EP4315551A1

EP4315551A1 - Circuit assembly and charging method for an electric energy storage system

Info

Publication number: EP4315551A1
Application number: EP22713545.6A
Authority: EP
Inventors: Ian Patrick MOSS; Jochen Weber; Johannes Swoboda; Berengar Krieg; Philipp Heimbucher; Josef Goeppert; Ngoc Ho TRAN; Samuel Vasconcelos Araujo
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2021-04-01
Filing date: 2022-03-02
Publication date: 2024-02-07
Also published as: CN117099284A; WO2022207217A1; DE102021203352A1

Abstract

The invention relates to a circuit assembly for an electric energy storage system comprising a first energy storage unit and a second energy storage unit, each of which has a first pole connection and a second pole connection. The circuit assembly has: at least one first output and a second output for connecting to at least one electric component in an electrically conductive manner, a first switch unit which is arranged between the first pole connection of the first energy storage unit and the first output, a second switch unit which is arranged between the second pole connection of the first energy storage unit and the second output, a third switch unit which is arranged between the first pole connection of the second energy storage unit and the first output, a fourth switch unit which is arranged between the second pole connection of the second energy storage unit and the second output, and a fifth switch unit which is arranged between the second pole connection of the first energy storage unit and the first pole connection of the second energy storage unit, wherein the first switch unit is connected to the third switch unit, the second switch unit is connected to the fourth switch unit, and at least the first and the third switch unit and/or the second and the fourth switch unit or the first and the fourth switch unit have two semiconductor switch elements which are arranged so as to be antiserially connected.

Description

description

title

Circuit arrangement and charging method for an electric

energy storage system

field of invention

The present invention relates to a circuit arrangement and a charging method for an electrical energy storage system according to the preamble of the independent patent claims.

State of the art

DE 102017206834 A1 shows a circuit arrangement and a charging method for an electrical energy storage system.

DE 10330834 A1 shows a method and a device for supplying at least one load in the event of a power failure.

WO 2011/105794 discloses a hybrid cell system with a serial circuit whose secondary cells can be connected both in series and in parallel.

Disclosure of Invention

The core of the invention in the circuit arrangement for an electrical energy storage system with a first energy storage unit and a second Energy storage unit, each having a first pole connection and a second pole connection, is that the circuit arrangement has:

- at least one first output and one second output for electrically conductive connection with at least one electrical component,

- a first switching unit, which is arranged between the first pole connection of the first energy storage unit and the first output,

- a second switching unit, which is arranged between the second pole connection of the first energy storage unit and the second output,

- a third switching unit, which is arranged between the first pole connection of the second energy storage unit and the first output,

- a fourth switching unit, which is arranged between the second pole connection of the second energy storage unit and the second output,

- a fifth switching unit, which is arranged between the second pole connection of the first energy storage unit and the first pole connection of the second energy storage unit, wherein the first switching unit is connected to the third switching unit, wherein the second switching unit is connected to the fourth switching unit, wherein at least the first switching unit and the third switching unit and/or the second

switching unit and the fourth switching unit or the first switching unit and the fourth

Switching unit have two anti-series connected arranged semiconductor switching elements.

The background to the invention is that semiconductor switching elements are more compact and have a longer service life than mechanical switches and enable greater switching dynamics. By means of the back-to-back arrangement of two semiconductor switching elements, charging currents and discharging currents can be interrupted independently of one another. As a result, an electrical energy store can be further discharged in a critical operating state in order to carry out a safety action, while the charging currents are interrupted in order to protect the electrical energy store.

Advantageously, the energy storage units can be connected in parallel or in series with the electrical component, so that the electrical component can be operated with different voltages. The semiconductor switching elements are advantageously implemented as transistors, in particular power transistors, for example as MOSFETs or IGBTs.

Further advantageous embodiments of the present invention are the subject matter of the dependent claims.

According to an advantageous embodiment, the circuit arrangement has at least a first input and a second input for the electrically conductive connection to a voltage source, the first input being connectable to the first switching unit and the third switching unit, in particular by means of a sixth switching unit, the second input being connected to the second switching unit and the fourth switching unit can be connected, in particular by means of a seventh switching unit. As a result, the energy storage units can be connected in parallel or in series to the voltage source, so that voltage sources or charging stations with different output voltages can be used to charge the energy storage system.

