EP3934941A1 - Power network for a motor vehicle and method for operating a power network for a motor vehicle - Google Patents

Abstract

The invention relates to a high-availability power network (E) for a motor vehicle having a manual or highly automated driving function. For this purpose, the power network (E) comprises a first partial power network (T1), which is connected to a supply potential (KL30.B), a second partial power network (T2), and a coupling element (K, Kx) which couples the second partial power network (T2) via the first partial power network (T1) to the supply potential (KL30.B). The coupling element (K, Kx) has a reversible disconnect function, such that the coupling element (K, Kx) is designed to reversibly decouple the first partial power network (T1) from the second partial power network (T2) according to a physical value of the first partial power network (T1).

Description

Energy network for a motor vehicle and method for operating an energy network for a motor vehicle

DESCRIPTION:

The invention relates to an energy network for a motor vehicle, comprising a first partial energy network which is connected to a supply potential, a second partial energy network, and a coupling element which couples the second partial energy network to the supply potential via the first partial energy network. The invention also relates to a method for operating such an energy network.

In vehicle technology, an energy supply and an interconnection of individual partial energy networks, for example individual components, are referred to as the energy network or on-board energy network of a motor vehicle. In general, the energy network can be divided into an abstract energy network, also known as an energy distribution network, and a physical on-board network. The abstract energy network describes an energy distribution, energy supply and energy conversion for or through the components of the energy network. On the other hand, the physical on-board network describes the real components, such as a wiring harness, plug, cable and the individual components.

In order to avoid the effects of a short circuit on an energy distribution network, DE 10 2017 201 488 A1 discloses a method for detecting a short circuit in the electrical energy distribution network in which electrical energy is provided from at least one electrical energy source to at least one consumer. This publication mainly describes a mathematical method for detecting the short circuit. Furthermore, DE 10 2012 022 083 A1 discloses a protective circuit for an electrical supply network of a motor vehicle. In response to a trigger signal from a control device, a triggerable disconnection element is activated in order to interrupt an electrical connection between a first connection and a second connection of the protective circuit. In this case, the electrical connection between the first and the second connection through the disconnection element cannot be provided again by a control signal from the control device. In particular in the event of an accident, which can be detected, for example, by means of an airbag control unit, a starter battery of the motor vehicle can be disconnected from the electrical supply network. In this way, any risk to passengers and the cargo on the motor vehicle can be prevented.

Finally, DE 10 2014 214 501 A1 discloses a method for controlling a multi-voltage electrical system of a motor vehicle. A multi-voltage on-board network is an on-board network that comprises several sub-networks with different network voltages. In order to reduce the effects of a short circuit in one of the subnetworks on another of the subnetworks, this publication provides a control unit which detects a short circuit between these subnetworks and then deactivates an affected component of the respective subnetwork.

The object of the present invention is now to increase the availability of an energy network.

The object is achieved by the subjects of the independent patent claims. Advantageous developments of the invention are disclosed by the dependent claims, the following description and the figures.

The invention provides an energy network for a motor vehicle. The energy network comprises a first partial energy network that is connected to a supply supply potential is connected, a second partial energy network and a Kop pelelement, which couples the second partial energy network via the first partial energy network with the supply potential. The coupling element has a reversible separating function. The coupling element is thus designed to reversibly decouple the first partial energy network from the second partial energy network as a function of a physical value of the first partial energy network.

In other words, the described energy network of the motor vehicle is designed in such a way that the first partial energy network and the second partial energy network represent, so to speak, physically separate sections of the energy network. The physical and thus electrically conductive connection of the two partial energy networks is only made via the coupling element. The coupling element has the reversible separating function mentioned. Thus, the electrical connection between the first partial energy network and the second partial energy network can be separated reversibly and in particular also non-destructively, but can also be restored if necessary.

