the winding 13 forms the first AC connection. Terminal U1 of winding 6 is connected to terminal V22 of winding 14 . The further terminal V21 of the winding 14 forms the second AC connection. Terminal V1 of winding 8 is connected to terminal W22 of winding 12 . The further terminal W21 of the winding 12 forms the third AC connection. Terminal U2 of winding 7 is connected to terminal W11 of winding 16 . The further terminal W12 of the winding 16 forms the fourth AC connection. The terminal W2 of the winding 11 is connected to the terminal V11 of the winding 15 . The further terminal V12 of the winding 15 forms the fifth AC connection. Terminal V2 of winding 9 is connected to terminal U11 of winding 17 . The further terminal U12 of the winding 17 forms the sixth AC connection. The number of turns of windings 6 to 11 is WA + WB and the number of turns of windings 12 to 17 is WB.

In the case of a twelve-pulse suction throttle circuit, the number of turns ratios have approximately the values WB / WA = 0.366 and WB / WA + WB = 0.268. The windings with the smallest number of turns WB must be designed for 12-pulse operation for a sinusoidal voltage of approximately U _WB = 0.0392 UN with the mains frequency f.

The rest of the circuit arrangement of FIG. 4 is as described under FIG. 1. The symbolic pointer image representation of the voltages of the suction throttle circuit 3 a according to FIG. 4 is also shown.

In Fig. 5 is a simplified drainage coil is illustrated. The suction throttle circuit 3 a consists of only nine windings 21 to 29 , the windings 21 to 23 (first winding group) on the magnetizable core 54 , the windings 24 to 26 (second winding group) on core 55 and the windings 27 to 29 (third winding group ) are arranged on core 56 . The terminals U1 or V1 or W1 of the windings 21 or 24 or 27 form the tap for the power supply (line-side connection terminals). The terminal W2 of the winding 27 is connected to the common terminal U23 of the winding 22 and 23 . The further terminal U21 of the winding 22 forms the first AC connection. The further terminal U22 of the winding 23 forms the fourth AC connection. The terminal U2 of the winding 21 is connected to the common terminal V23 of the windings 25 and 26 . The further terminal V21 of the winding 25 forms the second AC connection. The further terminal V22 of the winding 26 forms the fifth AC connection. The terminal V2 of the winding 24 is connected to the common terminal W23 of the windings 28 and 29 . The further terminal W21 of the winding 28 forms the third AC connection. The further terminal W22 of the winding 29 forms the sixth AC connection. The number of turns of the windings 21, 24, 27 is WB, the number of turns of the windings 22, 25, 28 is WA and the number of turns of the windings 23, 26, 29 is WA + WB.

In the case of a twelve-pulse suction throttle circuit, the number of turns ratio has approximately the value WB / WA = 0.366. In 12-pulse operation, the windings with the smallest number of windings WB must be designed for a sinusoidal voltage of approximately U _WB = 0.0355 UN with the mains frequency f.

The rest of the circuit arrangement is as described under Fig. 1.

The symbolic pointer image representation of the voltages of the suction throttle circuit 3 a according to FIG. 5 is also shown.

FIG. 6 shows an arrangement consisting of three three-phase suction throttle circuits on the network side. The first suction throttle circuit 3 a with the cores 18 to 20 and the total of twelve windings 6 to 17 is, as described under Fig. 4, connected. The number of turns ratio, however, has approximately the value WB ′ / WA ′ = 0.165 in order to achieve a 24-pulse rate. The outer terminals of the windings 14, 12, 13 and 16, 17, 15 (the load-side terminals) do not form AC connections of a converter 4 , but feeds of the second or third inductor circuit 3 b or 3 c.

The second suction throttle circuit 3 b has three cores 57, 58, 59 , with windings 30, 31, 37, 41 (first winding group) on the core 57 , windings 32, 33, 38, 39 (second winding group) on the core 58 and Windings 34, 35, 36, 40 (third winding group) are arranged on the core 59 . The third suction throttle circuit 3 c has three cores 60, 61, 62 , with windings 42, 43, 49, 53 (first winding group) on the core 60 , windings 44, 45, 50, 51 (second winding group) on the core 61 and Windings 46, 47, 48, 52 (third winding group) are arranged on the core 62 . The connection of the suction throttle circuits 3 b, 3 c is also as described under Fig. 4.

