EP2877366A2

EP2877366A2 - Electrical circuit arrangement for an electrically driven vehicle, vehicle and corresponding method

Info

Publication number: EP2877366A2
Application number: EP13773643.5A
Authority: EP
Inventors: Gunter Freitag; Bernhard Fischer; Thomas Schmid; Andreas BELGER
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2012-11-26
Filing date: 2013-09-18
Publication date: 2015-06-03
Also published as: DE102012221570A1; WO2014079603A2; WO2014079603A3

Abstract

Electrical circuit arrangement for an electrically driven vehicle, vehicle and corresponding method. The invention relates to preventing failure in an electrical circuit arrangement of an electrically driven vehicle. The circuit arrangement (1) comprises a high-voltage battery (11) for providing an electrical supply voltage (UV) for an electrical drive machine (2), a low-voltage on-board electrical system (4) having at least one electrical load (5, 6) which can be supplied with an operating voltage (UB), and a main voltage source (7) for providing the operating voltage (UB) for the low-voltage on-board electrical system (4). At least one first and one second auxiliary voltage source (22, 26) are provided, in each case for providing the operating voltage (UB) for the low-voltage on-board electrical system (4), as is a switching device (15, 18) which electrically connects the low-voltage on-board electrical system (4) to the first auxiliary voltage source (22) after failure of the main voltage source (7), and to the second auxiliary voltage source (26) after failure of the first auxiliary voltage source (22).

Description

description

Electrical circuit arrangement for an electrically driven vehicle, vehicle and corresponding method

The invention relates to an electrical circuit arrangement for an electrically driven vehicle, with a high-voltage battery for providing an electrical supply voltage for an electric drive machine for driving the vehicle, with a low-voltage onboard power supply with at least one electrical load, which with an operating voltage with respect to the supply voltage lower Voltage value can be supplied, and with a main voltage source for providing the operating voltage for the extra low voltage electrical system. The invention also relates to an electrically powered vehicle, as well as a method of operating a circuit in a vehicle.

Electrically powered vehicles - whether electric vehicles, hybrid vehicles - are already known from the prior art in various configurations. They include an electric drive machine (drive motor), which is usually designed as a synchronous machine or so-called brushless DC motor. To supply the drive machine with electrical energy, a high-voltage battery is used, which generates electrical supply voltage, which is a DC voltage. The voltage value of the supply voltage is usually about 400 V, in which respect higher voltage values may also be provided, such as 800 V. A high-voltage battery in the present case is generally understood to mean a battery which is designed to provide a supply voltage of at least 100 V, in particular of at least 200 V, more preferably of at least 400 V. From the supply voltage of the high-voltage battery, a motor voltage for the drive machine is then provided - this motor voltage is an AC voltage. For this purpose, an inverter or inverter is used, which consists of several transistors. stands. The adjustment of the rotational speed of the drive machine is then carried out, for example, by controlling the switching frequency of the transistors. An electrically powered vehicle further typically includes a low voltage electrical system with multiple electrical loads, which are supplied with an operating voltage of about 12 V to 15 V. As electrical consumers, which are operated with such a low voltage, are present in the present example only an air conditioner, an audio system, a lighting device, a starter for an internal combustion engine of a hybrid vehicle and a control device called. The main voltage source for supplying the extra-low voltage electrical system is usually a

