EP3881410A1 - Magnetically controllable inductor coil in a series circuit - Google Patents

Abstract

The invention relates to a device (1) for dynamic load-flow control in a high-voltage network (17), which has at least one phase conductor (16) and at least one first high-voltage terminal (42), each first high-voltage terminal being designed to be connected to one phase conductor (16). For each first high-voltage terminal (42), a first and a second core portion (5, 6), which are part of a closed magnetic circuit, a first high-voltage winding (5), which surrounds the first core portion (3), and a second high-voltage winding (6), which surrounds the second core portion (4) and is connected in parallel with the first high-voltage winding (5), are provided. The core portions and the windings are located in a tank filled with ester fluids. Furthermore, the device according to the invention has at least one saturation switching branch (10, 11), which is arranged outside of the tank, is designed to saturate the core portions (3, 4) and has controllable power semiconductor switches (20, 21, 22, 23). A control unit is used to control the power semiconductor switches, the first and the second high-voltage winding being connected at their high-voltage end (7) to the associated first high-voltage terminal (42) and being connectable at their low-voltage side (9) to one or the saturation switching branch (10, 11). The device (1) according to the invention can be connected in series into the high-voltage network (17), the saturation switching branches (10, 11) being installed in such a way that the saturation switching branches are electrically insulated from the ground potential.

Description

description

Magnetically adjustable choke coil in series connection

The invention relates to a device for reactive power compensation in at least one phase conductor having high-voltage network with at least one first high-voltage connection, which is set up for connection to a respective phase conductor, wherein for each first high-voltage connection, a first and a second core section, which are part of a are closed magnetic circuit and are arranged in a tank, a first high-voltage winding, which encloses the first core section, and a second high-voltage winding, which encloses the second core section and is connected in parallel to the first high-voltage winding, we at least one saturation switching branch, which is set up to saturate the core sections is and has controllable power semiconductor switches, and a control unit for controlling the power semiconductor switches are provided, wherein the first and the second high-voltage winding are connected to the first high-voltage connection and can be connected to one or the saturation switching branch.

Such a device is already known from EP 3 168 708 A1. There, a so-called “full variable shunt reactor” (FVSR) is disclosed. The previously known device has two mutually parallel high-voltage windings per phase, each of which encloses a core leg of a closed iron core and at its high-voltage end to a phase conductor of a high-voltage network The low-voltage sides of the high-voltage windings can be connected with the aid of a transistor switch either to an appropriately polarized converter or directly to an earth connection. The converter is set up to generate a direct current in the high-voltage winding connected to it. The direct current is set in such a way that the core leg enclosed by the winding is driven into a desired state of saturation. The state of the core material, for example, has a very low magnetic permeability, which increases the magnetic resistance of the winding and lowers its inductance. The saturation of said core sections is polarization-dependent, so that an alternating current flowing over the windings, depending on its polarization, essentially only flows over one of the two high-voltage windings. For example, a positive alternating current flows through the first high-voltage winding, while a negative alternating current flows down to earth via the second high-voltage winding. If the current is only driven via a high-voltage winding, the other winding, which is not currently being flowed through by the alternating current, can be subjected to a direct current in order to saturate the core leg enclosed by it to the desired extent.

The known device has the disadvantage that it can only be connected in parallel with the phase conductor or conductors of the supply network. In the case of a device connected in parallel, its one side is connected to the high-voltage potential of the phase conductor, the side facing away from the high-voltage connection being at ground potential.

The object of the invention is to provide a device of the type mentioned at the beginning, which can be connected in series to the high-voltage network and which is also inexpensive.

The invention solves this problem by a second high-voltage connection, which is also provided for connection to the said phase conductor and is connected via one or each saturation switching branch or directly to the high-voltage winding, each saturation branch being arranged outside the tank and electrically isolated from earth potential is set up.

In the context of the invention, the second connection is a high voltage connection. This second high voltage connection is also provided for connection to the phase conductor, so that the entire device is connected in series in the respective phase conductor. The saturation switching branch can be connected directly to the second high-voltage connection in the context of the invention, that is to say - with the exception of implementations - without the interposition of further components or parts. As an alternative to this, however, it is also possible within the scope of the invention to arrange further components in the current path between the saturation switching branch and the second high-voltage connection.

