DE102020208096A1 - Device and method for discharging an intermediate circuit capacitor and voltage converter arrangement - Google Patents

Abstract

The present invention relates to the discharging of an intermediate circuit capacitor by means of a half-bridge with two switching elements, which alternately charge and discharge two series-connected capacitors of a capacitor device by suitably controlling the switching elements.

Description

The present invention relates to a device and a method for discharging an intermediate circuit capacitor. The present invention also relates to a voltage converter arrangement with a device for discharging an intermediate circuit capacitor.

State of the art

Voltage networks with intermediate circuit capacitors for stabilizing a direct voltage are known, for example, from electrical drive systems. Since electrical voltages of several hundred volts can also be present on such intermediate circuit capacitors in high-voltage networks of electric vehicles, for example, in the event of a shutdown, especially in the event of an emergency shutdown, it must be ensured that the intermediate circuit capacitors can be discharged in a targeted manner.

The pamphlet DE 10 2012 201 827 A1 describes a device and a method for discharging an intermediate circuit of a high-voltage network. Here, two discharge circuits are provided, in a first step the intermediate circuit is initially partially discharged by means of the first discharge circuit and then in a second step the intermediate circuit is further discharged by means of a second discharge circuit.

Disclosure of the invention

The present invention creates a device and a method for discharging an intermediate circuit capacitor and a voltage converter arrangement having the features of the independent claims. Further advantageous embodiments are the subject of the dependent claims.

• Eine Vorrichtung zum Entladen eines Zwischenkreiskondensators mit einem Kondensatorelement und einer Halbbrücke. Das Kondensatorelement umfasst einen ersten Kondensator und einen zweiten Kondensator. Der erste Kondensator ist an einem ersten Anschluss mit einem ersten Anschluss des Zwischenkreiskondensators elektrisch verbunden. An einem zweiten Anschluss ist der erste Kondensator mit einem ersten Knotenpunkt elektrisch verbunden. Der zweite Kondensator ist an einem ersten Anschluss mit dem ersten Knotenpunkt elektrisch verbunden und an einem zweiten Anschluss mit einem zweiten Anschluss des Zwischenkreiskondensators elektrisch verbunden. Die erste Halbbrücke umfasst ein erstes Halbleiterschaltelement und ein zweites Halbleiterschaltelement. Das erste Halbleiterschaltelement ist an einem ersten Anschluss mit einem ersten Anschluss des Zwischenkreiskondensators elektrisch verbunden. An einem zweiten Anschluss ist das erste Halbleiterschaltelement mit einem zweiten Knotenpunkt elektrisch verbunden. Das zweite Halbleiterschaltelement ist an einem ersten Anschluss mit dem zweiten Knotenpunkt elektrisch verbunden und an einem zweiten Anschluss mit dem zweiten Anschluss des Zwischenkreiskondensators elektrisch verbunden. Ferner ist der erste Knotenpunkt des Kondensatorelements mit dem zweiten Knotenpunkt der Halbbrücke elektrisch gekoppelt.

Accordingly, it is provided:

• A device for discharging an intermediate circuit capacitor with a capacitor element and a half bridge. The capacitor element includes a first capacitor and a second capacitor. The first capacitor is electrically connected at a first connection to a first connection of the intermediate circuit capacitor. The first capacitor is electrically connected to a first node at a second connection. The second capacitor is electrically connected to the first node at a first connection and is electrically connected to a second connection of the intermediate circuit capacitor at a second connection. The first half bridge comprises a first semiconductor switching element and a second semiconductor switching element. The first semiconductor switching element is electrically connected at a first connection to a first connection of the intermediate circuit capacitor. The first semiconductor switching element is electrically connected to a second node at a second connection. The second semiconductor switching element is electrically connected to the second node at a first connection and is electrically connected to the second connection of the intermediate circuit capacitor at a second connection. Furthermore, the first node of the capacitor element is electrically coupled to the second node of the half bridge.

• Eine Spannungswandleranordnung mit einem Zwischenkreiskondensator, einer Spannungswandlerschaltung und einer erfindungsgemäßen Vorrichtung zum Entladen des Zwischenkreiskondensators. Die Spannungswandlerschaltung kann mindestens eine Halbbrücke, vorzugsweise jedoch mehrere Halbbrücken umfassen.