In the case of the suction throttle circuits 3 b and 3 c, the number of turns ratio must have the value WB / WA = 0.366 in order to achieve a twelve-pulse pulse.

A 12-phase rectifier in bridge circuit with a total of twenty-four rectifier valves D1 to D24 (controllable or not controllable) serves as the converter 4 .

By using a total of three suction throttle circuits 3 a, 3 b, 3 c, a 24-pulse rate of the load current (direct current) is achieved, ie the ripple of the load current is again greatly reduced.

FIG. 7 shows the connection of the power supply circuit according to FIG. 6 with the symbolic pointer image representation of the voltages at the line-side suction chokes. It is in particular the arrangement of the three suction throttle circuits 3 a, 3 b, 3 c, each with three cores, 18 - 20 , 57 - 59 , 60 - 62, the supply of the suction throttle circuits 3 a, 3 b, 3 c via the line chokes 2 and Connection of the suction throttle circuits 3 a, 3 b, 3 c to the converter 4 can be seen. The connections between the windings of different magnetizable cores are not shown. Each of the three suction throttle circuits 3 a, 3 b, 3 c represents a phase number doubler, the suction throttle circuits 3 b, 3 c with the cores 57 to 59 and 60 to 62 each having its own 12-pulse rectifier.

The arrangement of three-phase suction throttles in connection with rectifiers and large DC link capacity (DC link capacitor) requires a limitation of the inrush current. Such a limitation will by modifying the rectifier with replacement part or all of the uncontrolled converter valves achieved by controllable converter valves. This allows the current to be controlled.  

When feedback into the three-phase network is required can the arrangement of three-phase suction throttle circuits and higher-phase rectifier bridge advantageous with rework inverters without a disadvantageous one Increasing the connection voltage of the inverter accomplish with a transformer.

In FIG. 8 is a circuit with feedback working inverters is shown. The suction throttle circuit 3 a with the cores 18 to 20 and the twelve windings 6 to 17 is, as described under Fig. 4, connected. The outer terminals of the windings 12 to 14 and 15 to 17 (load-side connection terminals) in turn form AC connections of the rectifier valves D1. . . D12 constructed converter 4 in rectifier bridge circuit. The 6-pulse rework inverter 63 is made up of six controllable converter valves T13. . . T16 built in three-phase bridge circuit and connected to three-phase network 1 on the AC side. On the DC side, the rework inverter 63 is connected to the positive and negative load connection (DC output) via a smoothing choke 64, 65 each.

The turns ratio is WB / WA = 0.366.

As a result of the suction throttle effect which also occurs in generally known suction throttle circuits, that is to say increasing the direct voltage in the case of load currents below the magnetizing current of the suction throttle and lowering the output voltage in the case of load currents above the magnetizing current compared to the output voltage without the suction throttle, the voltage reserve required for the reworking inverter 63 becomes available.

In Fig. 9 shows a circuit with 12pulsigem Rückarbeits- inverter. The use of such a 12-pulse inverter makes it possible to dispense with the smoothing chokes 64, 65 according to FIG. 8. The suction throttle circuit 3 a with the cores 18 to 20 and the windings 6 to 17 is connected as described under FIG. 4. The outer terminals of the windings 12 to 14 and 15 to 17 simultaneously form the AC connections of the rectifier valves D1. . . D12 constructed converter 4 in rectifier bridge circuit as well as the controllable converter valves T1. . . T12-built rework inverter 66 in a 12-pulse bridge circuit. Each rectifier valve D1. . . D12 is a controllable converter valve T1. . . T12 anti-parallel.

The turns ratio is WB / WA = 0.366.

The converter valves assigned to the inverter 66 also enable regenerative operation without connecting the inverter 66 to a higher grid voltage.