The or the saturation switching branch is set up isolated in the context of the inven tion outside the tank and, for example, arranged on a high-voltage platform, the saturation branches with their power semiconductor switches and power electronics during operation can be at a high-voltage potential. This facilitates the connection to the high-voltage windings in the tank. Voltage drops occur, for example in the medium voltage range from 1 kV to 50 kV, between the components arranged on the high-voltage platform. These medium-voltage drops are, however, less expensive to handle than high-voltage drops of generally 100 kV to 800 kV, the components used for this purpose being known from medium-voltage technology. On the high-voltage platform, other components, for example capacitive construction parts and the like, can be arranged as part of the invention.

According to a first variant of the invention, the first and second high-voltage windings are connected to the first high-voltage connection. Additional parts or components can be assigned between the first high-voltage connection and the high-voltage windings.

However, no saturation branch is arranged between the second high-voltage connection and the high-voltage windings. Because each high-voltage winding is arranged in a tank filled with an insulating fluid and each saturation switching branch outside the tank, the tank with its inductive components and the power electronic components of the saturation switching branch can be manufactured and transported independently of one another. In addition to the tank at ground potential, the inductive components include the high-voltage windings which are at a high-voltage potential during operation and which are arranged in the tank. The liquid or gaseous insulating fluid is used for insulation and cooling, and is also used for cooling the high-voltage windings. According to this variant, it is no longer necessary to set up or isolate the power electronics of the isolated saturation branch in a high-voltage-resistant manner. On the high-voltage platform, the electrical potentials of the components arranged there differ only in the range from 1 to 52 kV. The said components can therefore be placed closer together than at higher voltages. This leads to a more compact device and reduced costs.

Each saturation switching branch is advantageously arranged on an electrically insulated high-voltage platform.

In these variants, it is also advantageous if each saturation switching branch is connected via at least one high-voltage bushing to the one or more high-voltage windings. The high-voltage bushings enable the connection of the respective saturation switching branch to the components of the device which are arranged in the tank.

A mineral oil, an ester oil or the like can be considered as the insulating fluid. Different insulating fluids can be provided in different tanks. However, the insulating fluid is preferably the same in all tanks. Deviating from this, the insulating fluid can also be designed as a protective gas. There are several tanks, for example Required if a tank is provided for each phase of the high-voltage network.

Advantageously, at least one high-voltage winding has a center connection via which said high-voltage winding is connected to one or the one saturation branch. The winding ends of the high-voltage windings are connected to the first or second high-voltage connection.

According to a further development expedient in this regard, each high-voltage winding has a center connection which is connected to one or the saturation switching branch.

Each saturation switching branch preferably has at least one two-pole submodule with a bridge circuit, which has power semiconductor switches and a DC voltage source, so that, depending on the control of the power semiconductor switches, the DC voltage source can either be connected in series to at least one high-voltage winding or can be bridged. The DC voltage source then provides the necessary voltages and DC currents for saturating the core of the high-voltage windings when the power semiconductor switches are appropriately controlled.

Each submodule is preferably formed as a full bridge circuit, which has a first series circuit branch and a second series circuit branch, each of which is connected in parallel to the DC voltage source. Each series circuit branch has a series connection of two power semiconductor switches, the potential point between the power semiconductor switches of the first series circuit branch being connected to a first connection terminal of the submodule and the potential point between the power semiconductor switches of the second series connection branch being connected to the second connection terminal of the submodule. Full-bridge circuits enable polarization reversal at the connection terminals, which are device that only has a parallel branch with two power semiconductor switches is not possible.

Each power semiconductor switch is preferably an IGBT with a freewheeling diode connected in opposite directions in parallel, a so-called GTO or a transistor switch. It is advantageous in the context of the invention that each power semiconductor switch can be transferred both from its interruption position, in which current cannot flow through the power semiconductor switch, to its open position or vice versa, in which it is possible to flow through the power semiconductor switch. Such power semiconductor switches are also called switchable power semiconductor switches, which can even interrupt a short-circuit current flowing through them, if suitable measures have been taken to reduce the resulting energy.

Each DC voltage source is preferably an energy store. Electrical energy stores, which are preferably unipolar, are advantageously considered as energy stores. For example, capacitors, supercapacitors, superconducting coils, battery accumulators, supercaps or the like come into consideration as energy stores. The enumerated or other energy storage devices can appear individually in a submodule or several of them are connected in series. This series connection is referred to in the context of the present invention with the term “energy storage” overall.