The separation or connection, i.e. the coupling or decoupling of the first and second partial energy networks, which can also be referred to as consumer units, is preferably carried out as a function of the physical value. The disconnection or connection can preferably also take place as a function of more than just one physical value, that is to say of several physical values. In particular, the two partial energy networks are only decoupled if the physical value or values represent a functional disruption of the first partial energy network. A malfunction can be, for example, an overload, for example due to a short circuit and / or increased total currents in the first partial energy network. The coupling element is thus designed, so to speak, to detect and evaluate the physical value (s) and, depending on the result of the evaluation, to electrically separate or connect the first partial energy network from the second partial energy network. The invention is based on the knowledge that consumer repercussions, i.e. errors in a partial energy network, in particular a component of a partial energy network, negatively affect not only the partial energy network concerned, but the entire energy network and, in the worst case, even lead to the failure of the entire energy network. With the reversible coupling element, the partial energy networks can now be decoupled in the event of a fault. In other words, by using the coupling element with a reversible separating function in the main supply path, these consumer repercussions can now be eliminated. The coupling element separates the partial energy networks from one another in the event of consumer feedback, which can be determined with the aid of the at least one physical value. Thus, the consumer feedback cannot affect the entire energy network, that is to say in particular the second partial energy network. This results in the advantage that the reversible separating function of the coupling element enables a connection between the first and second partial energy networks to be restored after the malfunction in the first partial energy network has been resolved, although the partial energy networks were previously physically separated from each other. In particular, if the malfunction is a fault in software for controlling the first partial energy network, this can often be remedied during a Fährbe operation of the motor vehicle by restarting the partial energy network or a component of the partial energy network. The functional disruption would thus be eliminated, which the coupling element could determine by detecting the physical value, and the first partial energy network could be coupled again with the second partial energy network. If, on the other hand, the two partial energy networks had been irreversibly separated or decoupled in this case, a workshop would have had to be visited to exchange a connection line between the partial energy networks or the coupling element. In one embodiment of the energy network, the reversible disconnection function enables, so to speak, a component-individual hardware reset (component reset) if the component, and thus, if applicable, the entire partial energy network, for example due to a software "hung up" error. Overall, this can increase the availability of the motor vehicle.

Furthermore, by using the coupling element with a reversible separating function, instead of, for example, fuses with an irreversible separating function, the costs and weight of the physical energy network can be reduced.

Said motor vehicle is preferably designed as a motor vehicle, in particular as a passenger car or truck, or as a passenger bus or motorbike. The motor vehicle can in particular be designed as an electrical motor vehicle, hybrid vehicle or motor vehicle with an internal combustion engine. The first and second partial energy networks can in particular each be designed as individual electrical components or consumers of the motor vehicle. Alternatively, both the first and the second partial energy network can also comprise a large number of individual components or consumers. The first partial power network can be designed, for example, as an infotainment system and / or radio or sound system control and / or navigation system and / or interior light control and / or trunk light control. In contrast, the second partial energy network can be designed, for example, as a brake control system and / or steering system and / or a light control and / or a wiper control. In general, the components of the partial energy networks can also be control devices for various systems of the motor vehicle. In addition to the components, the two partial energy networks or partial energy networks can also include, for example, at least one energy source and / or an energy store or connections for coupling to an energy source or an energy store. Furthermore, the two partial energy networks can also include cabling and / or connections to further partial energy networks or consumer units of the motor vehicle. A 12-volt supply voltage, for example, can be provided to the first or second partial energy network via the supply potential mentioned.

In a particularly advantageous manner, the coupling element can also be designed to reversibly decouple the first partial energy network from the second partial energy network as a function of a physical value of the energy network, in particular a supply path of the energy network.

The invention also includes embodiments which result in additional advantages.

One embodiment provides that the physical value of the first partial energy network represents an electrical value and / or a temperature value.

An electrical value can for example be designed as a current or voltage value. For example, the physical value can represent a short circuit as a malfunction of the first partial energy network, in particular a component of the first partial energy network. The two partial energy networks can thus be reversibly decoupled from one another in particular when an increased current flow from the first partial energy network to the second partial energy network is detected by the coupling element. In contrast, the temperature value can be used to indicate, for example, overheating of the first partial energy network as a malfunction. A malfunction can not only be a mechanical destruction of a component of the first partial energy network, but can also be caused, for example, by a hardware error and / or a software error in the control of the first partial energy network.

Thus, the first partial energy network can comprise, for example, at least one electrical consumer and at least one energy source as components. In contrast, the second partial energy network can only comprise electrical consumers as components, for example. Now a physica- Cal value in the form of a current flow from the first partial energy network to the second partial energy network can be monitored by the coupling element. If a current value in the current flow would exceed or fall below a predetermined limit value, the coupling element could decouple the two sub-networks. This could prevent the energy source of the first sub-network from being discharged by the components of the second sub-network when the sub-networks are connected, so that in particular no longer sufficient energy is available to operate the other components of the first sub-network.

