WO2021224080A1 - Circuit assembly for linking networks with different nominal voltages via dc-dc converters - Google Patents

Abstract

The invention relates to a circuit assembly (S) for linking networks with different nominal voltages via DC-DC converters (DC/DC_a, DC/DC_b), comprising: a connector (A1) for a first sub-network (BN48-1) with a first nominal voltage; a connector (A2) for a first sub-network (BN12-1) with a second nominal voltage; a first connection between the first input and output (1.1) of a first DC-DC converter (DC/DC_a) and the connector (A1) for the first sub-network (BN48-1) with the first nominal voltage, which is guided via a first node (K1); a second connection between the second input and output (1.2) of the first DC-DC converter (DC/DC_a) and the connector (A2) for the first sub-network (BN12-1) with the second nominal voltage, which is guided via a second node (K2); a third connection between the first input and output (2.1) of a second DC-DC converter and the connector (A3) for the second sub-network (BN48-2) with the first nominal voltage, which is guided via a third node (K3); and a fourth connection between the second input and output (2.2) of the second DC-DC converter and the connector (A4) for the second sub-network (BN12-2) with the second nominal voltage, which is guided via a fourth node; wherein the first connection is guided via at least one first circuit breaker (S3,S7), the second connection is guided via at least one second circuit breaker (S4, S8), the third connection is guided via at least one third circuit breaker (S5, S9) and/or the fourth connection is guided via at least one fourth circuit breaker (S6, S10).

Description

Circuit arrangement for linking networks with different nominal voltages via DC voltage converters

description

The invention relates to a further development of the invention disclosed in the German patent application with the official file number 102019209026.5.

The application with the file number 102019209026.5 discloses a circuit arrangement for linking networks with different voltage levels via DC voltage converters

- with a connection for a first sub-network with a first nominal voltage,

- with a connection for a first sub-network with a second nominal voltage,

- With a first DC voltage converter, which has a first input and output and a second input and output,

- with a connection, called the first connection, between the first input and output of the first DC voltage converter and the connection for the first sub-network with the first nominal voltage, which is routed via a first node,

- With a connection called the second connection between the second input and output of the first DC voltage converter and the connection for the first sub-network with the second nominal voltage, which is routed via a second node,

- with a connection for a second sub-network with the second nominal voltage,

- With a second DC / DC converter, which has a first input and output and a second input and output,

- with a connection called the third connection between the first input and output and a third node,

- with a connection called the fourth connection between the second input and output and the connection for the second sub-network with the second nominal voltage, which is routed via a fourth node, - With a first coupling switch, which is connected on the one hand to the first node and on the other hand to the third node and

- With a second coupling switch, which is connected on the one hand to the second node and on the other hand to the fourth node.

The application 102019209026.5 describes such a circuit arrangement which also has a connection for a second subnetwork with the first nominal voltage and in which the third connection is routed to the third connection via the third node.

With this circuit arrangement disclosed in the application with the file number 102019209026.5, it is possible to connect the at least four sub-networks with one another and to transport electrical energy from one sub-network to one of the other sub-networks and vice versa. The energy is transported between the subnetworks with the same nominal voltage via the coupling switches and between subnetworks with different nominal voltages via the DC voltage converter and - if the subnetworks are connected to different DC voltage converters - via a DC voltage converter and a coupling switch.

Through the coupling switch and the DC / DC converter, it is possible to use power sources provided in different subnetworks to supply electrical consumers, regardless of the subnetwork in which the consumer is located. This makes it possible to create redundancy for the power sources.

In the application with the file number 102019209026.5 it is also disclosed to connect particularly safety-relevant consumers to two sub-networks, so that if one of the two sub-networks fails, a supply from the other sub-network is possible.

Since the failure of a sub-network or a fault in the sub-network has repercussions on the circuit arrangement or the other sub-networks connected to it could, the sub-networks can be separated from each other via the coupling switch and the DC voltage converter. For this purpose, the coupling switch connected to the failed or faulty sub-network or the DC / DC converter connected to the failed or faulty sub-network can be switched off.