The energy store is expediently connected to a charging unit for charging the energy store. The energy store can preferably be connected to a supply network. This is expediently carried out via a loading unit, which can basically be configured in any way within the scope of the invention. It is essential, however, that energy can be drawn from the supply network via the charging unit and stored in the energy store. This energy then enables Current flow to saturate the respective high-voltage winding.

Additional windings are expediently provided, which are inductively coupled to the high-voltage windings, the additional windings being connected to at least one capacitively acting component. The additional windings are inductively coupled within the scope of the invention with at least one of the high-voltage windings of the FVSR. The additional windings are connected to a capacitive component. The term “connected” means that each capacitively acting component is connected galvanically either directly or via an electrical component, such as a switching unit, to at least one of the additional windings. The capacitive component, for example a capacitor or a “flexible AC equipped with capacitors Transmission system "(FACTS) components, such as a" Static Synchronous Compensator "(STATCOM), can thus influence the degree and direction of reactive power compensation.

The FVSR is primarily used for load flow control, current limitation or dynamic filtering.

The capacitive component expediently has a capacitor or a capacitor bank.

Further expedient embodiments and advantages of the inven tion are the subject of the following description of exemplary embodiments of the invention with reference to the figures of the drawing, the same reference numerals referring to components having the same effect and wherein

Figure 1 shows an embodiment of the invention

Device in a schematic representation,

FIG. 2 shows the saturation switching branches of the device according to FIG. 1, Figure 3 shows another embodiment of the inventions

device according to the invention,

Figure 4 shows another embodiment of the inventions

device according to the invention with raised saturation switching branches,

Figure 5 shows another embodiment of the inventions

Invention device and

Figure 6 show yet another embodiment of the inventive device.

Figure 1 shows an embodiment of the device 1 according to the invention, which has a tank 2 filled with an insulating fluid. Mineral oils, but also ester liquids or the like can be considered as the insulating fluid. Gaseous insulating fluids are also possible within the scope of the invention.

The insulating fluid provides the necessary voltage strength for components of the device 1, which are at a high voltage potential, compared to the tank 2, which is at ground potential. In addition, the insulating fluid is used to cool the components that develop heat during operation. In the embodiment shown in Figure 1, the tank is filled with an ester liquid.

A core is arranged inside the tank 2 and consists of a magnetizable material, preferably a ferromagnetic material such as iron. In order to avoid eddy currents, the core is made up of sheet metal sheets that lie flat against one another. The core forms a first core leg 3 and a second core leg 4 as core sections.

The first core leg 3 is enclosed by a first high-voltage winding 5. The second core leg 4 is from egg ner second high-voltage winding 6 surrounded. To form a closed magnetic or iron circuit, the yokes not shown in figur Lich, which extend from the upper end of the core leg 3 to the upper end of the core leg 4 and from the lower end of the core leg 3 to the lower end of the core leg 4. In addition, two figuratively also not shown return legs hen hen, which are not surrounded by a winding and extend right and left parallel to the core legs 3 and 4, respectively. In other words, a so-called 2/2 core is provided.

The first high-voltage winding 5 and the second high-voltage winding 6 each have a winding end 7, with which they are connected to a high-voltage bushing 8, with which the connection cables, which are in operation during operation at a high-voltage potential, are guided through the wall of the tank 2, which is at ground potential.

The high-voltage bushing 8 extends through the wall of the tank 2 and is equipped at its free outside of the tank 2 at an ordered end with an outdoor connection. The outdoor connection, not shown in the figures, serves to connect an air-insulated conductor 40, via which the high-voltage windings 5 and 6 are connected to a first high-voltage connection 42, via which the entire device 1 can be connected to a phase conductor 16 of a high-voltage supply network. For every other phase conductor of the high-voltage network, which are not shown here for reasons of clarity, the device 1 has an identical structure to that shown in FIG. These components are also not shown for reasons of clarity. Of course, cable connections are also possible within the framework of the invention.

At their En 9 facing away from the first high-voltage terminal 42, the first high-voltage winding 5 and the second high-voltage winding 6 are each with an outside of the tank 2 arranged saturation switching branch 10 or 11 connected, each saturation switching branch 10, 11 having a two-pole submodule 12, which is connected with a first terminal 13 to the respective high-voltage winding 5 or 6 respectively. The submodules 12 are connected to the second high-voltage connection 44 via their second connection terminal 14. A bushing 8 again serves to lead the connecting line between the high-voltage winding 5, 6 and saturation switching branch 10, 11 through the wall of the tank 2. In the exemplary embodiment shown, the second high-voltage connection 44 is also connected to the phase conductor 16. In other words, the device 1 according to the invention shown is connected in series in the supply network with the phase conductor 16.