According to a further advantageous configuration, the first pole connection of the first electrical energy storage unit can be connected to the first pole connection of the second electrical energy storage unit by means of the third switching unit, and the second pole connection of the first electrical energy storage unit can be connected to the second pole connection of the second electrical energy storage unit by means of the second switching unit. The advantage here is that only the first and fourth switching unit have to be opened to separate the electrical energy storage units from the inputs and the outputs.

It is advantageous if the second switching unit has a single semiconductor switching element, in particular set up to block in the charging direction, and the third switching unit has a single semiconductor switching element, in particular set up to block in the charging direction. As a result, the second and third switching units can be made compact. It is also advantageous if the first switching unit and the fourth switching unit each have two semiconductor switching elements connected back-to-back in series, with a first center tap being arranged between the semiconductor switching elements of the first switching unit, with a fourth center tap being arranged between the semiconductor switching elements of the fourth switching unit, with the sixth switching unit is connected to the first center tap and the seventh switching unit is connected to the fourth center tap. As a result, the inputs can be decoupled from the outputs, so that the electrical components connected to the outputs can be protected from the charging voltages during the charging process.

According to a further advantageous embodiment, the circuit arrangement has a first node, which connects the first switching unit to the third switching unit and the first output, and a second node, which connects the second switching unit to the fourth switching unit and the second output.

It is advantageous if the sixth switching unit is arranged between the first node and the first input and the seventh switching unit is arranged between the second node and the second input. The energy storage system can thus be connected to both the inputs and the outputs via the two nodes.

According to a further embodiment, the first switching unit, the second switching unit, the third switching unit and the fourth switching unit each have two semiconductor switching elements connected back-to-back in series, with a first center tap being arranged between the semiconductor switching elements of the first switching unit, with a second center tap being arranged between the semiconductor switching elements of the second switching unit center tap is arranged, with a third center tap being arranged between the semiconductor switching elements of the third switching unit, with a fourth center tap being arranged between the semiconductor switching elements of the fourth switching unit, with the sixth switching unit being connected to the first center tap and the third center tap and the seventh switching unit being connected to the second center tap and the fourth center tap is connected. The advantage here is that the inputs can be decoupled from the outputs, so that the connected to the outputs electrical component can be protected from the charging voltages during the charging process.

According to a further embodiment, the first switching unit and the third switching unit each have a mechanical switching element or the second switching unit and the fourth switching unit each have a mechanical switching element or the second switching unit and the third switching unit each have a mechanical switching element. As a result, the advantages of the semiconductor switching elements can be combined with the advantages of the mechanical switching elements.

According to a further embodiment, the second switching unit has only a single semiconductor switching element, in particular that is set up to block in the charging direction, and the fourth switching unit also has only a single semiconductor switching element, in particular that is set up to block in the charging direction, with between the first Pole connection of the first energy storage unit and the first switching unit, a first fuse is arranged, wherein a second fuse is arranged between the second pole connection of the second energy storage unit and the fourth switching unit. The advantage here is that the second and fourth switching units can be implemented in a simplified manner. In this case, an interruption of the switching arrangement in the discharge direction is made possible by the fuses.

Advantageously, the first fuse and/or the second fuse is designed as a relay or pyrotechnic switch. Thus, depending on the application, the backup can be executed irreversibly or reversibly.

It is also advantageous if the fifth switching unit and/or the sixth switching unit and/or the seventh switching unit each has a single semiconductor switching element, in particular which is set up to block in the discharge direction. As a result, these switching units can be designed in a simplified manner.

An additional fuse is not absolutely necessary in these cases, since these switching units only have to be able to block in the discharge direction.

As an alternative, the fifth switching unit and/or the sixth switching unit and/or the seventh switching unit can each be arranged in two pairs connected back-to-back in series Have semiconductor switching elements. Thus, these switching units can lock either in the charging direction and/or in the discharging direction.