It is also provided:

• A voltage converter arrangement with an intermediate circuit capacitor, a voltage converter circuit and a device according to the invention for discharging the intermediate circuit capacitor. The voltage converter circuit can comprise at least one half bridge, but preferably several half bridges.

• Ein Verfahren zum Entladen eines Zwischenkreiskondensators mittels einer erfindungsgemäßen Vorrichtung zum Entladen des Zwischenkreiskondensators. Das Verfahren umfasst zwei Schritte, welche abwechselnd ausgeführt werden. In einem ersten Schritt wird das erste Halbleiterschaltelement der Halbbrücke geöffnet und das zweite Halbleiterschaltelement der Halbbrücke geschlossen. In einem zweiten Schritt wird das erste Halbleiterschaltelement der Halbbrücke geschlossen und das zweite Halbleiterschaltelement der Halbbrücke geöffnet.

Finally, it is planned:

• A method for discharging an intermediate circuit capacitor by means of a device according to the invention for discharging the intermediate circuit capacitor. The method comprises two steps which are carried out alternately. In a first step, the first semiconductor switching element of the half bridge is opened and the second semiconductor switching element of the half bridge is closed. In a second step, the first semiconductor switching element of the half bridge is closed and the second semiconductor switching element of the half bridge is opened.

Advantages of the invention

The present invention is based on the knowledge that electrical losses occur when a capacitor is charged and discharged. Here electrical energy is converted into thermal energy. It is now an idea of the present invention to use these electrical losses to reduce the electrical energy stored in an intermediate circuit capacitor by means of several charging and discharging processes of further capacitors. If at least two capacitors connected in series are alternately charged and discharged parallel to the intermediate circuit capacitor, the resulting electrical losses can dissipate the energy of the intermediate circuit capacitor without causing a short circuit across the two connections of the intermediate circuit capacitor.

Since the total capacitance resulting from the series connection of the additional capacitors is arranged in parallel to the intermediate circuit capacitor in operational operation, no negative effects occur during operational operation. Rather, the total capacitance resulting from the series connection of the two additional capacitors together with the capacitance of the intermediate circuit capacitor increases the total capacitance slightly. The capacities of the capacitors in the additional capacitor element can be dimensioned in a suitable manner such that the electrical currents flowing during the individual recharging processes can be safely controlled and at the same time the most efficient possible discharging of the intermediate circuit capacitance can be achieved.

For charging and discharging the individual capacitors in the capacitor element parallel to the intermediate circuit capacitor, a switching element, in particular a semiconductor switching element, such as a MOSFET or a bipolar transistor with an insulated gate connection or the like, is provided parallel to each capacitor. As will be explained in more detail below, the switching elements for recharging the individual capacitors can be arranged directly parallel to the respective capacitors. Alternatively, it is also possible to decouple the capacitors from the switching elements by means of an additional switch.

The reloading of the capacitors in the capacitor element can in principle take place with any switching frequency or clock rate. As the switching frequency increases, a larger amount of energy can be converted per unit of time, with the electrical losses also increasing per unit of time and thus a faster discharge of the intermediate circuit capacitance can be achieved. In particular, the switching frequency for discharging the intermediate circuit capacitor can be selected to be higher than a switching frequency that is used for the operational operation of an assembly to which the intermediate circuit capacitor is connected.

According to one embodiment, the device for discharging the intermediate circuit capacitor comprises a control device. The control device is designed to alternately set a first switching state or a second switching state in the half bridge. In the first switching state, the first semiconductor switching element is open and the second semiconductor switching element is closed. In the second switching state, the first semiconductor switching element is closed and the second semiconductor switching element is open. When changing between the first switching state and the second switching state, in particular the dead times of the semiconductor switching elements can also be taken into account. For this purpose, a closed semiconductor switching element is first opened and, after a dead time, the respective other switching element is closed. In this way it can be ensured that when changing between the two switching states via the half bridge, there is no short circuit across the intermediate circuit capacitor.

According to one embodiment, the first node point of the capacitor element is electrically connected directly to the second node point of the half bridge. Thus, no further components, in particular no switching element or the like, are provided between the first node and the second node. A particularly simple configuration can be implemented in this way.