In the circuit arrangement described in the application with the file number 102019209026.5, a situation can arise in which the first coupling switch is open and the first DC voltage converter is switched off, for example due to a failure of the first subnet with the first nominal voltage. The actually intact first DC voltage converter is only switched off in this situation in order to separate the first subsystem with the first nominal voltage from the first and / or the second subsystem with the second nominal voltage. The coupling of the remaining intact subnetworks, the second subnetwork with the first nominal voltage and the first and second subnetwork with the second nominal voltage is then carried out via the second DC / DC converter or the second coupling switch. If the second DC / DC converter fails, there is no longer any connection between the second subnetwork with the first nominal voltage and the subnetwork with the second nominal voltage via which energy could be exchanged. A redundant energy supply may then no longer be available.

This is where the present invention begins.

The present invention is based on the object to improve the reliability ver.

According to the invention, this object is achieved in that the first connection is via at least one first isolating switch and the second connection is via at least one second disconnection switch, the third connection via at least one third disconnection switch and / or the fourth connection via at least one fourth disconnection switch is or are.

The isolating switch makes it possible to separate defective sub-networks and / or defective DC voltage converters from the intact sub-networks or the intact parts of the circuit arrangement according to the invention without the coupling switch having to be opened. This makes it possible, even in situations in which a coupling switch has to be opened in the circuit arrangement described in the application with the file number 102019209026.5, to separate a defective subnetwork from the circuit arrangement or to separate a defective DC voltage converter from the rest of the circuit arrangement. in order to achieve greater reliability.

According to the invention, it is possible that the circuit arrangement according to the invention, like the circuit arrangement known from the application with the file number 102019209026.5, has a connection for a second sub-network with the first nominal voltage and the third connection is routed via the third node to the third connection .

In the circuit arrangement according to the invention, the circuit breakers can be arranged at different points in the first, second, third and / or fourth connec tion.

One of the first isolating switches or the first isolating switch can be arranged between the connection of the circuit arrangement for the first sub-network with the first nominal voltage and the first node. It is then possible to separate the first sub-network with the first nominal voltage from the circuit arrangement according to the invention. If a defective first sub-network with the first nominal voltage is separated from the rest of the circuit arrangement according to the invention, there can be no effect on the The arrangement according to the invention unfold in such a way that its DC voltage converter would have to be switched off and its coupling switch would have to be opened.

One of the first isolating switch or the first isolating switch can also be arranged between the first node and the first input and output of the first DC voltage converter. It is then possible to separate the first input and output of the first DC / DC converter from the rest of the circuit arrangement according to the invention. If a defective first input and output is separated from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that the first coupling switch with this first input and output of the first DC voltage switch would have to be opened.

One of the second isolating switch or the second isolating switch can be arranged between the connection of the circuit arrangement for the first sub-network with the second nominal voltage and the second node. It is then possible to separate the first sub-network with the second nominal voltage from the circuit arrangement according to the invention. If a defective first sub-network with the second nominal voltage is separated from the rest of the circuit arrangement according to the invention, there can be no effect on the arrangement according to the invention in such a way that its DC voltage converter would have to be switched off and its coupling switch opened.

One of the second circuit breakers or the second circuit breaker can also be arranged between the second node and the second input and output of the first DC voltage converter. It is then possible to separate the second input and output of the first DC / DC converter from the rest of the circuit arrangement according to the invention. If a defective second input and output is separated from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that the second input and output Output of the first DC voltage switch connected to the second coupling switch would have to be opened.

One of the third circuit breakers or the third circuit breaker can be arranged between the connection of the circuit arrangement for the second sub-network with the first nominal voltage and the third node. It is then possible to separate the second sub-network with the first nominal voltage from the circuit arrangement according to the invention. If a defective second sub-network with the first nominal voltage is disconnected from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that its DC voltage converter would have to be switched off and its coupling switch opened.

One of the third circuit breakers or the third circuit breaker can also be arranged between the third node and the first input and output of the second DC voltage converter. Then it is possible to separate the first input and output of the second DC voltage converter from the rest of the circuit arrangement according to the invention. If a defective first input and output is separated from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that the first coupling switch connected to this first input and output of the second DC voltage switch would have to be opened.