It is essential in the context of the invention that each saturation switching branch 10 or 11 has a two-pole submodule 12, which has a bridge circuit of power semiconductor switches 20, 21, 22 and 23 and a DC voltage source 24, which is preferably unipolar and thus designed has a fixed plus and a minus pole. The saturation switching branches 10, 11 are set up insulated from the earth potential. Appropriate insulating components, such as Supporters or the like.

The bridge circuit can be a half bridge or a full bridge within the scope of the invention. In FIG. 1, each submodule has a full bridge and comprises four power semiconductor switches 20, 21, 22 and 23. A half bridge only comprises two of the power semiconductor switches. For the appropriate control of the four power semiconductor switches 20, 21, 22 and 23, a control unit 26 is provided which can be supplied on the input side with setpoints for the voltage UACS _O II, the alternating current IACS _O II and the reactive power QACS _O II. A current sensor 27 is used to detect the alternating current IAC flowing from the phase conductor 16 to the high-voltage windings, a voltage sensor 28 detecting the high-voltage voltage drop on the voltage side of the high-voltage windings 5 and 6 is detected. The current sensor 27 and the voltage sensor

28 are connected to the control unit 26 via signal lines, not shown in the figures. At the other end of the high voltage winding 5 and 6 are also sensors

29 and 30 can be seen, which are likewise connected to the control unit 26 via signal lines and detect currents which flow between the respective submodule 12 and the respective high-voltage winding 5 and 6, respectively. The power semiconductor switches 20, 21, 22 and 23 of a submodule 12 can by appropriate control signals, which are shown by dashed lines, by the control unit 26 from a disconnected position in which a current flow through the power semiconductor switch is interrupted, in a through position, in which a current flow is possible via the power semiconductor switch or vice versa from the through position to the disconnected position.

The operation of the device 1 is as follows: If the voltage detected by the voltage sensor 28 is positive, the power semiconductor switches 22 and 23 of the saturation switching branch 10 are closed. It should be assumed that the core leg 3 was saturated beforehand by a direct current flowing from the submodule 12 of the first saturation switching branch 10 to the high-voltage winding 5, so that for the positive half-wave of the alternating voltage the alternating resistance of the high-voltage winding 5 was smaller than the alternating resistance of the high-voltage winding 6. Thus, almost the entire alternating current I _{AC flows} via the current path denoted Ii to the second high-voltage connection 44. In the positive half-wave of the AC voltage, the power semiconductor switches 21 and 22 are therefore closed, so that the DC voltage source 24 of the saturation circuit 11 drives a DC current that flows from the high-voltage winding 6 to the second high-voltage connection 44. During the po sitive half-wave of the AC voltage in the phase conductor 16, the second core leg can thus be saturated in the desired manner. In contrast, during the negative half-wave, in which the voltage measured by the sensor 28 is negative, an alternating current I _AC flows essentially via the second high-voltage winding 6, so that by closing the power semiconductor switches 20 and 23 and opening the power semiconductor switches 21 and 22 Submodule 12 of the first saturation switching branch 10, a direct saturation current is generated by the submodule

12 flows to the first high-voltage winding 5 or vice versa and thus ensures the desired saturation of the core leg 3.

FIG. 2 shows the structure of the submodules 12 of the first and second saturation circuits 10, 11 in more detail. It can be seen that the submodules for both saturation switching branches 10 and 11 are constructed identically. It can also be seen that the power semiconductor switches 20, 21, 22 and 23 comprise a so-called IGBT 31, to which a free-wheeling diode 32 is connected in parallel in opposite directions. The structure of an IGBT with a freewheeling diode is known in principle, so that its mode of operation need not be discussed in more detail here. It is essential that the freewheeling diode 32 serves to protect the IGBTs from voltages in the reverse direction. IGBT 31 and diodes 32 are housed in a common switch housing. IGBT 31 and freewheeling diode 32 are collectively referred to here as power semiconductor switches.