DC-DC converter (DC / DC converter), which provides the operating extra-low voltage for the electrical consumers of the extra-low voltage electrical system during normal operation of the vehicle or while driving from the supply voltage of the high-voltage battery. The extra-low voltage electrical system is therefore normally supplied with electrical energy from the high-voltage battery, wherein the supply voltage of the high-voltage battery is converted into the operating voltage of lower level by means of the DC-DC converter. In addition to the DC-DC converter, a low-voltage battery is usually additionally used as an additional voltage source in an electrically driven vehicle, which can provide the operating voltage for the extra-low voltage electrical system. This low-voltage battery can also be charged via the DC-DC converter with electrical energy and is used, for example, when the vehicle is stationary or when parking to provide the extra-low voltage electrical system with energy. Now it has been found that electrically driven vehicles relatively often lose their operability due to a low voltage battery and / or due to a failure of the DC-DC converter, although the high-voltage battery itself is sufficiently charged. If there is a failure of the DC-DC converter, the DC power supply can be supplied with electrical energy from the extra-low voltage battery at most. If this battery is additionally discharged, no further operation of the vehicle is possible. And even in the case of a discharged low-voltage battery and functional DC-DC converter that same converter can not be put into operation, because it can no longer be supplied with the operating voltage of the extra-low voltage battery.

It is an object of the invention to show a way, as in an electrical circuit arrangement of the type mentioned a failure of the electrically driven vehicle can be prevented as possible.

This object is achieved by a circuit arrangement, by a vehicle and by a method having the features according to the respective independent claims. Advantageous embodiments of the invention are the subject of the dependent claims, the description and the figures.

Accordingly, it is proposed to use in the electrical circuit arrangement of the type mentioned in addition to the main voltage source at least a first and a second auxiliary voltage source, which are each designed to provide the operating voltage for the extra-low voltage electrical system, wherein a switching device is provided, which after failure of the main power source the Extra low voltage electrical system with the first additional voltage source and after additional failure of the first additional voltage source to the second auxiliary voltage source electrically connects. According to the invention, therefore, a triple redundancy for the supply of the extra-low voltage electrical system is provided with electrical energy, thus enabling a highly redundant safety with regard to the operation of the vehicle. In addition to the main voltage source (in particular DC voltage converter), at least two additional voltage sources are provided, which can optionally supply the extra-low voltage on-board electrical system. For this purpose, a switching device is also provided which, after failure of the main voltage source (in particular of the DC-DC converter) connects the extra-low voltage electrical system to the first additional voltage source (in particular low-voltage battery), preferably exclusively to the first additional voltage source, and after additional failure of the first additional voltage source causes the extra-low voltage electrical system is supplied with electrical energy of the second additional voltage source, in particular exclusively with energy of the second additional voltage source. Thus, even if both the main voltage source and the first additional voltage source fail, further operation of the vehicle is made possible by electrically connecting the extra-low voltage electrical system to the second additional voltage source. The connection of the extra-low voltage electrical system to the second additional voltage source preferably takes place only after failure of the first additional voltage source.

The electrically driven vehicle may be a pure electric vehicle, which is driven exclusively by means of the electric drive machine. Alternatively, it may also be a hybrid vehicle having both the electric drive machine and a separate internal combustion engine with an associated starter.

Preferably, the main voltage source is a DC-DC converter, which provides the operating voltage for the extra-low voltage electrical system from the supply voltage of the high-voltage battery. The operating voltage for the extra-low voltage electrical system is thus provided during normal operation of the vehicle or while driving by means of the DC-DC converter. If this fails, the extra-low voltage electrical system can be supplied with energy from the first additional voltage source. The first additional voltage source is preferably designed as a low-voltage battery, in particular a lead-acid battery. The low-voltage battery can be designed to provide an operating voltage of 12 V, for example. After failure of the DC-DC converter, such a low-voltage battery at least for a certain period of time is a reliable replacement for the supply of extra-low voltage electrical system. The high-voltage battery preferably comprises a plurality of series-connected battery cells, which are arranged between a first battery terminal on the one hand and a second battery terminal on the other. It proves to be particularly advantageous if the second additional voltage source by a predetermined subset of