One of the fourth circuit breakers or the fourth circuit breaker can be arranged between the connection of the circuit arrangement for the second sub-network with the second nominal voltage and the fourth node. It is then possible to separate the second sub-network with the second nominal voltage from the circuit arrangement according to the invention. If a defective second sub-network with the second nominal voltage is disconnected from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that its DC voltage converter would have to be switched off and its coupling switch opened. One of the fourth circuit breakers or the fourth circuit breaker can also be arranged between the fourth node and the second input and output of the second DC voltage converter. It is then possible to separate the second input and output of the second DC voltage converter from the rest of the inventive circuit arrangement. If a defective second input and output is separated from the rest of the circuit arrangement according to the invention, it cannot have any effect on the arrangement according to the invention in such a way that the second coupling switch connected to this second input and output of the second DC voltage switch would have to be opened.

It is possible for the isolating switches and the coupling switches of a circuit arrangement according to the invention to be controllable switches and for the circuit arrangement to have a controller which are connected to control connections of the controllable switches.

Furthermore, it is possible that at least one of the isolating switches or all isolating switches and / or at least one of the coupling switches or all coupling switches is a two-pole switch or are two-pole switches.

The first DC voltage converter and / or the second DC voltage converter can be a multiphase converter. Here, within the DC voltage converter, several groups, each consisting of at least one switch with assigned inductances, are arranged in parallel, the individual elements being controlled in a fixed sequence, but regulated in a correspondingly more complex manner. The group formation serves to increase performance and the seamless flow of electricity. This changes the properties of the converter:

- Increase in the ability to deliver electricity

- Reduction of residual ripple (ripple)

- Reduction of the required capacities

- Reduction of the emitted interference The invention is explained in more detail below with reference to the accompanying drawings. It shows:

Fig. 1 shows a circuit arrangement as is known from the application with the Aktenzei chen 102019209026.5,

2 shows a circuit arrangement according to the invention with isolating switches between nodes and inputs and outputs of DC voltage converters,

3 shows a circuit arrangement according to the invention with isolating switches between nodes and inputs and outputs of phases of multiphase DC voltage converters,

4 shows a circuit arrangement according to the invention with disconnectors between nodes and inputs and outputs of phases of multiphase DC voltage converters and with disconnectors between connections for sub-networks and the nodes.

The circuit arrangement known from the application with the file number 102019209026.5 is intended for linking networks with different nominal voltages via DC voltage converters. Such circuit arrangements can, as well as the circuit arrangements according to the invention, be part of a motor vehicle electrical system that comprises various sub-networks that have different nominal voltages, for example sub-networks with 12 V nominal voltage and sub-networks with 48 V nominal voltages. The circuit arrangements can also have higher voltages, as are common, for example, in vehicles with electric drives.

The circuit arrangement shown in FIG. 1 and the circuit arrangements according to the invention from FIGS. 2 to 4 have many similarities, in particular the same topology and the same structural elements and components. The same structural elements and components are denoted by the same reference characters in the figures. Each of the circuit arrangements S shown in the figures has a connection A1 for a first sub-network BN48-1 with a first nominal voltage and a connection A3 for a first sub-network BN12-1 with a second nominal voltage. Each of the circuit arrangements has a first DC / DC converter DC / DC_a, which has a first input and output 1.1 and a second input and output 1.2. A first connection between the first input and output 1.1 of the first DC voltage converter DC / DC_a and the connection A1 for the first subnetwork BN48-1 with the first nominal voltage make an electrical current from the first input and output 1.1 to connection A1 and vice versa possible . This first connection is routed via a first node K1. Furthermore, a second connection is made between the second input and output 1.2 of the first DC / DC converter DC / DC_a and the connection A2 for the first sub-network BN12-1 with the second nominal voltage, via which a current between the first DC / DC converter DC / DC_a and the Connection A2 and vice versa is possible. This second connection is routed via a second node K2.

The circuit arrangements S shown in the figures also each have a connection A3 for a second sub-network BN48-2 with the first nominal voltage, a connection A4 for a second sub-network BN12-2 with the second nominal voltage and a second DC-DC converter DC / DC_b, the one first input and output 2.1 and a second input and output 2.2. A third connection connects the first input and output 2.1 of the second DC voltage converter DC / DC_b and the connection A3 for the second subnetwork BN48-2 with the first nominal voltage via a third node K3 and a fourth connection connects the second input and output 2.2 of the second direct voltage converter DC / DC_b and the connection A4 for the second sub-network BN12-2 with the second nominal voltage via a fourth node K4.