As a further alternative, the fifth switching unit and/or the sixth switching unit and/or the seventh switching unit can have a mechanical switching element, in particular a relay or contactor. As a result, the advantages of the semiconductor switching elements can be combined with the advantages of the mechanical switching elements.

Furthermore, it is advantageous if in each case one of the semiconductor switching elements arranged in anti-series connection is set up to block in the charging direction, and the respective other of the semiconductor switching elements arranged in anti-series connection is set up to block in the discharging direction. In this case, the respective semiconductor switching elements can be controlled in a targeted manner, so that the energy storage system can be discharged but not charged at a point in time, for example.

Advantageously, the source connections or the drain connections of the semiconductor switching elements arranged back-to-back are connected to one another. The arrangement can be selected depending on the application of the switching arrangement.

The core of the invention in the electrical energy storage system with at least two electrical energy storage units is that the electrical energy storage system has a circuit arrangement as described above or according to one of the claims directed to the circuit arrangement.

The core of the invention when using a circuit arrangement as described above or according to one of the claims directed to the circuit arrangement is that the circuit arrangement is used in an electrically driven vehicle or in a hybrid vehicle.

The background to the invention is that the vehicle can be charged using various DC voltage sources. Thus, the availability of charging stations for the vehicle is improved. The vehicle can be designed as a land vehicle and/or water vehicle and/or aircraft, which has an electric drive and optionally an additional internal combustion engine as a drive. The vehicle can therefore be designed as a purely electrically driven vehicle or as a hybrid vehicle.

An electrical energy storage unit can be understood in particular as an electrochemical battery cell and/or a battery module with at least one electrochemical battery cell and/or a battery pack with at least one battery module. For example, the electric

Energy storage unit be a lithium battery cell or a lithium battery module or a lithium battery pack. In particular, the electrical energy storage unit can be a lithium-ion battery cell or a lithium-ion battery module or a lithium-ion battery pack. Furthermore, the battery cell can be of the lithium-polymer accumulator, nickel-metal hydride accumulator,

Lead-acid accumulator, lithium-air accumulator or lithium-sulfur accumulator or, more generally, an accumulator of any electrochemical composition.

Brief description of the drawings Showing:

Fig. 1 shows a first embodiment of an inventive

Circuit arrangement of an electrical energy storage system 1;

Fig. 2 shows a second embodiment of an inventive

Circuit arrangement of an electrical energy storage system 11;

3 shows a third embodiment of an inventive

Circuit arrangement of an electrical energy storage system 21;

4 shows a fourth exemplary embodiment of a device according to the invention

Circuit arrangement of an electrical energy storage system 31;

5 shows a fifth embodiment of an inventive

Circuit arrangement of an electrical energy storage system 41;

6 shows a sixth embodiment of an inventive

Circuit arrangement of an electrical energy storage system 51;

7 shows a seventh exemplary embodiment of a device according to the invention

Circuit arrangement of an electrical energy storage system 61;

8 shows an eighth exemplary embodiment of a device according to the invention

Circuit arrangement of an electrical energy storage system 71 and

9 shows a ninth embodiment of an inventive

Circuit arrangement of an electrical energy storage system 81.

Embodiments of the invention In the following section, the invention is explained using exemplary embodiments, from which further inventive features can result, but to which the scope of the invention is not limited. The exemplary embodiments are shown in the drawings.

A first embodiment of the circuit arrangement according to the invention for an energy storage system 1 is shown in FIG.

The energy storage system 1 has a first energy storage unit 2 and a second energy storage unit 4, each having an energy storage cell. The respective energy storage unit (2, 4) can also have several energy storage cells connected in series or a combination of energy storage cells connected in series and in parallel or energy storage cells connected in parallel.

Each energy storage unit (2, 4) has a first, in particular positive, pole connection (PI, P4) and a second, in particular negative, pole connection (P3, P2) and a current sensor 3.