Alternatively, the first partial energy network could be designed as a multi-voltage network. The first partial energy network thus itself have partial energy networks each with their own components, the partial energy networks in particular having different supply potentials. As a result, the coupling element could also perform the reversible decoupling of the first and second sub-networks as a function of a physical value of one of the sub-networks of the first partial energy network.

Another embodiment provides that the first partial energy network comprises at least one non-safety-relevant component for providing a function of a motor vehicle. On the other hand, the second partial energy network comprises at least one safety-relevant component for providing a function of a motor vehicle. In other words, the second partial energy network can thus represent a partial energy network that is required for safe operation of the motor vehicle in road traffic. The safety-relevant function of the second partial energy network can be, for example, a driving function, a steering function, in particular a steering support function and / or a braking function, in particular a brake support function and / or a light function and / or a wiper function of the motor vehicle. On the other hand, the first partial energy network can accordingly be irrelevant for the safe operation of the motor vehicle and thus rather serves the comfort of an occupant of the motor vehicle. At the non- The safety-relevant function of the first partial energy network can be, for example, a navigation function and / or function of a radio or sound system and / or an infotainment function and / or a lighting function in the interior of the motor vehicle or a trunk.

This has the advantage that it is avoided that a malfunction of a non-safety-relevant component affects the function of a safety-relevant component due to the previously described consumer reaction. The energy supply of safety-relevant components, in particular in accordance with IS026262, can therefore be guaranteed in a particularly preferred manner, while at the same time the vehicle availability can be maintained. In other words, the coupling element with a reversible separating function can provide protection and isolation of the safety-relevant components from the non-safety-relevant components. Overall, a sudden, unannounced failure of safety-relevant electrical systems, such as steering assistance and / or braking assistance, can be prevented.

Additionally or alternatively, it can also be provided that the first partial energy network comprises at least one safety-relevant component for providing a function of a motor vehicle and the second partial energy network comprises at least one non-safety-relevant component for providing a function of a motor vehicle.

Another embodiment provides that the coupling element is designed as a DC / DC converter (direct voltage converter) or as a switchable potential distributor.

The DC / DC converter is in particular also designed as a switchable DC / DC converter. In this context, switchable is understood to mean that the DC / DC converter or the potential distributor can be controlled in order to provide the reversible isolating function. For this purpose, both the DC / DC converter and the potential distributor can include, for example, a switching element, such as a semiconductor switch or a relay, which, depending on the physical value, for example a current or a voltage, establishes the connection between the first partial power grid and the second partial power grid separates. The switchable DC / DC converter or the switchable potential distributor can particularly preferably also be referred to as an intelligent DC / DC converter or intelligent potential distributor.

Another embodiment provides that the coupling element for providing the isolating function comprises at least one controllable switching element, a detection device for detecting the physical value, and a control device for generating a control signal as a function of the physical value for controlling the switching element.

That is to say, the coupling element can be used as an evaluation device, so to speak, in order to diagnose the energy network, that is to say the physical energy on-board network. Thus, for example, the current or the voltage can be determined, or the temperature can be measured, and thus also the energy or power consumption of a respective partial energy network of the energy network.

The named detection device can be designed, for example, as a current sensor, voltage sensor and / or temperature sensor. The control device can in particular be designed as a controller, such as, for example, a microcontroller. The switching element can preferably be designed as a semiconductor switch. Preferably, the semiconductor switch can be operated in a switching mode, that is, in an switched-on switching state, the semiconductor switch is electrically conductive and in a switched-off switching state, the semiconductor switch is not electrically conductive. To provide the reversible separation function the semiconductor switch can be controlled with the help of the control device in particular with the control signal of the control device as a function of the physical value, and thus either switched to the switched-on or the switched-off switching state. The semiconductor switch can, for example, be designed as a field effect transistor, bipolar transistor, thyristor or the like.

Another embodiment provides that the coupling element is designed to decouple the first partial energy network from the second partial energy network only as a function of the physical value when the physical value either exceeds or falls below a predetermined limit value. Similarly, it can be provided that if several physical values are recorded, the coupling element can be designed to decouple the first partial energy network from the second partial energy network as a function of the physical values only if the physical values have an associated, predetermined limit value either exceed or fall below.

If, for example, the coupling element detects a voltage drop due to a short circuit in the first partial energy network and a predetermined voltage limit value, the coupling element can separate the first and second partial energy networks from one another. Of course, this also applies analogously when an overvoltage is detected in the energy network. The limit value can thus in particular be a current limit value, a voltage limit value and / or a temperature limit value.