Via the first connection and the second connection, electrical energy can be fed from the sub-networks BN48-1, BN12-1 to the first DC / DC converter DC / DC_a and transmitted in the reverse directions. Via the third connection and the fourth connection, electrical energy can be transmitted from the sub-networks BN48-2, BN12-2 to the second DC / DC converter DC / DC_b and in the opposite directions. A transmission of energy from the subnetwork BN48-1 to one of the subnetworks BN48-2, BN12-2 and vice versa is not possible with the topology described so far. The same applies to energy transmission from the subnetwork BN12_2 to one of the subnetworks BN48-1, BN12-1 and vice versa. In addition, no energy can be transmitted from the first direct voltage converter DC / DC_a to the second sub-networks BN48-2, BN12-2 and vice versa or from the second direct voltage converter DC / DC_b to the first sub-networks BN48-1, BN12-1 and vice versa.

So that such an energy transfer is also possible, a first and a second coupling switch S1, S2 are provided. The first coupling switch S1 is connected on the one hand to the first node K1 and on the other hand to the third node K3, the second coupling switch S2 is connected on the one hand to the second node K2 and on the other hand to the fourth node K4. Are the coupling switches S1,

S2 closed, an energy transfer between the first sub-networks BN48-1, BN12-1 on the one hand and the second sub-networks BN48-2, BN12-2 on the other hand is possible. In addition, it is possible to transfer energy from each of the sub-networks BN12-1, BN12-2 with the second nominal voltage via each of the DC voltage converters DC / DC_a, DC / DC_b to the sub-networks BN48-1, BN48-2 with the first nominal voltage and vice versa.

The first sub-network BN48-1 with the first nominal voltage comprises an electrical machine M / G, which can work as a motor and as a generator in order to receive or provide electrical energy or power. In addition, a battery with the first nominal voltage is provided in the first sub-network BN48-1, which can receive or provide electrical energy or power. Furthermore, safety-relevant consumers ASIL are seen in the first sub-network BN48-1 with the first nominal voltage. The second sub-network BN48-2 with the first nominal voltage includes not only non-safety-relevant consumers QM but also the safety-relevant consumers ASIL, which are already part of the first sub-network BN48-1 with the first nominal voltage. The safety-relevant consumers ASIL can thus be supplied with electrical energy in two ways, namely from the first sub-network and from the second sub-network with the first nominal voltage.

The first sub-network BN12-1 with the second nominal voltage comprises a battery that can receive or provide electrical energy or power. Furthermore, safety-relevant consumers ASIL are provided in the first subnetwork BN12-1 with the second nominal voltage.

The second sub-network BN12-2 with the second nominal voltage includes not only non-safety-relevant consumers QM but also the safety-relevant consumers ASIL, which are already part of the first sub-network BN12-1 with the second nominal voltage. These safety-relevant consumers ASIL can also be supplied with electrical energy in two ways, namely from the first sub-network and from the second sub-network with the second nominal voltage.

The circuit arrangement shown in FIG. 2 has, in addition to the components and elements already mentioned, a first disconnector S3, a second disconnector S4, a third disconnector S5 and a fourth disconnector S6.

The first isolating switch S3 is arranged between the first node K1 and the first input and output 1.1 of the first DC / DC converter DC / DC_a. With it, the first input and output 1.1 of the first DC voltage converter DC / DC_a can be separated from the rest of the circuit arrangement. The second isolating switch S4 is arranged between the second node K2 and the second input and output 1.2 of the first DC / DC converter DC / DC_a.

With it, the second input and output 1.2 of the first DC voltage converter DC / DC_a can be separated from the rest of the circuit arrangement.

The third disconnector S5 is arranged between the third node K3 and the first input and output 2.1 of the second DC / DC converter DC / DC_b. With it, the first input and output 2.1 of the second DC voltage converter DC / DC_b can be separated from the rest of the circuit arrangement.

The fourth isolating switch S6 is arranged between the fourth node K4 and the second input and output 2.2 of the second DC / DC converter DC / DC_b. With it, the second input and output 2.2 of the second DC / DC converter DC / DC_b can be separated from the rest of the circuit arrangement.

The circuit arrangement shown in FIG. 3 differs from the circuit arrangement shown in FIG. 2 in that the direct voltage converters DC / DC_a, DC / DC_b are multiphase direct voltage converters. The first and second DC voltage converters DC / DC_a, DC / DC_b each have several groups connected in parallel, each consisting of a switching element with associated inductances, the individual elements being controlled or regulated in a fixed sequence. Each group of the first and second DC / DC converters DC / DC_a, DC / DC_b has a first input and output and a second input and output.