Battery cell is formed and the high-voltage battery further comprises an additional terminal, to which a voltage applied to the subset of the battery cells electrical voltage as the operating voltage for the extra low voltage electrical system

can be tapped. In this initial form, the advantages of the present invention fully come into play, because the triple redundancy can be made with the least effort and without expensive additional components for generating electrical voltage. Namely, the already existing battery cells of the high-voltage battery can be used for the second additional voltage source. Thus, the extra low voltage electrical system can be supplied even with an empty low voltage battery and in case of failure of the DC-DC converter with electrical energy. A failure of the vehicle due to a discharged low-voltage battery and a failed DC-DC converter can thus be prevented with little technical effort. However, even with a functional DC-DC converter, the vehicle can continue to be operated even if the low-voltage battery is discharged. In this case, the extra-low voltage electrical system can be supplied with energy from the subset of the cells of the high-voltage battery, and these cells can optionally also be recharged via the DC-DC converter.

For the subset of battery cells battery cells are preferably used, which are arranged directly adjacent to each other, and in particular are also directly connected to one of the battery terminals, namely preferably with that terminal to which the reference potential (ground) is provided.

In one embodiment, the switching device comprises a first switch, via which the extra-low voltage electrical system can be coupled to the main voltage source. A control element of the first switch can be connected to the main voltage source and supplied with the operating voltage provided by the main voltage source, so that after failure of the main voltage source the first switch is automatically switched to a switching state in which the extra low voltage electrical system is disconnected from the main voltage source is. Thus, in the case of a fault of the main voltage source, in particular the DC-DC converter, the extra-low voltage electrical system is electrically isolated from the same source and can then be supplied with electrical energy of the first additional voltage source. The first switch is preferably designed as a relay, which has a coil as a control, which is electrically coupled to the main voltage source. In particular, this coil is connected in parallel to the main power source and permanently connected to it, so that the relay always remains in its closed switch position when the main power source is functional and automatically drops after failure of the main power source. Such an approach enables a reliable disconnection of the extra low voltage electrical system from the main power source in the event of a failure of the same.

The switching device preferably has a second switch which switches between a first switching state in which the extra-low voltage electrical system with the first additional voltage source is coupled, and a second switching state can be switched, in which the extra low voltage electrical system is coupled to the second additional voltage source. At a certain point in time, the extra-low voltage electrical system can thus be connected to either the first or the second additional voltage source.

Also, a control of the second switch may be connected to the first auxiliary voltage source and supplied with the operating voltage provided by the first auxiliary voltage source, namely such that is maintained in the presence of the operating voltage of the first additional voltage source of the second switch in the first switching state in which the extra low voltage electrical system is coupled to the first additional voltage source, and that after failure of the first additional voltage source of the second switch is automatically switched to the second switching state in which the extra low voltage electrical system is coupled to the second additional voltage source. Also, the second switch may be formed as a relay, which in addition to a movable contact element comprises two stationary contact elements, of which a first contact element with the first additional voltage source and a second contact element are connected to the second additional voltage source. The coil of the relay can be permanently connected to the first additional voltage source and, in particular, connected in parallel therewith. In the normal case, or in the case of a functional first additional voltage source, the relay is therefore in the first switching state, in which the extra-low voltage electrical system is connected to the first additional voltage source. After failure of the voltage of the first additional voltage source, the relay drops, and the movable contact element is brought into a position in which the extra low voltage electrical system is disconnected from the first additional voltage source and connected to the second Zusatzspannungsquel - le. This embodiment has the total

Advantage that, after failure of the first additional voltage source, switching to the second additional voltage source takes place automatically. However, the invention is not limited to the execution of the first and / or the second switch as a relay. Alternatively, the first and / or second switch can also be realized in the form of at least one transistor whose control connection is connected as a control element to the main voltage source or to the first additional voltage source.

In one embodiment, it is provided that the first and the second switch are electrically connected to one another so that the first or the second additional voltage source can be charged with electrical energy via the DC-DC converter as the main voltage source, depending on the switching state of the second switch. The low-voltage on-board network can be coupled on the one hand via the first switch with the DC-DC converter and on the other hand with the second switch. If the DC-DC converter is functional, the first additional voltage source can be charged via this. If the first additional voltage source fails, the second additional voltage source, that is to say in particular the subset of the battery cells of the high-voltage component, can be charged via the DC-DC converter. Thus, even if the low-voltage battery fails, the vehicle can continue to operate normally over a longer period of time.