For example, for normal operation of the second partial energy network, an average supply voltage, that is to say a voltage of at least 9.8 volts, is to be provided. If the voltage of the second partial energy network falls below 9.8 volts for more than one second, for example, the functionality of the second partial energy network can be disrupted. In this case, the coupling element could thus separate the two partial energy networks from one another. If the voltage would drop further from 9.8 volts to less than 8.2 volts and this state would last for more than 200 milli Seconds are maintained, this could also result in a malfunction of the second partial energy network. This also applies analogously in the event that the supply voltage falls below 6 volts for more than 500 microseconds. Thus, for example, the coupling element can provide the reversible disconnection function not only as a function of the predefined limit value but in particular also as a function of a predefined time value. This can be done analogously, for example, for the current or the temperature of the energy network. Depending on the dimensioning of the energy network, the first partial energy network can be separated from the second partial energy network when a current value of more than 300 amps or, for example, more than 1000 amps is determined.

Another embodiment provides that the energy network comprises a low voltage network and a floch voltage network which are coupled to one another via a converter element. The floch voltage network is designed to supply the low-voltage network with energy. In addition to the first and second partial energy networks, the low-voltage network also includes the coupling element.

In other words, the energy network is designed as a multi-voltage energy network, with the reversible separation function only being implemented for the low-voltage network. The low-voltage network and the floch-voltage network therefore each represent an independent sub-network of the energy network.

This energy network architecture is used in particular for modern motor vehicles with electric drive or flybridge drive. In the application, the term "floch voltage network" refers to both so-called high-voltage energy networks with a potential or a nominal voltage of about 60 volts to about 1000 volts, as well as so-called medium-voltage energy networks with a potential or a nominal voltage of about 20 volts to about 60 volts, usually around 48 volts. In contrast, the term “low-voltage network” refers to a so-called low-voltage energy network with a potential or a nominal voltage of approximately less than or equal to 30 volts, usually with a nominal voltage of about 12 volts. In particular, a high-voltage battery and, for example, an electric motor for the electric drive are arranged in the high-voltage network. Thus, so to speak, the high-voltage battery of the high-voltage network supplies the first and second partial energy networks of the low-voltage network.

Another embodiment provides that the high-voltage network is connected to the supply potential via the converter element.

The converter element is preferably designed as a DC / DC converter which can convert a higher potential of the high-voltage network into a lower potential, that is to say the supply voltage for the partial energy networks of the low-voltage network.

Another embodiment provides that a battery is assigned to the second partial energy network for supplying energy. In normal operation of the energy network, the first partial energy network and the second partial energy network are then supplied with energy from the high-voltage network. In the event that the first partial energy network is reversibly decoupled from the second partial energy network, the second partial energy network is then supplied with energy from the battery.

In other words, during normal operation of the energy network, the battery of the second partial energy network is charged, so to speak, from the high-voltage network, that is to say in particular from the high-voltage battery of the high-voltage network. Normal operation is to be understood as the operation of the energy network in the event that there is no malfunction. On the other hand, if a functional disturbance of the first partial energy network is detected and the first partial energy network is accordingly separated from the second partial energy network, the function of the second partial energy network can now be ensured by the battery of the second partial energy network supplying the second partial energy network with energy. The second partial energy network can thus at least temporarily supply itself with energy. This results in the advantage that, particularly if the second partial energy network is safety-relevant components of the energy network, the motor vehicle can continue to be safely steered to a suitable parking location without, for example, steering or braking assistance failing.

Optionally, a separate battery can also be assigned to the first partial energy network so that the entire low-voltage network can still be operated even if the high-voltage network fails.

This results in the advantage that the coupling element can therefore also be used particularly preferably for battery diagnosis, that is to say for example diagnosis of the battery of the first partial energy network. A current or a voltage provided by the battery can thus be recorded and evaluated via the coupling element. From the value of the current or the voltage, conclusions can then be drawn about the charging capacity of the battery and thus about the battery's age.

In particular, the invention also relates to a motor vehicle with an energy network as described above.

