DE4025685A1 - Rectifying circuit protecting mains against transformer harmonics - utilises star connections of phase-shifted sec. windings for integration of parasitic capacitances into filter circuits - Google Patents

Abstract

The transformer has a three-phase prim. winding (2) and two sec. windings (3, 4) supplying respective bridge rectifiers (9, 10) and filtering chokes (SL) and capacitors (SC1, SC2). The DC output is pulse-width-modulated by electronic switches (13, 14) with free-wheel diodes (15) and low-pass filters (16, 17). Both sec. windings (3, 4) are star-connected and partially coupled to the prim. winding (2) so that on the sec. side the capacitances (CQ, CT) between windings and to the earthed screen (6) are in parallel with the low-pass filter capacitances (FC). USE/ADVANTAGE - Esp. at high-power transmitters. Stray capacitances are integrated into mains protection circuit.

Description

The invention relates to a converter circuit, in particular for a high-performance transmitter, a three-phase, primary winding arrangement of a transformer at least two three-phase, secondary-side winding arrangements are assigned and each secondary winding arrangement a bridge rectifier with filter element is connected downstream and the voltages of the two secondary winding arrangements are out of phase with each other.

Such a converter circuit is described in DE PS 26 53 137 described. The fact that two secondary-sided Winding arrangements are provided, each of the two needs Bridge rectifier and the relevant secondary side Winding arrangement should only be designed for half the voltage. For example, the two bridge rectifiers in Series a DC voltage of about 30 kV to a transmitter component then it is sufficient if each of the secondary winding arrangements, the respective bridge rectifier and the associated switching elements are designed for 15 kV.

In DE-PS 26 53 137 is a secondary winding arrangement in the star and the other secondary winding arrangement switched in a triangle. This results in one Phase shift of 30 ° between the output voltages. This system corresponds to a 12-pulse converter system. This enforces the harmonic loads on the network the converter circuit down. The current distortion factor is decreased. The ripple voltage is reduced to what's going on the interference voltage distance of the connected consumer  (Transmitter) has a favorable effect. It is accepted that the delta connection does not have a star point that becomes the Integrating the capacities of the transformer into a downstream one Low pass filter is suitable.

In the earlier patent application P 38 22 957.9 is a power amplifier with a transformer and a low pass filter described. The inherently harmful construction capacities of the transformer become the capacities of the low-pass filter. This reduces the power loss.

The object of the invention is a circuit of the input Specify the type in which the harmonic load of the Network is small and at the same time harmful capacities of the transformer integrated into circuit capacities will.

According to the invention, the above object is for a converter circuit of the type mentioned in that both secondary winding arrangements connected in a star are and that for the phase shift the secondary side Windings of one and / or the other on the secondary side Winding arrangement partially to that primary winding the primary winding arrangement are coupled, assigned to the adjacent secondary winding is.

Since the star points on both secondary winding arrangements are available, it is possible to switch between these and capacities acting on the transformer structure, for example Screen capacities to connect capacitors to the circuit. This eliminates the effects of disruptive Transformer capacities largely suppressed.

The phase shift between the two secondary sides  Winding arrangements to reduce harmonic loads of the network is caused by a phase shift of the voltages of the windings on the secondary side. The phase shift can be set so that they are practically the same, small current distortion factor leads like the well-known circuit, in which a secondary winding arrangement in a triangle and the other is connected in the star.

Advantageous refinements of the invention result from the dependent claims and the following description. In the Show drawing

Fig. 1 shows a power converter circuit for a transmitter,

FIG. 2a which a secondary-side winding arrangement,

FIG. 2b shows the corresponding voltage diagram,

Fig. 3a whose other secondary-side winding arrangement,

FIG. 3b shows the corresponding voltage diagram,

Fig. 4 shows a further embodiment of the converter circuit,

Fig. 5 is a development of the primary-side winding arrangement,

FIG. 6a, the primary side winding arrangement,

Fig. 6b shows the corresponding voltage diagram,

Fig. 7a, the primary-side winding arrangement of FIG. 6 with exchanged phases,

Fig. 7b redrawn the circuit of Fig. 7a and

Fig. 7c the corresponding voltage diagram.

According to Fig. 1 comprises a transformer (1) to a three-phase primary side winding arrangement (2) which is connected in a triangle. A three-phase winding arrangement ( 3 ) and a further three-phase winding arrangement ( 4 ) are provided on the secondary side. An iron core of the transformer ( 1 ) is labeled ( 5 ) and its screen is labeled ( 6 ).

Both secondary winding arrangements ( 3 , 4 ) are connected in a star. Effective shield capacities of the transformer ( 1 ) are between the star points ( 7 , 8 ) and the grounded shield ( 6 ) (CT 1 to CT 6 ). There are also cross capacities (CQ 1 to CQ 3 ).