Each submodule 12 is designed as a so-called full bridge and comprises a first series circuit branch 32 and a second series circuit branch 34, each consisting of two power semiconductor switches 20, 21 or 22 and 23 connected in series. The potential point between power semiconductor switches 20 and 21 is with the first connection terminal

13 and the potential point between the power semiconductor switches 22 and 23 of the second series circuit branch 34 connected to the connecting terminal 14 of the submodule 12. FIG. 3 shows a further exemplary embodiment of the device 1 according to the invention, which partially corresponds to the exemplary embodiment shown in connection with FIG. 1. In addition to the components or elements already described in FIG. 1, the exemplary embodiment of the device 1 shown in FIG. 7 also has a capacitive component, which in the exemplary embodiment shown is designed as a capacitor 35. The capacitor 35 is connected to a compensation winding 36 in parallel, the compensation winding 36 consisting of two partial compensation windings 37 and 38 which are connected to one another in series. The partial compensation winding 37 is inductively coupled to the first high-voltage winding and the second partial compensation winding 38 to the high-voltage winding 6. The high-voltage windings 5 and 6 and the respective partial compensation winding 37 and 38 are arranged concentrically to one another, with the same core section 3 or 4 of the otherwise not further illustrated core being closed. In Figure 3, only an additional winding 36 is illustrated for the phase shown there. In the tank 2, however, further compensation windings are provided for the other phases, which are constructed identically and are connected to the capacitor 35 in the same way. The compensation windings 36 of the different phases are connected to one another in a delta connection. This triangular circuit is indicated by arrows 39a and 39b. In the parallel branch of the compensation winding, in which the capacitor 35 is arranged, a scarf ter 49 is also shown schematically, which comprises two oppositely connected thyristors in the exemplary embodiment shown. With the help of the electronic switch 49, the capacitor 35 of the compensating winding 36 can be switched in parallel or the effect of the capacitively acting construction part 35 can be suppressed.

The condenser 35 is shown in FIG. 3 as a single condenser, which is arranged outside the tank 2 of the FVSR. However, the capacitor 35 comprises a number of in Series or parallel arranged capacitors and can therefore also be referred to as a capacitor bank. The number of capacitors connected in parallel or in series depends on the respective requirements, where the capacitive effect can be increased or decreased.

The capacitor or, in other words, the capacitor bank 35, like the switch 49, is arranged outside the tank 2 of the FVSR. Deviating from this, the arrangement in a common tank is of course also possible. In order to enable an electrical connection between the compensating winding 36 in the tank 2, appropriate bushings 8 are again seen before, which enable a voltage-proof implementation of the high-voltage lines through the wall of the tank 2, which lies on earth potential.

FIG. 4 shows a further exemplary embodiment of the device 1 according to the invention, which has a first high-voltage connection 42 for connecting the phase conductor 16 and a second high-voltage connection 44, which is also provided for connecting the phase conductor 16. The Vorrich device is thus switched back in series in the phase conductor 16 ge. As shown in Figures 1 and 3 execution examples, the saturation branches 10 and 11 are arranged outside of the tank 2. To connect the saturation branches with the arranged in the tank 2 high-voltage windings 5 and 6 in turn serve Hochspannungsdurchführungsun conditions 8, which reach through the wall of the tank 2, where the necessary dielectric strength against the tank 2 provides earth potential at an outer insulator.

The saturation switching branches 10, 11 are arranged on a high voltage platform 50, which has a planar support structure 51 and two externally ribbed supports made of egg nem non-conductive material. The supports 52 are firmly anchored in the ground at one end and are fixedly connected to the support plate 51 with their end facing away from the ground. In Figures 4, 5 and 6, two supporters 52 are recognizable. At this point, however, it is pointed out that further supports (not shown in the figures) for carrying the support structure 51 are possible. With the help of the insulators or supporters 52, it is possible for the saturation switching branches 10 and 11 to be at a high voltage potential.

This therefore applies to the power electronics of the power semiconductor switches. Complex electrical isolation has become superfluous.

FIG. 5 shows a further exemplary embodiment of the device according to the invention, which differs from the exemplary embodiment shown in FIG. 4 in that the second high-voltage connection 44 is not connected directly to the saturation switching branches 10, 11 via a star point.

Rather, the second high-voltage connection 44 is connected via a bushing 8 directly to the high-voltage winding ends 9 arranged in the tank 2. The high-voltage windings 5 and 6 each have a center connection 53, which serves to connect the saturation switching branches 10 and 11 arranged on the platform 50. The saturation switching branches 10 and 11 are connected to one another via an expedient circuit 54.