The invention also relates to a method for operating an energy network for a motor vehicle. The energy network comprises a first partial energy network which is connected to a supply potential, a second partial energy network and a coupling element which couples the second partial energy network to the supply potential via the first partial energy network. In a step a), a physical value of the first partial energy network is initially recorded. Subsequently, in a step b), depending on the physical value: a control signal is generated for the coupling element. Finally, in a step c), a reversible decoupling of the first partial energy network from the second partial energy network takes place as a function of the control signal. The acquisition of the physical value can take place in particular by means of a acquisition device. Furthermore, the energy network, that is to say in particular the coupling element, can also include a control device which generates the control signal as a function of the physical value, with a switching element of the coupling element in particular being able to be controlled by the control signal. By activating this switching element, the two partial energy networks can then be reversibly decoupled. Alternatively, the physical value itself can also represent the control signal. Thus, the coupling element can be controlled directly with the physical value for connecting or disconnecting the partial energy networks.

The invention also includes further developments of the method according to the invention which have features as they have already been described in connection with the further developments of the energy network according to the invention. For this reason, the corresponding developments of the method according to the invention are not described again here.

The invention also includes the combinations of the features of the described embodiments enclosed.

Exemplary embodiments of the invention are described below. This shows:

Fig. 1 is a schematic block diagram of an energy network for a

Motor vehicle with manual driving function, with a first preferred embodiment of a coupling element with reversible separation function;

FIG. 2 shows the schematic block diagram of an energy network for the motor vehicle with manual driving function, as shown in FIG. 1, with a second preferred embodiment of a coupling element with a reversible separating function; Fig. 3 is a schematic block diagram of an energy network for a

Motor vehicle with a highly automated driving function and a particularly preferred embodiment of the coupling element with a reversible separating function; and

Fig. 4 is a schematic flowchart with individual method steps for operating an energy network which has a coupling element with a reversible isolating function.

The exemplary embodiments explained below are preferred embodiments of the invention. In the Ausführungsbeispie len, the described components of the embodiments each represent individual features of the invention that are to be considered independently of one another and that further develop the invention in each case also independently of one another. Therefore, the disclosure is intended to include combinations of the features of the embodiments other than those shown. Furthermore, the described embodiments can also be supplemented by further features of the invention already described.

In the figures, the same reference symbols denote functionally identical elements.

Fig. 1 shows a schematic block diagram of a preferred Ausfüh approximately example of the energy network according to the invention. The energy network E, also known as the on-board energy network, is designed in particular as an energy network E of a motor vehicle with a manual driving function. The energy network E is divided into two voltage networks, namely a floch voltage network FIV and a low-voltage network NV, the two voltage networks being coupled to one another via a converter element W, namely a DC / DC converter (direct voltage converter). The converter element can thus convert a higher potential of the floch voltage network FIV of about 48 volts into a lower potential of the low voltage network NV of about 12 volts, or vice versa. As described at the beginning, the term “floch volt” in the registration refers to both a floch volt nominal voltage of around 60 volts to 1000 Volts, usually from about 400 volts to 900 volts, as well as a medium-voltage nominal voltage of about 20 volts to about 60 volts, usually about 48 volts. In contrast, the term “low voltage” in the present application relates to a low-voltage nominal voltage of approximately less than or equal to 30 volts, usually a nominal voltage of approximately 12 volts. In the figures, the high-voltage network HV is described in particular as a medium-voltage energy network with a potential of approximately 48 volts.

Both voltage networks have a large number of individual components, also referred to below as consumers. The high-voltage network HV includes as components in addition to a high-voltage battery BHV, a high-voltage consumer RHV and an electrical machine EM. The components of the high-voltage network HV are connected with one connection to a positive potential HV + and with their respective second connection to a ground potential GND. A voltage, that is to say the aforementioned potential of approximately 48 volts, is then preferably applied between the ground potential GND and the positive potential HV + of the high-voltage network HV. In an exemplary embodiment other than the one shown, the high-voltage network HV could also have a potential of approximately 400 volts to 900 volts. In this case the potential would then be applied between the positive potential HV + and a negative potential HV-, not shown in the figures.

In contrast to this, the components of the low-voltage network NV are subdivided into partial energy networks, namely a first partial energy network T1 and a second partial energy network T2. In the exemplary embodiment shown in FIG. 1, the first partial energy network T1 comprises a large number of components, such as a cooling fan element KLE, an infotainment system INF, a navigation system NAV and a radio control RAD. Additionally or alternatively, the first partial energy network T1 could have a sound system control and / or an interior light control for the motor vehicle and / or a trunk. Furthermore, the first partial energy network T1 in FIG. 1 can optionally also include a battery B1 as a component. The components of the first partial energy network T1 are correspondingly non-safety-relevant components for providing a function of the motor vehicle trained. As an alternative to the embodiment shown, the first partial energy network T1 could also comprise only a single component. The one component would then, so to speak, represent the first partial energy network T1.