The invention further relates to an electrically driven vehicle having a circuit arrangement according to the invention.

An inventive method is designed to operate a circuit arrangement of an electrically driven vehicle, wherein an electrical supply voltage for an electric drive machine of the vehicle is provided by means of a high-voltage battery, at least one electrical load of a low voltage electrical system is supplied with an operating voltage and the operating voltage for the extra low voltage electrical system by means of a main voltage source provided. After failure of the main power source, the extra low voltage electrical system is electrically connected by means of a switching device with a first additional voltage source and after failure of the first additional voltage source with a second additional voltage source.

The preferred embodiments presented with reference to the circuit arrangement according to the invention and their advantages apply correspondingly to the vehicle according to the invention as well as to the method according to the invention.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. All the features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the respectively indicated combination but also in other combinations or alone.

The invention will now be explained in more detail using a preferred embodiment and with reference to the accompanying drawings. 1 shows a schematic representation of an electrical

Circuit arrangement according to an embodiment of the invention; and

2 shows a schematic representation of an exemplary

High-voltage battery of the circuit arrangement.

1 shows an electrical circuit arrangement 1 or a two-voltage on-board electrical system of an electrically driven vehicle according to an embodiment of the invention. The vehicle may be, for example, a passenger car with an electric drive machine 2. Optionally, the vehicle may also be a hybrid vehicle and additionally an internal combustion engine not shown in detail in the figures involve with a starter. In a purely electric vehicle, however, such an internal combustion engine is dispensed with, and the vehicle is driven exclusively by means of the electric drive machine 2.

The circuit arrangement 1 has a high-voltage network 3, in which the electric drive machine 2 is arranged. Furthermore, the circuit arrangement comprises a low voltage on-board network 4, which may include a plurality of electrical consumers 5, 6, wherein the number of electrical loads 5, 6 may be basically arbitrary.

The circuit arrangement 1 further comprises a DC-DC converter 7, which is connected on the input side to a node 8 of the high-voltage network 3 and on the output side to a node 9. The DC-DC converter 7 is also connected to a reference potential 10 (ground). At the same reference potential 10 are also the high-voltage network 3 and the extra-low voltage electrical system 4, wherein alternatively it can also be provided that the two networks 3, 4 are at different reference potentials.

To supply the electric machine 2 with energy, a high-voltage battery 11 with a plurality of battery cells is provided in the high-voltage network 3. Between a first battery terminal 12 and a second battery terminal 13, the high-voltage battery 11 provides a supply voltage UV. The second battery terminal 13 is in this case directly connected to the reference potential 10, wherein alternatively it can also be provided that the reference potential 10 lies within the battery 11, that is, for example, the battery 11 is symmetrical with respect to the reference potential 10 and the reference potential 10 is thus centered between the battery terminals 12, 13 is located. Then, a positive potential is applied to the first battery terminal 12, while a negative potential with respect to the reference potential 10 is applied to the second battery terminal 13. From the supply voltage UV is using a not shown inverter a provided electrical AC voltage for the prime mover 2. The supply voltage UV may, for example, have a voltage value of 400 V or 800 V. The first battery terminal 12 is connected to the node 8 and thus to the input of the DC-DC converter 7. This results in a parallel connection of the high-voltage battery 11 and the prime mover 2, which is connected between the node 8 and the reference potential 10.