The energy storage system 1 can be electrically conductively connected to a voltage source 7 by means of a first input E1 and a second input E2. A first switching unit S1 and a sixth switching unit S6 are arranged between the first input El and the first pole connection PI of the first energy storage unit 2 . A first node Kl is arranged between the first switching unit S1 and the sixth switching unit S6, with the first switching unit S1 being arranged between the first node Kl and the first pole connection PI of the first energy storage unit 2 and the sixth switching unit S6 between the first node Kl and the first input El is arranged. A third switching unit S3 is arranged between the first node Kl and the first pole connection P4 of the second energy storage unit 4 . The first node Kl thus connects the first switching unit S1 to the third switching unit S3 and the sixth switching unit S6. Here, connected is understood to be electrically conductive or electrically conductively connected, and connectable is understood to be electrically conductive or electrically conductively connectable.

A second switching unit S2 and a seventh switching unit S7 are arranged between the second input E2 and the second pole connection P3 of the first energy storage unit 2 . A second node K2 is arranged between the second switching unit S2 and the seventh switching unit S7, with the second switching unit S2 being arranged between the second node K2 and the second pole connection P3 of the first energy storage unit 2 and the seventh switching unit S7 between the second node K2 and the second input E2 is arranged. A fourth switching unit S4 is arranged between the second node K2 and the second pole connection P2 of the second energy storage unit 4 . The second node K2 thus connects the second switching unit S1 to the fourth switching unit S4 and the seventh switching unit S7.

The energy storage units (2, 4) can be connected in series by means of a fifth switching unit S5. For this purpose, the fifth switching unit S5 is arranged between the second pole connection P3 of the first energy storage unit 2 and the first pole connection P4 of the second energy storage unit 4 . As a result, the second pole connection P3 of the first energy storage unit 2 and the first pole connection P4 of the second energy storage unit 4 can be electrically conductively connected.

To connect the energy storage units (2, 4) in series, the fifth switching unit S5 is closed and the second switching unit S2 and the third switching unit S3 are open.

To connect the energy storage units (2, 4) in parallel, the fifth switching unit S5 is open and the second switching unit S2 and the third switching unit S3 are closed.

According to the first exemplary embodiment, the respective switching units (S1, S2, S3, S4, S5, S6, S7) each have at least one semiconductor switching element, in particular one Transistor, in particular a power transistor, in particular a MOSFET or an IGBT.

In this case, the first switching unit S1, the second switching unit S2, the third switching unit S3 and the fourth switching unit S4 each have two semiconductor switching elements which are arranged back-to-back in series. One semiconductor switching element each of these switching units (S1, S2, S3, S4) acts as a discharge switch (Sld, S2d, S3d, S4d) and the respective other semiconductor switching element acts as a charging switch (Sic, S2c, S3c, S4c). The discharging switches (Sld, S2d, S3d, S4d) are set up to interrupt the flow of current in the discharging direction, and the charging switches (Sic, S2c, S3c, S4c) are set up to interrupt the flow of current in the charging direction.

The two semiconductor switching elements are arranged next to one another in such a way that the source connections of the two semiconductor switching elements are connected to one another (common source) or that the drain connections of the two semiconductor switching elements are connected to one another (common drain).

Discharging direction is understood to mean the current flow direction in the circuit arrangement when the electrical energy storage system is being discharged. The charging direction is understood to mean the direction of current flow in the circuit arrangement when the electrical energy storage system is being charged.

The fifth switching unit S5, the sixth switching unit S6 and the seventh switching unit S7 each have only one semiconductor switching element. The respective semiconductor switching element of these switching units acts as a discharge switch (S5d, S6d, S7).

According to an exemplary embodiment not shown in the figures, the fifth switching unit S5 and/or the sixth switching unit S6 and/or the seventh switching unit S7 can also each have two semiconductor switching elements which are arranged back-to-back in series. Alternatively, the fifth switching unit S5 and/or the sixth switching unit S6 and/or the seventh switching unit S7 can have a mechanical switching element, in particular a contactor or a relay. The energy storage system 1 can be electrically conductively connected to an electrical component 6 that can be fed from the energy storage system 1 by means of a first output A1 and a second output A2. The first output Al is connected to the first node Kl and the second output A2 is connected to the second node K2.

The circuit arrangement according to the invention for an energy storage system 1 can be used, for example, for an electric motor of a vehicle. For this purpose, the outputs (A1, A2) of the energy storage system 1 are connected to a vehicle board network.