According to an alternative embodiment, the device for discharging the intermediate circuit capacitor comprises a switching device. The switching device is designed to electrically connect or disconnect the first node of the capacitor element to the second node of the half-bridge. In particular, the first node can be electrically connected to the second node by means of the switching device for discharging the intermediate circuit capacitor. During operational operation of an assembly connected to the intermediate circuit capacitor, the switching device can disconnect the electrical connection between the first node and the second node. In this way, the capacitor device is separated from the half-bridge during operational operation, so that the capacitors of the capacitor device do not have any negative effects on operational operation and, in particular, also do not cause any additional electrical losses during operational operation.

According to one embodiment, the capacitor element comprises at least one ohmic resistor. The ohmic resistor is arranged in series with the first capacitor and the second capacitor. In particular, an ohmic resistor can be provided for each capacitor of the capacitor element. For example, a series connection of the first capacitor and a first ohmic resistor can be provided in the capacitor element between the first connection of the intermediate circuit capacitor and the first node, and a series connection of a second capacitor and a second can be provided between the second node and the second connection of the intermediate circuit capacitor Ohmic resistance can be provided. In this case, the capacitor element corresponds to an RC element, as it is for example is also used for so-called snubber circuits.

According to one embodiment of the voltage converter arrangement, the half-bridge of the device for discharging the intermediate circuit capacitor is provided in addition to the voltage converter circuit. Thus, in addition to the half-bridges of the voltage converter circuit, a further half-bridge for discharging the intermediate circuit capacitor is provided for the device for discharging the intermediate circuit capacitor.

According to a further embodiment, the half-bridge of the device for discharging the intermediate circuit capacitor can correspond to at least one half-bridge of the voltage converter circuit. In this way, the corresponding half-bridge of the voltage converter circuit can carry out the charge reversal of the capacitors in the capacitor element in order to discharge the intermediate circuit capacitor.

According to one embodiment, a capacitor element is arranged in parallel with each half bridge of the voltage converter circuit. Accordingly, each half bridge, together with the corresponding capacitor element, can form a device for discharging the intermediate circuit capacitor. By using several half bridges with capacitor elements arranged in parallel, the intermediate circuit capacitor can thus be discharged particularly quickly.

The above configurations and developments can be combined with one another as desired, as far as this makes sense. Further refinements, developments and implementations of the invention also include combinations, not explicitly mentioned, of features of the invention described above or below with regard to the exemplary embodiments. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic forms of the invention.

Figure list

• 1: eine schematische Darstellung eines Prinzipschaltbilds einer Spannungswandleranordnung mit einer Vorrichtung zum Entladen eines Zwischenkreiskondensators gemäß einer Ausführungsform;
• 2: eine schematische Darstellung eines Prinzipschaltbilds für eine Vorrichtung zum Entladen eines Zwischenkreiskondensators gemäß einer Ausführungsform;
• 3: eine schematische Darstellung eines Prinzipschaltbilds einer Vorrichtung zum Entladen eines Zwischenkreiskondensators gemäß einer weiteren Ausführungsform;
• 4: eine schematische Darstellung eines Prinzipschaltbilds einer Spannungswandleranordnung mit einer Vorrichtung zum Entladen eines Zwischenkreiskondensators gemäß einer weiteren Ausführungsform; und
• 5: eine schematische Darstellung eines Ablaufdiagramms, wie es einem Verfahren zum Entladen eines Zwischenkreiskondensators gemäß einer Ausführungsform zugrunde liegt.

Further features and advantages of the invention are explained below with reference to the figures. Show:

• 1 : a schematic representation of a basic circuit diagram of a voltage converter arrangement with a device for discharging an intermediate circuit capacitor according to one embodiment;
• 2 : a schematic representation of a basic circuit diagram for a device for discharging an intermediate circuit capacitor according to an embodiment;
• 3 : a schematic representation of a basic circuit diagram of a device for discharging an intermediate circuit capacitor according to a further embodiment;
• 4th : a schematic representation of a basic circuit diagram of a voltage converter arrangement with a device for discharging an intermediate circuit capacitor according to a further embodiment; and
• 5 : a schematic representation of a flow chart as a method for discharging an intermediate circuit capacitor according to an embodiment is based.