In contrast, the extra-low voltage electrical system 4 is operated with a low voltage of, for example 12 V to 15 V. The electrical consumers 5, 6 are connected in parallel to one another and connected on the one hand to a node 14 and on the other hand to the reference potential 10. About the node 14, the consumers 5, 6 are supplied with electrical operating voltage. For this purpose, the node 14 is coupled via a first electrical switch 15 and a diode 16 to the node 9 and thus to the output of the DC-DC converter 7. The anode of the diode 16 is connected to the node 9 and the output of the DC-DC converter 7, while the cathode is connected to the switch 15. In the exemplary embodiment, the first switch 15 is designed as a relay with a coil 17 as a control element, wherein the coil on the one hand with the node 9 and thus with the output of

DC voltage converter 7 and on the other hand connected to the reference potential 10. In the presence of the voltage at the output of the DC-DC converter 7, the coil 17 thus continuously attracts the movable contact element of the switch 15, so that the switch 15 is closed, and current flows through the switch 15.

On the side opposite the first switch 15, the node 14 is connected to a second electrical switch 18, which is likewise designed as a relay. Of the

Node 14 is connected to a movable contact element of the switch 18, which can be moved between two switching positions. In a first switching position kon- The movable contact element clocks a first stationary contact element 19, and in a second switching position (as shown in FIG. 1), the movable contact element makes contact with a second stationary contact element 20. To attract the movable contact element, a coil 21 is provided as a control, which is parallel to a low-voltage battery 22 is switched. The parallel connection of coil 21 and low-voltage battery 22 is connected on the one hand to the first stationary contact element 19 and on the other hand to the reference potential 10. In the normal case, when the low-voltage battery 22 provides electrical voltage, the coil 21 is energized, and the movable contact element contacts the stationary contact element 19, so that the node 14 is connected to the low-voltage battery 22. If the voltage of the low-voltage battery 22 fails, the switch 18 drops, and the movable contact element contacts the second stationary contact element 20.

The two switches 15, 18 together form a switching device in the sense of the present invention.

The high-voltage battery 11 furthermore has an additional connection 23, at which partial electrical voltage UT with respect to the reference potential 10 can be tapped, which is applied to a predetermined subset of battery cells of the high-voltage battery 11. The additional connection 23 is connected via an electrical line 24 to the second stationary contact element 20 of the switch 18. The high-voltage battery 11 is shown by way of example in FIG 2 in more detail. As already stated, the high-voltage battery 11 has the first battery terminal 12 and the second battery terminal 13. It comprises a plurality of battery cells 25, specifically more than 100 such battery cells. The high-voltage battery 11 may be, for example, a lithium-ion battery. For example, a single battery cell 25 may provide a 3.7V electrical voltage (with the cell charged). For providing the partial voltage UT at the additional connection 23 (see also FIG. 1), a subset 26 of the battery cells 25 and, for example, four such battery cells 25 are electrically separated from the high-voltage battery 11. In the illustrated embodiment according to FIG. 2, the first battery cells 25, calculated as a subset 26, are separated from the second battery terminal 13 or the reference potential 10. In principle, it may be provided that the additional connection 23 is connected to a node between two adjacent battery cells 25, without an electrical separation between the subset 26 and the remaining cells 25 takes place. Optionally, however, switching means 27 may be provided which cause the subset 26 to be selectively electrically disconnected from the remaining battery cells 25 and thus decoupled. These switching means 27 have a switch 28 and a further switch 29, which are switched synchronously, and that between a first switching state, in which the subset 26 is connected via a line 30 to the remaining battery cells 25 and thus all the battery cells 25 from the auxiliary connection 23 are decoupled and provide the supply voltage UV, and a second switching state shown in FIG 2, in which the subset 26 is connected to the auxiliary terminal 23 and a terminal 31 of the outer battery cell 25 of the remaining cells is connected to the reference potential 10. In the second switching state of the switches 28, 29, the partial quantity 26 is thus separated from the high-voltage battery 11, and the partial voltage UT of, for example, 15 V is provided at the additional terminal 23.

Optionally, it can also be provided that whenever the movable contact element of the switch 18 (FIG. 1) is in the second switching position and thus connected to the additional terminal 23, the switches 28, 29 of the high-voltage battery 11 are in the second switching state in which the partial voltage UT of 15 V is applied to the auxiliary conclusion 23 is present. This can be ensured for example by means of a control unit.