The described use of a circuit arrangement for an energy storage system 1 is also possible in energy technology, for example in wind energy technology or solar energy technology or hydropower energy technology, or for buffer storage.

A second embodiment of the circuit arrangement according to the invention for an energy storage system 11 is shown in FIG.

In addition to the first embodiment, the second embodiment of the circuit arrangement according to the invention has a first center tap M1, a second center tap M2, a third center tap M3 and a fourth center tap M4.

The first center tap Ml is arranged between the first charging switch and the first discharging switch of the first switching unit S1. The second center tap M2 is arranged between the second charging switch and the second discharging switch of the second switching unit S2. The third center tap M3 is arranged between the third charging switch and the third discharging switch of the third switching unit S3. The fourth center tap M4 is arranged between the fourth charging switch and the fourth discharging switch of the fourth switching unit S4.

The first pole connection P4 of the second energy storage unit 4 is connected by means of the third center tap M3 and the first center tap Ml and the sixth Switching unit S6 can be connected to the first pole connection PI of the first energy storage unit 2 and the first input El.

The second pole connection P3 of the first energy storage unit 2 can be connected to the second pole connection P2 of the second energy storage unit 4 and the second input E2 by means of the second center tap M2 and the fourth center tap M4 and the seventh switching unit S7.

The respective discharge switch (Sld, S2d, S3d, S4d) is arranged between the respective pole connection (PI, P2, P3, P4) and the respective center tap (Ml, M2, M3, M4) and the respective charging switch (Sic, S2c, S3c, S4c) is arranged between the respective center tap (M1, M2, M3, M4) and the respective input (E1, E2).

In contrast to the first exemplary embodiment, the first node K1 is not directly connected to the sixth switching unit S6, and the second node K2 is not directly connected to the seventh switching unit S7.

A third embodiment of the circuit arrangement according to the invention for an energy storage system 21 is shown in FIG.

The third embodiment of the circuit arrangement differs from the first embodiment in that, instead of the first switching unit S1, a first mechanical switching element Slm is arranged between the first pole connection PI of the first energy storage unit 2 and the first node Kl. Instead of the third switching unit S3, a third mechanical switching element S3m is arranged between the first pole connection P4 of the second energy storage unit 4 and the first node Kl. The respective mechanical switching element (Slm, S3m) can be implemented as a contactor or relay.

According to an alternative exemplary embodiment not shown in the figures, a second mechanical switching element can be arranged instead of the second switching unit S2 and a fourth mechanical switching element can be arranged in the circuit arrangement instead of the fourth switching unit S4. while the first switching unit S1 and the third switching unit S3 each have two semiconductor switching elements which are arranged back-to-back in series.

4 shows a fourth embodiment of the circuit arrangement according to the invention for an electrical energy storage system 31.

The fourth embodiment differs from the first embodiment in that the second switching unit S2 has only a second charging switch S2c and no second discharging switch S2d, and the fourth switching unit S4 has only a fourth charging switch S4c and no fourth discharging switch S4d. The circuit arrangement has a first fuse 38 and a second fuse 39 for this purpose. The respective fuse (38, 39) can be designed, for example, as a pyrotechnic switching element.

The first fuse 38 is arranged between the first pole connection PI of the first energy storage unit 2 and the first switching unit S1. The first fuse 38 is set up to interrupt a discharge current to the first output Al.

The second fuse 30 is arranged between the second pole connection P2 of the second energy storage unit 4 and the fourth switching unit S4. The second fuse 39 is set up to interrupt a discharge current to the second output A2.

A fifth exemplary embodiment of the circuit arrangement according to the invention for an electrical energy storage system 41 is shown in FIG.

The fifth exemplary embodiment differs from the previous exemplary embodiments in that the first pole connection PI of the first energy storage unit 2 can be connected to the first pole connection P4 of the second energy storage unit 4 by means of the third switching unit S3, and that the second pole connection P3 of the first energy storage unit 2 can be connected by means of the second switching unit S2 can be connected to the second pole connection P2 of the second energy storage unit 4 . The first node Kl connects the first switching unit S1 to the first output Al and the first input El.

The second node K2 connects the fourth switching unit S4 to the second output A2 and the second input E2.