A bridge rectifier ( 9 or 10 ) is connected downstream of each secondary winding arrangement ( 3 or 4 ). A sieve element ( 11 or 12 ) is connected to this. Each filter element ( 11 , 12 ) works with filter chokes (SL) and two filter capacitors (SC 1 , SC 2 ) connected in series. The star point ( 7 ) is located between the filter capacitors (SC 1 , SC 2 ) of the filter element ( 11 ). The star point ( 8 ) lies between the filter throttles (SC 1 and SC 2 ) of the filter element ( 12 ).

An electronic switch ( 13 or 14 ) for pulse duration modulation of the direct voltage is connected downstream of the filter elements ( 11 , 12 ). The switch ( 13 and 14 ) are each followed by a free-wheeling diode ( 15 ) and a low-pass filter ( 16 or 17 ), which in particular has a filter capacitor (FC). The filter condensation (FC) are in series. Parallel to them is a consumer ( 18 ), in particular a high-performance transmission component.

The converter circuit described thus forms a power amplifier for the transmission component ( 18 ) with a modular structure made up of the same modules ( 9 , 11 , 13 , 16 ) on the one hand and the modules ( 10 , 12 , 14 , 17 ) on the other. Each of the switches ( 13 , 14 ) only needs to be designed so that it switches half the nominal voltage of the transmitter component ( 18 ). If this is 30 kV, for example, it is sufficient to design the switches ( 13 , 14 ) to 15 kV.

The fact that both secondary winding arrangements ( 3 , 4 ) are connected in a star and their star points ( 7 , 8 ) are each between the filter capacitors (SC 1 , SC 2 ) result in the following advantages:

If one assumes that there is currently an AF voltage at the star point ( 7 ), but there is no AF voltage at the star point ( 8 ), then the shielding capacitances (CT 1 or CT 3 ) are parallel to the filter capacitor (SC 2 ) Sieve member ( 12 ). This is not a disadvantage since the shield capacities are significantly smaller than the capacitance of the filter capacitor (SC 2 ). The latter is a few hundred myF, whereas the shielding capacities are a few hundred pF. The shield capacities (CT 1 or CT 3 ) therefore do not interfere with switching operations.

The shielding capacitances (CT 4 to CT 6 ) or the transverse capacitances (CQ 1 to CQ 3 ) lie above the filter capacitor (SC 2 ) of the filter element ( 11 ) in parallel with the filter capacitor (FC) of the low-pass filter ( 17 ). As a result, they are integrated in the low-pass filter ( 17 ).

The same applies in the other operating cases.

The secondary-side winding arrangements ( 3 , 4 ) are arranged in a swivel-top circuit. Each of the three windings (U 1 , V 1 , W 1 or U 2 , V 2 , W 2 ) of the two secondary winding arrangements ( 3 , 4 ) has a partial winding (U 1 ', V 1 ', W 1 'or U 2 ', V 2 ', W 2 '), which are not on the iron core ( 5 ) of the associated winding (U 1 , V 1 , W 1 , U 2 , V 2 , W 2 ), but on the iron core adjacent winding is arranged. This is shown in Fig. 2a and Fig. 3a. The partial windings are each coupled to that primary winding of the primary-side winding arrangement ( 2 ) that is assigned to an adjacent secondary-side winding.

According to Fig. 2a, the winding (U 1 ') sits on the leg of the iron core ( 5 ) on which the winding (V 1 ) is arranged. The partial winding (V 1 ') is arranged on the same iron core leg as the winding (W 1 ). The partial winding (W 1 ') is arranged on the same iron core leg as the winding (U 1 ).

FIG. 2b shows the resulting voltammogram. The resulting stresses are denoted by (a 1 , a 2 , a 3 ). The voltage diagram shows a phase shift by the angle (c). This is preferably + 15 °.

According to Fig. 3a, the partial winding (U 2 ') of the winding (U 2 ) sits on the iron core leg of the winding (W 2 ). The partial winding (V 2 ') sits on the leg of the winding (U 2 ). The partial winding (W 2 ') sits on the leg of the winding (V 2 ). This results in the voltages (b 1 to b 3 ). The voltage diagram of FIG. 3b shows that a phase shift takes place characterized by the angle (d). This is preferably -15 °.

Overall, it follows that the output voltages of the secondary winding arrangements ( 3 , 4 ) are shifted by 30 ° with respect to one another. This phase shift essentially corresponds to the known case in which a delta connection is selected for one secondary-side winding arrangement and a star connection for the other secondary-side winding arrangement. It has been found that the winding arrangements of FIGS. 2a and 3a lead. To a current distortion of 15%. This current distortion factor is much better than the distortion factor that would occur if three pure star connections without a pivoting tip connection were used. Because this current distortion factor would be 29%. With regard to the harmonic load on the primary network, the circuit corresponds to a 12-pulse system.