In general, it applies to all circuits that the suction throttle circuit 3 a, 3 b, 3 c on the mains side can consist of three single-phase cores or one three-phase core each. The three-phase core can be constructed as a four-legged core or as a five-legged core.

The three described variants of the suction throttle circuit ( FIG. 1, FIG. 4, FIG. 5) differ in their effect on the zero system.

To achieve a twelve-pulse the ratio of turns must be the suction throttle circuit approximately the value WB / WA = 0.366. Then there will be two load-side  Power systems generated, the fundamental vibrations about one Have a phase difference of 30 °.

To achieve a twenty-four pulse rate, the Approximate number of turns of the suction throttle circuit have the value WB / WA = 0.165. Then there will be two load-side Electricity systems generated, their fundamental vibrations have approximately a phase difference of 15 °.

Alternatively or in addition to the line chokes 2 , line chokes can be arranged between the load-side terminals of the suction throttle circuit and the AC connections of the rectifiers.

In Fig. 10 a Leistungseinspeiseschaltung is shown with mains-side suction throttle valve and additional flow divider throttle. It can be seen a three-phase network 1 with its three phases L1, L2, L3 and the neutral conductor N to which the network-side suction throttle is 3 a, a power converter 4 is connected via line reactors 2, via a current divider throttle 67 and. The line chokes 2 , whose windings are designed for the nominal alternating current I _{N of} the power feed circuit, serve to absorb the distortion voltages. The converter 4 feeds the DC voltage load 5 represented by the resistor R and the capacitor C, preferably a DC voltage intermediate circuit with an intermediate circuit capacitor.

The circuit of the current divider choke 67 consists of six windings 68 to 73 in magnetic and electrical operative connection, two windings each forming a winding group and arranged on a common, magnetizable core 74 to 76 . In particular, the windings 68 and 69 (first winding group) are on the core 74 , the windings 70 and 71 (second winding group) on the core 75 and the windings 72 and 73 (third winding group) on the core 76 . The power supply of the current divider choke 67 takes place at the three network-side connection terminals (taps) U4, V4, W4, U4 the common connection point of the windings 68 and 69 , V4 the common connection point of the windings 70 and 71 and W4 the common connection point of the windings 72 and 73 correspond. The terminals U5, V5, W5, U6, V6, W6 form the load-side connection terminals of the current divider choke 67 . The terminal U6 of the winding 69, the terminal V6 of the winding 71 and the terminal W6 of the winding 73 are led directly to AC connections of the converter 4 . The terminals U5, V5, W5 of the current divider choke 67 are connected directly to the mains-side terminals W1, U1, V1, the suction choke 3 a. Specifically, terminal U5 of winding 68 is connected to terminal W1 of winding 27 , terminal V5 of winding 70 is connected to terminal U1 of winding 21, and terminal W5 of winding 72 is connected to terminal V1 of winding 24 .

The number of turns of the windings 68, 70 and 72 is W _D and the number of turns of the windings 69, 71 and 73 is W _C. The number of turns ratio W _D / W _C has approximately the value W _D / W _C = 0.5321. The windings with the smaller number of turns W _D must be designed for a sinusoidal voltage of U _WD = 0.033 U _N with the network frequency f, where U _{N is} the voltage of the three-phase network and U _{WD is} the voltage on the winding with the number of turns W _D. The windings with the number of turns W _D must be designed for an alternating current of 0.67 I _N and the windings with the number of turns W _C for an alternating current of 0.33 I _N.

The six load-side terminals U21, V21, W21, U22, V22 and W22 of the line-side suction throttle 3 a are connected directly to the remaining AC connections of the converter 4 . The arrangement of the windings 21 to 29 of the line-side suction throttle circuit 3 a on the magnetizable cores 54 to 56 and the connection of the windings 21 to 29 is as described under FIG. 5. The number of turns of the windings 21, 24 and 27 is W _B , the number of turns of the windings 22, 25 and 28 is W _A and the number of turns of the windings 23, 26 and 29 is W _A + W _B.