With renewed reference to FIG. 1, the circuit arrangement 1 includes a total of three different voltage sources: As

Main voltage source is the DC-DC converter 7, which generates an operating voltage UB for the load 5, 6 from the supply voltage UV of the high-voltage battery 11. The first additional voltage source is the low-voltage battery 22, and the second additional voltage source is the subset 26 of the battery cells 25 of the high-voltage battery 11, which are arranged between the auxiliary terminal 23 and the reference potential 10. In normal operation of the vehicle or during normal driving (for example, from a predetermined speed), the operating voltage UB by means of

DC-DC converter 7 generated. This can for example be controlled by means of a control unit (not dargstellt). In this normal operation, the DC-DC converter 7 provides a voltage whose voltage value is slightly higher than the battery voltage of the low-voltage battery 22 and, for example, 15 V. Thus, the switch 15 is closed, and also the switch 18 is in the first switching position or in its first switching state, so that the node 14 is connected to the low-voltage battery 22. This is because the low voltage battery 22 is charged and electric current flows through the coil 21. In normal operation, the low-voltage battery 22 can thus continue to use electrical energy over the

DC voltage converter 7 are charged.

At standstill of the vehicle or when parking - and generally speaking in an operating mode with switched off converter 7 - the operating voltage UB is generated for the load 5, 6 with the low voltage battery 22, while the DC-DC converter 7 supplies no voltage - the switch 15 is open, and the switch 18 connects the low voltage battery 22 to the loads 5, 6. If a fault of the DC voltage converter 7 occurs during normal operation so that it does not provide any voltage at the node 9, then the first switch 15 drops out and the electrical consumers 5, 6 are supplied exclusively with the aid of the low voltage battery 22. Thus, the vehicle can continue to operate even though the DC-DC converter 7 has failed. If the low-voltage battery 22 is also discharged, no current flows through the coil 21, and the second switch 18 drops. In this case, the node 14 and thus the extra-low voltage electrical system 4 is connected to the auxiliary terminal 23 of the high-voltage battery 11. The extra-low voltage electrical system 4 is now supplied exclusively with electrical energy of the subset 26. This results in a total of three redundancy and thus a highly safe operation of the vehicle, without the addition of voltage components must be used to generate electrical voltage. It can also happen that the functional battery DC voltage converter 7, the low-voltage battery 22 is discharged because, for example, the consumer 5, 6 are operated too long at standstill of the vehicle. In this case, the extra-low voltage electrical system 4 is connected to the auxiliary terminal 23 of the high-voltage battery 11, while the DC-DC converter 7 can continue to be operated. Thus, the low voltage battery 22 is replaced by the subset 26 of the cells 25, and the vehicle can continue to operate for any length of time. By way of the DC-DC converter 7, the subset 26 of the cells 25 can be charged. The further operation may for example be such that the operating voltage UB and thus the current state of charge of the subset 26 of the cells 25 is monitored by the said control unit and is driven after falling below a predetermined voltage limit of the DC-DC converter 7 to the subset 26 again with energy charge. The driver thus has enough time to replace the low-voltage battery 22 or recharge. If the low-voltage battery 22 or the subset 26 is charged with electrical energy via the DC-DC converter 7, the diode 16 ensures that return currents from the low-voltage battery 22 per se or the subset 26 do not adversely affect the first switch 15.

Claims

claims

An electrical circuit arrangement (1) for an electrically driven vehicle, comprising:

a high-voltage battery (11) for supplying an electric supply voltage (UV) to an electric drive machine (2) for driving the vehicle,

- A low voltage electrical system (4) with at least one electrical load (5, 6), which is supplied with an operating voltage (UB) with respect to the supply voltage (UV) of the high-voltage battery (11) lower voltage value, and

- A main voltage source (7) for providing the operating voltage (UB) for the extra low voltage electrical system (4), characterized by

- At least a first and a second auxiliary voltage source (22, 26) each for providing the operating voltage (UB) for the extra low voltage electrical system (4) and

- A switching device (15, 18) which is designed to after failure of the main power source (7) the extra low voltage electrical system (4) with the first additional voltage source (22) and after failure of the first additional voltage source (22) with the second additional voltage source (26) electrically connect to.