FIG. 6 shows a further exemplary embodiment of the device according to the invention, which differs from the exemplary embodiment shown in FIG. 5 in that only one saturation switching branch is arranged on the high-voltage platform 50, which is connected to both high-voltage windings 5, 6, suitable switches being provided to bring about the desired saturation of the core sections 3 and 4.

Claims

Claims

1. Device (1) for dynamic load flow control in a high-voltage network (17) having at least one phase conductor (16) with at least one first high-voltage connection (42), which is set up for connection to a phase conductor (16), wherein for every first high voltage connection (42)

- A first and a second core section (5,6), which are part of a closed magnetic circuit and are arranged in a tank,

- A first high-voltage winding (5) which surrounds the first core section (3), and

a second high-voltage winding (6), which surrounds the second core section (4) and is connected in parallel to the first high-voltage winding (5),

- At least one saturation switching branch (10, 11) which is set up to saturate the core sections (3, 4) and has controllable power semiconductor switches (20, 21, 22, 23), and

a control unit for controlling the power semiconductor switches is provided,

the first and the second high-voltage winding being connected to the first high-voltage connection and being connectable to one or the saturation switching branch (10, 11), g e k e n e z e i c h n e t d u r c h,

a second high-voltage connection (44), which is also provided for connection to the said phase conductor (16) and is connected via one or each saturation switching branch (10, 11) or directly to the high-voltage cables (5, 6), each of which Saturation branch (10, 11) is arranged outside the tank (2) and is set up electrically insulated from earth potential.

2. Device (1) according to claim 1,

d a d u r c h g e k e n n z e i c h n e t that

each saturation switching branch (10, 11) is arranged on a high-voltage platform (50), the one by means of electrical isolating support columns (51) supported on the ground support structure (52).

3. Device (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that

each saturation switching branch (10, 11) is connected to the high-voltage winding (s) (5, 6) via at least one high-voltage bushing (8) installed on the tank (2).

4. Device (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that

at least one high-voltage winding (5, 6) has a center connection (53) via which the respective high-voltage winding (5, 6) is connected to a saturation branch (10, 11), the winding ends (7, 9) of the respective high-voltage winding (5, 6) are connected to the first (42) or two-th high-voltage connection (44).

5. The device (1) according to claim 4,

d a d u r c h g e k e n n z e i c h n e t that

each high-voltage winding (5, 6) has a center connection (53) which is connected to one or the saturation switching branch

(10,11) is connected.

6. Device (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that

each saturation switching branch (10, 11) has at least one two-pole submodule (12) with a bridge circuit, which has power semiconductor switches (20, 21, 22, 23) and one

DC voltage source (24), so that depending on the control of the power semiconductor switch (20,21,22,23)

DC voltage source can either be connected in series to at least one high-voltage winding (10, 11) or can be bridged.

7. The device (1) according to claim 6,

characterized in that each submodule (12) forms a full-bridge circuit, which has a first series circuit branch (33) and a second series circuit branch (34), each of which is connected in parallel to the direct voltage source (24), each series circuit branch (33, 34) a series connection comprises two power semiconductor switches (20, 21, 22, 23), the potential point between the power semiconductor switches (20, 21) of the first series circuit branch (33) with a first terminal (13) of the submodule (12) and the potential point is connected between the power semiconductor switches (22, 23) of the second series circuit branch (34) with the second connection terminal (14) of the submodule (12).

8. The device (1) according to claim 6 or 7,

d a d u r c h g e k e n n z e i c h n e t that

each power semiconductor switch (20, 21, 22, 23) is an IGBT (31) with a freewheeling diode (32) connected in parallel in opposite directions, is a GTO or a transistor switch.

9. The device (1) according to one of claims 6 to 8,

d a d u r c h g e k e n n z e i c h n e t that

each DC voltage source (24) comprises an energy store.

10. The device (1) according to claim 9,

d a d u r c h g e k e n n z e i c h n e t that

the energy store can be connected to a supply network.

11. The device (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that

Compensating windings (35) are provided which are inductively coupled to the high-voltage windings (5, 6), the compensating windings (36) being connected to at least one capacitive component (35).

12. The device (1) according to claim 11,

d a d u r c h g e k e n n z e i c h n e t that

the capacitively acting component has capacitors (46).