In the fifth exemplary embodiment of the switching arrangement, the first switching unit S1 and the fourth switching unit S4 each have two semiconductor switching elements. In this case, the respective two semiconductor switching elements are arranged in such a way that the respective drain connections are connected to one another.

The second switching unit S2, the third switching unit S3, the fifth switching unit S5, the sixth switching unit S6 and the seventh switching unit S7 each have a single semiconductor switching element.

A sixth exemplary embodiment of the circuit arrangement according to the invention for an electrical energy storage system 51 is shown in FIG.

The sixth exemplary embodiment differs from the fifth exemplary embodiment in that the second switching unit S2, the third switching unit S3, the fifth switching unit S5, the sixth switching unit S6 and the seventh switching unit S7 each have a mechanical switching element.

A seventh exemplary embodiment of the circuit arrangement according to the invention for an electrical energy storage system 61 is shown in FIG.

The seventh exemplary embodiment differs from the sixth exemplary embodiment in that the semiconductor switching elements arranged back-to-back in series are arranged in such a way that the respective source connections of the two semiconductor switching elements are connected to one another. An eighth exemplary embodiment of the circuit arrangement according to the invention for an electrical energy storage system 71 is shown in FIG.

The eighth exemplary embodiment differs from the fifth exemplary embodiment in that a first center tap M1, which connects the first input El to the first switching unit S1, is arranged between the semiconductor switching elements of the first switching unit S1. The first output Al is connected directly to the first switching unit S1. In addition, between the semiconductor switching elements of the fourth switching unit

S4 arranged a fourth center tap M4, which connects the second input E2 to the fourth switching unit S4. The second output A2 is connected directly to the fourth switching unit S4. In Fig. 9 is a ninth embodiment of the invention

Circuit arrangement for an electrical energy storage system 81 is shown.

The ninth exemplary embodiment differs from the eighth exemplary embodiment in that the second switching unit S2, the third switching unit S3, the fifth switching unit S5, the sixth switching unit S6 and the seventh switching unit S7 each have a mechanical switching element.

Claims

Expectations

1. Circuit arrangement for an electrical energy storage system (1, 11, 21, 31, 41, 51, 61, 71, 81) with a first energy storage unit (2) and a second energy storage unit (4), each having a first pole connection (PI, P4 ) and a second pole connection (P3, P2), having:

- at least one first output (Al) and one second output (A2) for the electrically conductive connection to at least one electrical component (6),

- a first switching unit (Sl), which is arranged between the first pole connection (PI) of the first energy storage unit (2) and the first output (Al),

- a second switching unit (S2), which is arranged between the second pole connection (P3) of the first energy storage unit (2) and the second output (A2),

- a third switching unit (S3), which is arranged between the first pole connection (P4) of the second energy storage unit (4) and the first output (Al),

- a fourth switching unit (S4), which is arranged between the second pole connection (P2) of the second energy storage unit (4) and the second output (A2),

- A fifth switching unit (S5) which is arranged between the second pole connection (P3) of the first energy storage unit (2) and the first pole connection (P4) of the second energy storage unit (4), the first switching unit (S1) being connected to the third switching unit ( S3), the second switching unit (S2) being connected to the fourth switching unit (S4), at least the first switching unit (S1) and the third switching unit (S3) and/or the second switching unit (S2) and the fourth switching unit (S4) or the first switching unit (S1) and the fourth switching unit (S4) have two semiconductor switching elements arranged back-to-back in series.

2. Circuit arrangement according to Claim 1, characterized in that the circuit arrangement has at least one first input (El) and one second input (E2) for the electrically conductive connection to a voltage source (7), wherein the first input (E1) can be connected to the first switching unit (S1) and the third switching unit (S3), in particular by means of a sixth switching unit

(56), wherein the second input (E2) can be connected to the second switching unit (S2) and the fourth switching unit (S4), in particular by means of a seventh switching unit

(57).

3. Circuit arrangement according to Claim 1 or 2, characterized in that the first pole connection (PI) of the first electrical energy storage unit (2) can be connected to the first pole connection (P4) of the second electrical energy storage unit (4) by means of the third switching unit (S3) and the second pole connection (P3) of the first electrical energy storage unit (2) can be connected to the second pole connection (P2) of the second electrical energy storage unit (4) by means of the second switching unit (S2).