2. Circuit arrangement (1) according to claim 1, characterized in that the main voltage source (7) is a DC-DC converter, which is adapted to the operating voltage (UB) for the extra-low voltage electrical system (4) from the supply voltage (UV) of the high-voltage battery (11). provide.

3. Circuit arrangement (1) according to claim 1 or 2, characterized in that the first additional voltage source (22) is designed as a low voltage battery.

4. Circuit arrangement (1) according to one of the preceding claims, characterized in that the high-voltage battery (11) comprises a plurality of series-connected battery cells (25), which between a first and a second battery terminal (12, 13) of the high-voltage battery (11) are arranged, wherein the second additional voltage source (26) by a predetermined subset of the battery cells (25) of the high-voltage battery (11) is formed and the high-voltage battery (11) further an additional connection (23), on which a voltage applied to the subset of the battery cells (25) electrical partial voltage (UT) can be tapped as the operating voltage (UB) for the extra-low voltage electrical system (4).

5. Circuit arrangement (1) according to one of the preceding claims, characterized in that the switching device (15, 18) comprises a first switch (15) via which the extra low voltage electrical system (4) with the main voltage source (7) can be coupled, wherein a control (17) of the first switch (15) is connected to the main voltage source (7) and can be supplied with the operating voltage (UB) provided by the main voltage source (7), so that after failure of the main voltage source (7), the first switch (15) automatically can be switched to a switching state in which the low-voltage on-board electrical system (4) is disconnected from the main voltage source (7).

6. Circuit arrangement (1) according to one of the preceding claims, characterized in that the switching device (15, 18) comprises a second switch (18) which between a first switching state in which the extra low voltage electrical system (4) with the first additional voltage source (22 ), and a second switching state is switchable, in which the extra-low voltage electrical system (4) is coupled to the second additional voltage source (26).

7. Circuit arrangement (1) according to claim 6, characterized in that a control element (21) of the second switch (18) connected to the first additional voltage source (22) and with the of the first auxiliary voltage source (22) provided operating voltage (UB) can be supplied such that in the presence of the operating voltage (UB) of the first auxiliary voltage source (22), the second switch (18) in the first Switching state is maintained and after failure of the first additional voltage source (22) of the second switch (18) is automatically switched to the second switching state.

8. Circuit arrangement (1) according to claim 5 and claim 6 or 7, characterized in that the first and the second switch (15, 18) are electrically coupled together so that the main voltage source (7), in particular the DC-DC converter, depending on the Switching state of the second switch (18), the first or the second auxiliary voltage source (22, 26) is charged with electrical energy.

9. Electrically powered vehicle with a circuit arrangement (1) according to one of the preceding claims.

10. A method of operating a circuit arrangement (1) of an electrically driven vehicle, wherein:

an electrical supply voltage (UV) is provided for an electric drive machine (2) of the vehicle by means of a high-voltage battery (11),

- At least one electrical load (5, 6) of a small voltage electrical system (4) with an operating voltage (UB) with respect to the supply voltage (UV) of the high-voltage battery (11) lower voltage value is supplied and

the operating voltage (UB) for the extra-low voltage electrical system (4) is provided by means of a main voltage source (7),

characterized in that

at least a first and a second additional voltage source (22, 26) each provide the operating voltage (UB) for the extra low voltage electrical system (4) and after failure of the main voltage source (7) the extra low voltage electrical system (4) by means of a switching device (15, 18) with the first additional voltage source (22) and after failure of the first additional voltage source (22) with the second additional voltage source (26) is electrically connected.