In this 18-pulse circuit, the number of turns ratio W _B / W _{A has} approximately the same value W _B / W _A = 0.5321. The windings with the smallest number of turns W _B must be designed for 18-pulse operation for a sinusoidal voltage of approximately U _WB = 0.064 U _N with the mains frequency f, where U _{WB is} the voltage at the winding of the number of turns W _B. The windings with the number of turns W _B must be designed for an alternating current of 0.67 I _N and the windings with the number of turns W _A and W _A + W _B for an alternating current of 0.33 I _N.

Instead of the network-side suction throttle valve 3 a, the other can above in Fig. 1 and variations of the network-side suction throttle 4 described are used, wherein the above-indicated turns ratio is to be set.

The converter 4 is designed as a nine-phase three-phase rectifier in a bridge circuit with eighteen rectifier valves D1 to D18. The rectifier valves D1 to D18 can be controllable or uncontrolled.

Due to the special arrangement of the windings of the current divider choke 67 and the line-side inductor 3 a, the currents flowing in the windings are transformed such that the line current between the zero crossings of the line voltage and very small load currents has a non-zero value at all times.

The relative level of the currents in the windings of the current divider inductor 67 and the line-side inductor 3 a can be set via the number of turns ratios W _D / W _C or W _B / W _{A of} the windings and thus the current in the supply lines, with a suitable choice of the relative Short circuit voltage of the line chokes, optimally adapt to the sinusoidal shape. The differential voltage between the line voltage and the alternating voltage at the rectifier load 4 is applied by the line choke 2 , the current divider choke 67 and the line-side inductor 3 a.

In Figs. 11 and 12, the typical time courses of interest currents and voltages for the circuit of Fig. 10 are shown. In Fig. 11, the mains voltage (phase voltage) U _L1-N (solid trace), the voltage at the Anschlußkemme U4 of the current divider throttle U _{U 4-N} (neutral voltage, dashed trace) and the line current i _L1 (solid trace) are shown. The arrangement of the line chokes 2 in the line feed lines results in a smoothing of the line current and thus an improved approximation to the sinusoidal shape.

In Fig. 12 are the line voltage U _{L 1-N} (star voltage, solid line), the line current i _L1 (solid line), the current i ₂₃ through the winding 23 (solid line), the current i ₂₂ through the winding 22 ( dotted line) and the current i ₆₉ through the winding 69 (dashed line) shown. The fundamental oscillations of the currents i ₂₃ and i _{22 of} the line-side inductor 3 a have a phase difference Δt1 = 0.111 T Δωt of 40 ° to one another (T = period of a fundamental oscillation, ω = angular frequency = 2π f, f = mains frequency), the fundamental oscillation of the current i _{23 leads} the fundamental oscillation of the mains current i _L1 by 20 ° (phase difference Δt2 = 0.056 T Δωt = 20 °). The fundamental oscillation of the current i _{69 of} the current divider choke is in phase with the fundamental oscillation of the mains current i _L1 .

By using the line-side suction throttle circuit 3 a and the current divider choke 67 , an 18-pulse rate of the load current (direct current) is achieved, ie the ripple of the load current is greatly reduced by the two chokes.

The arrangement of the current divider choke 67 and the line-side suction throttle circuit 3 a in connection with the converter 4 and the large intermediate circuit capacitance (intermediate circuit capacitor) requires a limitation of the inrush current. Such a limitation is achieved by modifying the converter 4 by replacing some or all of the uncontrolled converter valves with controllable converter valves. This allows the current to be controlled.

In general, that the current divider throttle 67 and the network-side interphase reactor 3 a may be comprised of three or Einphasenkernen of one three-phase core. The three-phase cores can be constructed as five-leg cores.

As an alternative or in addition to the line chokes 2 , line chokes 77 to 85 can be arranged between the load-side terminals of the current divider choke 67 and the line-side suction choke 3 a and the AC connections of the converter 4 , as indicated by dashed lines.

The circuits indicated in FIGS . 8 and 9 can be used to feed electrical energy from the DC voltage circuit back into the three-phase voltage network.