The first input and output of each of the groups of the first DC / DC converter DC / DC_a is via a first isolating switch S3 to the first node K1 and the second input and output of each of the groups of the first DC / DC_a via a second isolating switch S4 to the second Node K2 connected. The first disconnectors S3 allow the first inputs and outputs 1.1 of the first DC / DC converter DC / DC_a to separate from the rest of the Schaltungsanord voltage. The second isolating switch S4 make it possible to separate the second inputs and outputs 1 .2 of the first DC / DC converter DC / DC_a from the rest of the circuit arrangement.

The first input and output of each of the groups of the second direct voltage converter DC / DC_b is connected to the third node K3 via a third isolating switch S5 and the second input and output of each of the groups of the second direct voltage converter DC / DC_b via a fourth isolating switch S6 the fourth node K4 connected. The third disconnector S5 make it possible to separate the first inputs and outputs 2.1 of the second DC voltage converter DC / DC_b from the rest of the circuit arrangement. The fourth isolating switch S6 makes it possible to separate the second inputs and outputs 2.2 of the second DC voltage converter DC / DC_b from the rest of the circuit arrangement.

The circuit arrangement S shown in FIG. 4 differs from the circuit arrangement according to FIG the connections A1, A2, A3, A4 for the subnetworks BN12-1, BN12-2, BN48-1, BN48-2 of the circuit arrangement and the nodes K1, K2, K3, K4 are connected.

The further first isolating switch S7 is thus connected to the connection A1 and the first node K1. With this further first isolating switch S7, it is possible to disconnect the connection A1 and the first subnetwork BN48-1 connected to it with the first nominal voltage from the circuit arrangement S.

The further second isolating switch S8 is connected to the connection A2 and the second node K2. With the further, second isolating switch S8, it is possible to disconnect the connection A2 and the first subnetwork BN12-1 connected to it with the second nominal voltage from the circuit arrangement S. The further third isolating switch S9 is connected to the connection A3 and the third node K3. With the further third isolating switch S9, it is possible to disconnect the connection A3 and the second subnetwork BN48-1 connected to it from the circuit arrangement S with the first nominal voltage.

Finally, the further fourth isolating switch S10 is connected to the connection A4 and the fourth node K4. The connection A4 and the second sub-network BN12-1 connected to it with the second nominal voltage can be disconnected from the circuit arrangement S with the further fourth disconnector S10.

A separation from one of the subnetworks can be useful if there is a defect in the subnetwork, for example a short circuit. The separation can then be carried out without one of the coupling switches having to be opened and one of the DC voltage converters having to be switched off.

List of reference symbols

S circuit arrangement

A1 Connection of the circuit arrangement for the first sub-network with the first nominal voltage

A2 Connection of the circuit arrangement for the first sub-network with the second nominal voltage

A3 Connection of the circuit arrangement for the second sub-network with the first nominal voltage

A4 Connection of the circuit arrangement for the second sub-network with the second nominal voltage

DC / DC _. first DC / DC converter

1.1 first input and output of the first DC / DC converter

1.2 second input and output of the first DC / DC converter

DC / DC _. second DC / DC converter

2.1 first input and output of the second DC / DC converter

2.2 second input and output of the second DC / DC converter

K1 first node

K2 second node

K3 third node

K4 fourth knot

51 first coupling switch

52 second coupling switch

53 first disconnector

54 second disconnector

55 third disconnector 56 fourth disconnector

57 further first isolating switch

58 further second disconnector

59 further third isolating switch

S10 another fourth disconnector

BN48-1 first sub-network with first nominal voltage BN48-2 second sub-network with first nominal voltage BN12-1 first sub-network with second nominal voltage BN12-2 second sub-network with second nominal voltage