Description of embodiments

1 shows a schematic representation of a basic circuit diagram of a voltage converter arrangement with a device 1 for discharging an intermediate circuit capacitor 2 according to one embodiment. The voltage converter arrangement can be used, for example, to convert a DC voltage provided at an input connection into a suitable voltage for an electrical machine 4th head for. In addition, any other applications for a voltage converter arrangement are of course also possible.

The voltage converter arrangement comprises an intermediate circuit capacitor 2 , which is arranged between the connection elements of a DC voltage connection. The DC voltage provided at the DC voltage connection can be provided by a voltage converter circuit 3 can be converted into a further voltage, for example a direct or alternating voltage with a predetermined voltage level. In the embodiment shown here, the voltage converter circuit 3 For example, convert the DC voltage provided on the input side into a three-phase electrical AC voltage to the electrical machine 4th head for. The voltage converter circuit 3 For example, comprise a plurality of switching elements which are controlled with a predetermined clock frequency or a clock frequency within a predetermined frequency range.

In addition to the operational operation, for example, an operating state can be provided in which the input connection of the voltage converter arrangement and thus in particular the intermediate circuit capacitor 2 is separated from other components and in particular from a DC voltage source. For example, a battery circuit breaker, not shown, can be used for this purpose Disconnect the input connection of the voltage converter arrangement from other components. In this case the intermediate circuit capacitor is 2 but initially charged to a voltage level that corresponds to the electrical voltage at the input connection before disconnection. In such a case it may be necessary to replace the intermediate circuit capacitor 2 to discharge. The intermediate circuit capacitor 2 can either be completely discharged or the voltage across the intermediate circuit capacitor 2 can be lowered to at least a predetermined maximum voltage level. Such a discharge of the intermediate circuit capacitor 2 can for example by means of the device 1 for discharging the intermediate circuit capacitor 2 respectively.

The device 1 for discharging the intermediate circuit capacitor 2 can, as in 1 shown, for example, a capacitor element 10 and a half bridge 20th include. The capacitor element 10 comprises two capacitors arranged in series 11th , 12th . A first connection element of the first capacitor 11th of the capacitor element 10 is with a first connection of the intermediate circuit capacitor 2 electrically connected. A second connection element of the first capacitor 11th is with a first node K1 connected. A first connection element of the second capacitor 12th of the capacitor element 10 is also with the first node K1 connected. A second connection element of the second capacitor 12th is connected to a second connection of the intermediate circuit capacitor 2 connected. The half bridge 20th comprises two switching elements connected in series, in particular semiconductor switching elements 21 , 22nd . The semiconductor switching elements can be, for example, MOSFETs or bipolar transistors with an insulated gate connection (IGBT). Of course, any other switching elements, in particular any other semiconductor switching elements, are also possible. A first connection of the first switching element 21 the half bridge 20th is with the first connection of the intermediate circuit capacitor 2 electrically connected. A second connection element of the switching element 21 is with a second junction K2 connected. A first connection element of the second switching element 22nd the half bridge 20th is also with the second junction K2 electrically connected, and a second connection element of the second switching element 22nd is with the second connection element of the intermediate circuit capacitor 2 connected. Furthermore is the first junction K1 with the second junction K2 electrically connected. The electrical connection can, as in 1 shown, a direct electrical connection between the two nodes K1 and K2 provide. In this case, there are no further components, in particular no switching elements, between the first node K1 and the second node K2 intended. Alternatively, however, as will be explained below, it is also possible between the first node K1 and the second node K2 to provide a switching device.

The switching elements 21 , 22nd the half bridge 20th can for example from a control device 40 can be controlled. At the control device 40 it can be a control device which, if necessary, also controls the switching elements in the voltage converter circuit 3 drives. In principle, however, it is also possible to control the switching elements 21 , 22nd the half bridge 20th and controlling the switching elements in the voltage converter circuit 3 separate control devices to be provided.

The control device 40 can be used to discharge the intermediate circuit capacitor 2 the switching elements 21 and 22nd the half bridge 20th drive in a suitable manner. During the discharge of the intermediate circuit capacitor 2 can on the switching elements of the voltage converter circuit 3 a suitable configuration can be set in order, for example, to set a safe operating state. In such a safe operating state, it can be, for example, a freewheeling or an active short circuit of one at the output connection of the voltage converter 3 connected electrical machine 4th Act.