Claims (27)

1. Power supply circuit from a three-phase network into a DC voltage load via a converter with three-phase, line-side suction throttle circuit, characterized by the following features:

• - The three-phase, line-side suction throttle circuit ( 3 a) consists of three winding groups each having a common, magnetizable core or leg ( 18 to 20 ), each winding group having four windings,
• - The center of two winding group halves is connected to one phase of the three-phase network ( 1 ),
• - each phase of the three-phase network (1) with windings on all three cores or legs (18 - 20) electrically connected,
• - Each winding group has two load-side terminals for connection to the AC connections of at least a 12-pulse converter ( 4 ) in a bridge circuit.

2. Power feed circuit according to claim 1, characterized in that the windings are connected in opposite directions in series and the windings with the smallest number of turns (WB) are designed for a sinusoidal voltage of U _WB = 0.0457 UN with the mains frequency f, where UN the Voltage of the three-phase network and U _{WB are} the voltage on the winding with the smallest number of turns ( Fig. 1). 3. Power feed circuit according to claim 1, characterized in that the windings are connected in the same direction in series and the windings with the smallest number of turns (WB) are designed for a sinusoidal voltage of U _WB = 0.0392 UN with the mains frequency f, where UN the Voltage of the three-phase network and U _{WB are} the voltage on the winding with the smallest number of turns ( Fig. 4). 4. Power supply circuit from a three-phase network into a DC voltage load via a converter with three-phase, line-side suction throttle circuit characterized by the following features:

• - The three-phase, line-side suction throttle circuit ( 3 a) consists of three winding groups each having a common, magnetizable core or leg ( 54 to 56 ), each winding group having four windings,
• - The connection of a winding of each winding group is connected to one phase of the three-phase network ( 1 ),
• - each phase of the three-phase network (1) with windings on only two cores or legs (18 - 20) electrically connected,
• - Each winding group has two load-side terminals for connection to the AC connections of an at least 12-pulse converter ( 4 ) in a bridge circuit ( Fig. 5).