Claims

Claims 1. Circuit arrangement (S) for linking networks with different nominal voltages via DC voltage converters (DC / DC_a, DC / DC_b) - with a connection (A1) for a first sub-network (BN48-1) with a first nominal voltage, - with a connection (A2) for a first sub-network (BN12-1) with a second nominal voltage, - With a first DC voltage converter (DC / DC_a), which has a first input and output (1.1) and a second input and output (1.2), - With a connection called the first connection between the first input and output (1.1) of the first DC / DC converter (DC / DC_a) and the connection (A1) for the first subnetwork (BN48-1) with the first nominal voltage, which has a first Node (K1) is performed, - With a connection called the second connection between the second input and output (1.2) of the first DC voltage converter (DC / DC_a) and the connection (A2) for the first sub-network (BN12-1) with the second nominal voltage, which is via a second node (K2) is performed, - with a connection (A4) for a second sub-network (BN12-2) with the second nominal voltage, - With a second DC voltage converter (DC / DC_b), which has a first input and output (2.1) and a second input and output (2.2), - with a connection called the third connection between the first input and output (2.1) and a third node (K3), - with a connection called the fourth connection between the second input and output (2.2) and the connection (A4) for the second subnetwork (BN12-2) with the second nominal voltage, which is routed via a fourth node (K4), - With a first coupling switch (S1) which is connected on the one hand to the first node (K1) and on the other hand to the third node (K3) and - With a second coupling switch (S2) which is connected on the one hand to the second node (K2) and on the other hand to the fourth node (K4), characterized in that - The first connection via at least one first isolating switch (S3, S7), the second connection via at least one second isolating switch (S4, S8), the third connection via at least one third isolating switch (S5, S9) and / or the fourth connection via at least one fourth disconnector (S6, S10) is or are. 2. Circuit arrangement (S) according to claim 1, characterized in that the circuit arrangement has a connection (A3) for a second subnetwork (BN48-2) with the first nominal voltage and that the third connec tion via the third node (K3) further to third connection (A3) is performed. 3. Circuit arrangement (S) according to claim 1 or 2, characterized in that one of the first isolating switch (S7) or the first isolating switch between the connection (A1) of the circuit arrangement (S) for the first subnetwork (BN48-1) with the first nominal voltage and the first node (K1) is arranged. 4. Circuit arrangement (S) according to claim 1 or 2, characterized in that one of the first isolating switch (S3) or the first isolating switch between the first node (K1) and the first input and output (1.1) of the first DC voltage converter (DC / DC_a) is arranged. 5. Circuit arrangement (S) according to one of claims 1 to 3, characterized in that one of the second isolating switch (S8) or the second isolating switch between the connection (A2) of the circuit arrangement (S) for the first sub-network (BN12-1) is arranged with the second nominal voltage and the second node (K2). 6. Circuit arrangement (S) according to one of claims 1 to 4, characterized in that one of the second isolating switch (S4) or the second isolating switch between the second node (K2) and the second input and output (1.2) of the first DC voltage converter (DC / DC_a) is arranged. 7. Circuit arrangement (S) according to one of claims 1 to 5, characterized in that one of the third isolating switch (S9) or the third isolating switch between the connection (A3) of the circuit arrangement (S) for the second sub-network (BN48-2) is arranged with the first nominal voltage and the third node (K3). 8. Circuit arrangement (S) according to one of claims 1 to 6, characterized in that one of the third disconnector (S5) or the third disconnector between the third node (K3) and the first input and output (2.1) of the second DC / DC converter (DC / DC_b) is arranged. 9. Circuit arrangement (S) according to one of claims 1 to 7, characterized in that one of the fourth isolating switch (S10) or the fourth isolating switch between the connection (A4) of the circuit arrangement (S) for the second sub-network (BN12-2) is arranged with the second nominal voltage and the fourth node (K4). 10. Circuit arrangement (S) according to one of claims 1 to 8, characterized in that one of the fourth isolating switch (S6) or the fourth isolating switch between the fourth node (K4) and the second input and output (A4) of the second DC / DC converter (DC / DC_b) is arranged. 11. Circuit arrangement (S) according to one of claims 1 to 9, characterized in that the isolating switch (S3 to S10) and the coupling scarf ter (S1, S2) are controllable switches and the circuit arrangement (S) has a controller which is connected to Control connections of the controllable switch (S1 to S10) is connected. 12. Circuit arrangement (S) according to one of claims 1 to 10, characterized in that one of the isolating switches (S3 to S10) or all isolating switches (S3 to S10) and / or one of the coupling switches (S1, S2) or all coupling switches (S1, S2) are two-pole switches. 13. Circuit arrangement (S) according to one of claims 1 to 11, characterized in that the first DC voltage converter (DC / DC_a) and / o which the second DC voltage converter (DC / DC_b) is or are a multiphase converter.