For discharging the intermediate circuit capacitor 2 can, for example, the upper switching element in a first switching state 21 the half bridge 20th are closed while the lower switching element 22nd the half bridge 20th is open. This way, the bottom capacitor will start first 12th via the upper switching element 21 charged. In addition, a second switching state can be set, in which the upper switching element is initially 21 the half bridge 20th is opened and then the lower switching element 22nd is closed. It then becomes the lower capacitor 12th discharging while the top capacitor 11th being charged. In the further course, the upper switching element 21 opened, and then the lower switching element 22nd be closed in order to set the first switching state again. For discharging the intermediate circuit capacitor 22nd the sequence described above can be repeated until the intermediate circuit capacitor 2 has been discharged to a desired voltage level.

2 shows a schematic representation of a basic circuit diagram of a device 1 for discharging an intermediate circuit capacitor 2 according to one embodiment. This embodiment according to 2 can also be used as a device 1 for discharging the intermediate circuit capacitor 2 in the voltage converter arrangement according to 1 can be used. The same also applies to the embodiment described below in accordance with 3 .

The device 1 for discharging the intermediate circuit capacitor 2 according to 2 differs from the embodiment according to 1 in that between the first node K1 and the second node K2 a switching device 30th is provided. This switching device 30th can, for example, two series-connected semiconductor switching elements 31 , 32 have, the freewheeling diodes of the two semiconductor switching elements 31 , 32 are arranged opposite. The switching device 30th can be open during normal operations, so the first node K1 electrically from the second node K2 is separated. For discharging the intermediate circuit capacitor 2 can the switching device 30th the first junction K1 with the second junction K2 connect electrically. For this purpose, for example, the two semiconductor switching elements 31 , 32 getting closed. It goes without saying, however, that instead of the two semiconductor switching elements 31 , 32 any other suitable switching elements can also be used. After closing the switching device 30th can by suitably controlling the switching elements 21 , 22nd the half bridge 20th the intermediate circuit capacitor 2 be discharged. In particular, that in connection with 1 principle already described can be applied.

3 shows a schematic representation of a basic circuit diagram of a device 1 for discharging an intermediate circuit capacitor 2 according to a further embodiment. The embodiment according to 3 differs from the embodiment described above in particular in that in the capacitor element 10 in addition to the two capacitors 11th and 12th at least one ohmic resistance 13th , 14th is provided. In the in 3 illustrated embodiment is in series with each capacitor 11th , 12th one ohmic resistance each 13th , 14th intended. Thus there is between the first connection element of the intermediate circuit capacitor 2 and the first node K1 a series circuit of a first ohmic resistor 13th and a first capacitor 11th intended. The same is true between the first junction K1 and the second connection element of the intermediate circuit capacitor 2 a series circuit of a second ohmic resistor 14th and the second capacitor 12th intended. Thus, the two form capacitors 11th , 12th of the capacitor element 10 together with the ohmic resistor (s) 13th , 14th an RC element, which can also be used as a filter element for interference frequencies in operations. In addition, the ohmic resistances lead 13th , 14th in the capacitor element 10 to further ohmic losses and thus to the conversion of electrical energy into thermal energy. In this case, too, it may be possible between the first node K1 and the node K2 a switching element 30th be provided.

4th shows a schematic representation of a basic circuit diagram of a voltage converter arrangement according to a further embodiment. The embodiment according to 4th differs from the embodiment described above in particular in that as a half-bridge 20th for the device 1 for discharging the intermediate circuit capacitor 2 a half bridge of the voltage converter circuit 3 is used. Thus, a separate external half-bridge can be used 20th omitted. To avoid excessive switching losses, the capacitor device 10 , especially the first junction K1 the capacitor device 10 from the corresponding half bridge, in particular the second junction K2 , by means of a switching device already described above 30th electrically separated. For discharging the intermediate circuit capacitor 2 can then this switching device 30th the first junction K1 with the second junction K2 electrically connect, so that thereupon according to the sequence described above by appropriate control of the switching elements 21 , 22nd the intermediate circuit capacitor 2 can be discharged.

In the in 4th illustrated embodiment is only a capacitor device 10 for a half bridge in the voltage converter circuit 3 shown. In addition, it is also possible for several half bridges in the voltage converter circuit 3 , especially for all half bridges in the voltage converter circuit 3 , each with a separate capacitor device 11th to be provided. In this way, each half bridge of the voltage converter circuit 3 together with the corresponding capacitor device 10 one device each 1 for discharging the intermediate circuit capacitor 2 form.