5. Power feed circuit according to claim 4, characterized in that the windings with the largest number of turns (WA + WB) each connected in series with the windings with the average number of turns (WA) and each arranged on the same core that the windings with the smallest number of turns (WB) with the windings with the largest number of turns (WA + WB) connected in series in the same direction and arranged on different cores, and that the windings with the lowest number of turns (WB) for a sinusoidal voltage of U _WB = 0.0355 UN are designed with the network frequency f, where UN is the voltage of the three-phase network and U _{WB is} the voltage at the winding with the smallest number of turns ( FIG. 5). 6. Power feed circuit according to one of claims 1 to 5, characterized in that the number of turns ratio (WB / WA) between the smallest number of turns (WB) and the average number of turns (WA) for 12-pulse operation has the value 0.366 and for 24-pulse operation the value 0.165. 7. Power feed circuit according to one of claims 1 to 6, characterized in that to form a 24-pulse circuit second and third twelve-pulse suction throttle circuits ( 3 b, 3 c) via the line-side suction throttle circuit ( 3 a) with the number of turns ratio (WB '/ WA') are connected between the smallest number of turns (WB ') and the average number of turns (WA') of 0.165 with the three-phase network ( 1 ) ( Fig. 6, 7). 8. Power feed circuit according to one of claims 1 to 7, characterized in that the three-phase line-side suction throttle circuit ( 3 a, b, c) consists of three single-phase cores with associated winding groups. 9. Power feed circuit according to one of claims 1 to 7, characterized in that the three-phase suction throttle circuit ( 3 a, b, c) consists of a three-phase core with associated winding groups. 10. Power feed circuit according to claim 9, characterized characterized in that the three-phase core has five legs is executed. 11. Power feed circuit according to one of claims 1 to 10, characterized in that between the load-side terminals of the suction throttle circuit ( 3 a) and the AC connections of the converter ( 4 ) line chokes ( 77 - 82 ) are arranged. 12. Power feed circuit according to one of claims 1 to 11, characterized in that between the three-phase network ( 1 ) and the line-side suction throttle circuit ( 3 a) line chokes ( 2 ) are arranged. 13. Power feed circuit according to one of claims 1 to 12, characterized in that at least part of the rectifier valves (D1 ... D24) of the converter ( 4 ) is designed to be controllable. 14. Power feed circuit according to one of claims 1 to 12, characterized in that antiparallel to the rectifier valves (D1 ... D12) controllable valves (T1 ... T12) of a reverse inverter ( 66 ) for energy recovery from the DC load ( 5 ) are arranged in the three-phase network ( 1 ) ( Fig. 9). 15. Power feed circuit according to one of claims 1 to 12, characterized in that a six-pulse rework inverter ( 63 ) consisting of six controllable valves (T13 ... T18) with its DC connections via two smoothing chokes ( 64, 65 ) to the DC voltage load ( 5 ) and with its three-phase connections to the three-phase network ( 1 ) ( Fig. 8). 16. Power supply circuit according to one of claims 1 to 15, characterized by the use of a three-phase current divider choke ( 67 ) between the three-phase network ( 1 ) and suction throttle circuit ( 3 a), the current divider choke ( 67 ) each consisting of two windings ( 68 to 73 ) , each contains a common magnetizable core ( 74 to 76 ) having winding groups and the three-phase network ( 1 ) is connected with one phase to a connection of such a winding group. 17. Power feed circuit according to claim 16, characterized in that the two windings of a winding group of the current divider choke ( 67 ) are connected in series in the same direction and the windings with the smaller number of turns (W _D ) for a sinusoidal voltage of U _WD = 0.033 U _N with the Mains frequency f are designed, where U _{N is} the voltage of the three-phase network and U _{WD is} the voltage on the winding with the smaller number of turns. 18. Power feed circuit according to claim 16 and / or 17, characterized in that the number of turns ratio (W _D / W _C ) between the smaller number of turns (W _D ) and the larger number of turns (W _C ) of the current divider choke ( 67 ) has the value 0.5321 having. 19. Power supply circuit according to one of claims 16 to 18, characterized in that each of the winding groups of the current divider choke ( 67 ) has a line-side connection terminal for connection to the three-phase network ( 1 ) and two load-side connection terminals for connection to an AC connection of the converter designed as a rectifier in a three-phase bridge circuit ( 4 ) or a line-side connection terminal of the line-side suction throttle circuit ( 3 a), with all windings belonging to a winding group being arranged on a core or leg. 20. Power feed circuit according to one of claims 16 to 19, characterized in that the three-phase current divider choke ( 67 ) consists of three single-phase cores with associated winding groups. 21. Power feed circuit according to one of claims 16 to 19, characterized in that the three-phase current divider choke ( 67 ) consists of a three-phase core with associated winding groups. 22. Power feed circuit according to claim 21, characterized characterized in that the three-phase core has four legs is executed. 23. Power feed circuit according to claim 21, characterized characterized in that the three-phase core has five legs is executed. 24. Power supply circuit according to one of claims 16 to 23, characterized in that between the three-phase network ( 1 ) and current divider choke ( 67 ) line chokes ( 2 ) are arranged. 25. Power feed circuit according to one of claims 16 to 24, characterized in that between the AC connections of the converter ( 4 ) and the load-side terminals of the current divider choke ( 67 ) or the line-side inductor ( 3 a) line chokes ( 83 - 85 ) are arranged. 26. Power feed circuit according to one of claims 16 to 25, characterized in that at least part of the rectifier valves (D1 to D18) of the converter ( 4 ) is designed to be controllable. 27. Power supply circuit according to one of claims 16 to 26, characterized in that the number of turns ratio (W _B / W _A ) between the smallest number of turns (W _B ) and the average number of turns (W _A ) of the line-side inductor ( 3 a) for 18- Pulse mode has the value 0.5321, and that the windings with the smallest number of turns (W _B ) are designed for a sinusoidal voltage of U _WB = 0.064 U _N with the network frequency f, where U _{N is} the voltage of the three-phase network ( 1 ) and U _{WB are} the voltage on the winding with the smallest number of turns.