4. Circuit arrangement according to Claim 3, characterized in that the second switching unit (S2) has a single semiconductor switching element, in particular which is set up to block in the charging direction, and the third switching unit (S3) has a single semiconductor switching element, in particular which is set up in block loading direction.

5. Circuit arrangement according to Claim 3 or 4, characterized in that the first switching unit (Sl) and the fourth switching unit (S4) each have two semiconductor switching elements arranged back-to-back in series, with a first center tap (Ml) between the semiconductor switching elements of the first switching unit (Sl) is arranged, a fourth center tap (M4) being arranged between the semiconductor switching elements of the fourth switching unit (S4), the sixth switching unit (S6) being connected to the first center tap (M1) and the seventh switching unit (S7) being connected to the fourth center tap ( M4) is connected.

6. Circuit arrangement according to claim 1 or 2, characterized in that the circuit arrangement has a first node (Kl) which connects the first switching unit (Sl) to the third switching unit (S3) and the first output (Al), and a second node ( K2) which connects the second switching unit (S2) to the fourth switching unit (S4) and the second output (A2).

7. Circuit arrangement according to claim 6, characterized in that the sixth switching unit (S6) is arranged between the first node (Kl) and the first input (El) and the seventh switching unit (S7) between the second node (K2) and the second Input (E2) is arranged.

8. Circuit arrangement according to Claim 6 or 7, characterized in that the first switching unit (S1), the second switching unit (S2), the third switching unit (S3) and the fourth switching unit (S4) each have two semiconductor switching elements arranged in anti-series connection, with between a first center tap (M1) is arranged between the semiconductor switching elements of the first switching unit (S1), a second center tap (M2) being arranged between the semiconductor switching elements of the second switching unit (S2), a third center tap ( M3), a fourth center tap (M4) being located between the semiconductor switching elements of the fourth switching unit (S4), the sixth switching unit (S6) being connected to the first center tap (M1) and the third center tap (M3) and the seventh Switching unit (S7) with the second center tap (M2) and the fourth center tap (M4) v is bound.

9. Circuit arrangement according to one of claims 6 or 7, characterized in that the second switching unit (S2) has a single semiconductor switching element, in particular that is set up to block in the charging direction, and the fourth switching unit (S4) has a single semiconductor switching element, in particular that is set up to block in the charging direction, with between the first pole connection (PI ) the first energy storage unit (2) and the first switching unit (Sl) a first fuse (38) is arranged, wherein between the second pole connection (P2) of the second energy storage unit (4) and the fourth switching unit (S4) a second fuse (39) is arranged, in particular wherein the first fuse (38) and / or the second fuse (39) is designed as a relay or pyrotechnic switch.

10. Circuit arrangement according to one of the preceding claims, characterized in that the first switching unit (Sl) and the third switching unit (S3) each have a mechanical switching element, or that the second switching unit (S2) and the fourth switching unit (S4) each have a mechanical Have switching element, or that the second switching unit (S2) and the third switching unit (S3) each have a mechanical switching element.

11. Circuit arrangement according to one of the preceding claims, characterized in that the fifth switching unit (S5) and/or the sixth switching unit (S6) and/or the seventh switching unit (S7) each have a single semiconductor switching element, in particular which is set up to face in the discharge direction lock, or two anti-series connected arranged semiconductor switching elements or a mechanical switching element, in particular a relay or contactor.

12. Circuit arrangement according to one of the preceding claims, characterized in that in each case one of the semiconductor switching elements arranged in anti-series connection is set up to block in the charging direction, and the other one in anti-series connected semiconductor switching elements is set up to block in the discharge direction, and / or that the source terminals or the drain terminals of the back-to-series arranged semiconductor switching elements are connected to each other.

13. Electrical energy storage system (1, 11, 21, 31) with at least two electrical energy storage units (2, 4), characterized in that the electrical energy storage system (100) has a circuit arrangement according to one of the preceding claims.

14. Use of a circuit arrangement according to one of claims 1 to 8 in an electrically driven vehicle or in a hybrid vehicle.