If the load on each individual electronic switch ( 13 , 14 ) is to be further reduced, then a further pulse-duration-modulated electronic switch ( 19 or 20 ) with a free-wheeling diode ( 15 ) is connected downstream of each filter element ( 11 or 12 ) according to FIG. 4. Each of these switches is then assigned its own low-pass filter ( 21 , 22 ). All four filter capacitors (FC) are then in series. With a nominal voltage of 30 kV for the transmission component ( 18 ), it follows that each of the electronic switches ( 13 , 14 , 19 , 20 ) only has to be designed for 7.5 kV. For the rest, reference is made to FIG. 4 in the above statements.

In cases in which more than one transmitting component ( 18 ) is operated in the same station, that is to say on the same network, the pivoting tip arrangement described above for the secondary side can also be provided on the two or more primary-side winding arrangements ( 2 ) then provided. For the sake of simplicity, FIG. 5 shows only one of two primary-side winding arrangements ( 2 ). Each of the primary-side winding arrangements ( 2 ) is assigned two secondary-side winding arrangements ( 3 , 4 ). FIG. 6a shows a primary-side winding device (2). Fig. 7a and Fig. 7b show the other primary-side winding assembly (23). Both primary-side winding arrangements ( 2 , 23 ) are constructed identically for structural reasons. They differ in the connection of the phases (R, S, T). They are connected in a triangle.

According to Fig. 6a are on the phases (R, S, T) partial windings (Wz, Wx or Wy), at the winding ends of the voltage points (R ', S', T ') exist. The main winding (WH) lies between R ′ and T ′. The main winding (WL) lies between R 'and S'. The main winding (WM) lies between S 'and T'. This results in a phase shift between the resulting phase voltages and the voltages of the main windings by the angle (e), which is preferably + 7.5 °.

FIGS. 7a and 7b are located on the phases (R, S, T) partial windings (Wz, Wy, Wx). The main windings (WH, WM, WL) lie between R ', S' or S ', T' or T 'and R'. According to FIG. 7c, this results in a voltage diagram in which the resulting voltages between the phases (R, S, T) and the voltages on the main windings are phase-shifted by the angle (f). This angle is preferably -7.5 °.

The phase shift between the primary-side winding arrangements ( 2 , 23 ) by + 7.5 ° and -7.5 ° results in a total phase shift of 15 °. This further reduces the harmonic load on the network. It corresponds to a 24-pulse circuit.

In the case of the primary-side winding arrangements according to FIGS . 5 to 7, it is not absolutely necessary for the partial windings and the main windings to be built up individually. Tapping is sufficient.

In other exemplary embodiments, other phase shifts can also be carried out to get voted. For example, it is possible a total phase shift of 30 ° also due to phase shifts to reach 22.5 ° and 7.5 °.

Claims (5)

1. converter circuit, in particular for a high-power transmitter, wherein a three-phase, primary-side winding arrangement of a transformer is assigned at least two three-phase, secondary-side winding arrangements and each secondary-side winding arrangement is followed by a bridge rectifier with a filter element and the voltages of the two secondary-side winding arrangements are out of phase with one another, characterized in that both secondary-side winding arrangements ( 3 , 4 ) are connected in a star and that the secondary-side windings (U 1 , V 1 , W 1 , U 2 , V 2 , W 2 ) of one and / or the other winding arrangement ( 3 , 4 ) are partially coupled in each case to that primary winding of the primary-side winding arrangement ( 2 ) which is in itself assigned to the adjacent secondary-side winding. 2. Converter circuit according to claim 1, characterized in that the star points ( 7 , 8 ) of the secondary-side winding arrangements ( 3 , 4 ) between two series capacitors (SC 1 , SC 2 ) of the bridge rectifier ( 9 and 10 ) each connected downstream Sieve member ( 11 and 12 ) are placed. 3. Converter circuit according to claim 2, characterized in that the filter capacitor (SC 2 ) of the filter element ( 11 ) via a filter capacitor (FC) of a low-pass filter ( 17 ) is connected to ground. 4. Converter circuit according to one of the preceding claims, characterized in that the output voltage of one secondary-side winding arrangement ( 3 ) by + 15 ° and the output voltage of the other secondary-side winding arrangement ( 4 ) are phase-shifted by -15 °. 5. Converter circuit according to one of the preceding claims, characterized in that at least two primary-side winding arrangements ( 2 , 23 ) are provided, which are mutually out of phase.