5 shows a schematic representation of a flow chart of a method for discharging an intermediate circuit capacitor 2 according to one embodiment. The method can in particular be applied to one of the above-described embodiments of the device 1 for discharging an intermediate circuit capacitor 2 be applied.

The process is used to discharge the intermediate circuit capacitor 2 alternately two switching states are set. In step S1 becomes the second switching element 22nd the half bridge 20th closed and the first switching element 21 the half bridge 20th open. A second switching state is then set in which the second switching element is initially 22nd is opened and then, preferably in compliance with a predetermined Dead time of the switching elements, the first switching element connection element 21 is opened. Later in step S2 by opening the first switching element 21 and then closing the second switching element 22nd the first switching state can be set again. The two switching states described above can now be set alternately until the intermediate circuit capacitor 2 has been discharged to a predetermined minimum voltage level.

In summary, the present invention relates to the discharging of an intermediate circuit capacitor by means of a half bridge with two switching elements, which alternately charge and discharge two series-connected capacitors of a capacitor device by suitably controlling the switching elements.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102012201827 A1 [0003]

Claims (10)

Device (1) for discharging an intermediate circuit capacitor (2), with: a capacitor element (10) with a first capacitor (11) and a second capacitor (12), wherein the first capacitor (11) is electrically connected at a first connection to a first connection of the intermediate circuit capacitor (2) and at a second connection to a first node (K1) is electrically connected, and wherein the second capacitor (12) is electrically connected at a first connection to the first node (K1) and is electrically connected to a second connection of the intermediate circuit capacitor (2) at a second connection; and a half bridge (20) with a first semiconductor switching element (21) and a second semiconductor switching element (22), the first semiconductor switching element (21) being electrically connected at a first connection to the first connection of the intermediate circuit capacitor (2) and at a second connection to a second node (K2) is electrically connected, and wherein the second semiconductor switching element (22) is electrically connected to the second node (K2) at a first connection and is electrically connected to the second connection of the intermediate circuit capacitor (2) at a second connection; wherein the first node (K1) of the capacitor element (10) is electrically coupled to the second node (K2) of the half bridge (20). Device (1) according to Claim 1 with a control device (40) which is designed to alternately set a first switching state or a second switching state in the half-bridge (20), the first semiconductor switching element (21) being open and the second semiconductor switching element (22) being closed in the first switching state is, and wherein in the second switching state the first semiconductor switching element (21) is closed and the second semiconductor switching element (22) is open. Device (1) according to Claim 1 or 2 , wherein the first node (K1) of the capacitor element (10) is electrically connected directly to the second node (K2) of the half bridge (20). Device (1) according to Claim 1 or 2 with a switching device (30) which is designed to electrically connect the first node (K1) of the capacitor element (10) to the second node (K2) of the half-bridge (20). Device (1) according to one of the Claims 1 until 4th wherein the capacitor element (10) comprises at least one ohmic resistor (13, 14) which is arranged in series with the first capacitor (11) and the second capacitor (12). Voltage converter arrangement, comprising: an intermediate circuit capacitor (2), a voltage converter circuit (3) with several half bridges; and a device (1) for discharging the intermediate circuit capacitor (2) to one of the Claims 1 until 5 . Voltage transformer arrangement according to Claim 6 , wherein the voltage converter circuit (3) comprises the half bridge (20) of the device (1) for discharging the intermediate circuit capacitor (2). Voltage transformer arrangement according to Claim 6 , wherein a capacitor element (10) is arranged parallel to each half-bridge of the voltage converter circuit (3), and each half-bridge together with the respective corresponding capacitor element (10) forms a device (1) for discharging the intermediate circuit capacitor (2). Voltage transformer arrangement according to Claim 6 wherein the half bridge (20) of the device (1) for discharging the intermediate circuit capacitor is arranged parallel to the half bridges of the voltage converter circuit (3). Method for discharging an intermediate circuit capacitor (2) by means of a device according to Claim 1 , the method alternately opening the first semiconductor switching element (21) and closing the second semiconductor switching element (22) in a first step (S1), and closing the first semiconductor switching element (a 20) and opening the second semiconductor switching element (22) in a second step.

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