In order to be supplied with electrical energy, the battery B1 of the first partial energy network T1 is connected to a supply potential KL30.B with a connection. The battery B1 is also connected to the ground potential GND with a second connection. The remaining components of the first partial energy network T1 are also connected to the supply potential KL30.B with a first connection in each case. For this purpose, the individual first connections of the other components are interconnected in a node and thus form a common connection with which the other components are connected to the supply potential KL30.B. The other components of the first partial power network T1 are also connected to the ground potential GND with their respective second connections.

Analogous to the first partial energy network T1, the second partial energy network T2 also has a large number of electrical components, such as a brake control system BRS, a steering system EPS, a wiper control W1, a light control LI and a battery B2. Correspondingly, the components of the second partial energy network T2 are designed as safety-relevant components for providing a function of the motor vehicle. Each of the components of the second partial energy network T2 is connected to a second supply potential KL30.A via a separate first connection. The individual components of the second partial energy network T2 are connected to the ground potential GND with a second connection.

Both between the supply potential KL30.B and the ground potential GND, and between the supply potential KL30.A and the ground potential GND, there is a supply voltage for the first and second partial energy networks T1 and T2, namely the aforementioned low volt potential of about 12 volts. The supply potentials KL30.B and KL30.A preferably represent a supply of the partial energy networks with permanent plus, which is often referred to as “terminal thirty” in vehicle technology.

In addition to the first and second partial energy networks T1 and T2, the low-voltage network NV also has a coupling element K. The coupling element couples the first partial energy network T1 with the second partial energy network T2. In the exemplary embodiment shown in FIG. 1, the coupling element K is connected to the supply potential KL30.B via a first connection and to the second supply potential KL30.A via a second connection. The coupling element K has the function of decoupling the first partial energy network T1 from the second partial energy network T2 in the event of a malfunction of the first partial energy network T1, i.e. in particular one of the components of the first partial energy network T1. The first partial energy network T1 and the second partial energy network T2 can thus be physically separated from one another in a reversible and non-destructive manner in the event of a malfunction. As an alternative to the exemplary embodiment shown in FIG. 1, in addition to the components described above, the first partial energy network T1 could also include the converter element W and the components of the floch voltage network FIV. Thus, the coupling element K could also decouple the second partial energy network V2 from the first partial energy network T2 as a function of at least one physical value of the converter element W and / or one of the components of the floch voltage network FIV.

The embodiment shown in Fig. 1 can be based on the following situation with play. In normal operation of the energy network E, the floch-voltage battery BHV of the floch-voltage network FIV can initially be designed to supply the components of the first partial energy network T1 and the second partial energy network T2 of the low-voltage network NV via the converter element W in addition to the floch-voltage consumers RHV and the electrical machine EM. Battery B1 and the battery are particularly preferred Battery B2 of the first and second partial energy networks T1 and T2 are charged using the high-voltage battery BHV. In normal operation, the supply potentials KL30.B and KL30.A of the first and second partial energy sets T1 and T2 are initially connected to one another via the coupling element K in an electrically conductive manner.

Now one of the components, such as the infotainment system INF of the first partial energy network T1, could have a malfunction, for example in the form of a short circuit. The short circuit could cause the voltage in the low-voltage network NV to collapse. The short circuit in the INF infotainment system could thus cause what is known as consumer feedback for all other components of the low-voltage network. As a result of this consumer reaction, namely the voltage dip, or also voltage drop, there would no longer be sufficient voltage to operate the other components of the first partial energy network T1 and the components of the second partial energy network T2. Both the components of the first partial energy network T1 and the components of the second partial energy network T2 would therefore no longer be functional. Overall, the entire low-voltage network NV of the energy network E would therefore fail.

If the motor vehicle to which the energy network E is assigned were, for example, in a ferry operation, the motor vehicle could no longer be controlled due to failure of the safety-relevant components of the second partial energy network T2. Thus, for example, steering assistance and / or braking assistance would suddenly fail so that the motor vehicle could only be braked or steered with considerable effort. Furthermore, in the event of such a failure of the function of safety-relevant components, such as the steering system EPS or the brake control system BRS, the motor vehicle could also be automatically stopped immediately. The motor vehicle would stop. This would increase the risk of accidents, particularly in road traffic. In order to prevent such a failure of the braking or steering assistance or the motor vehicle stopping, the coupling element K of the energy network E is designed to decouple the non-safety-relevant components of the first partial energy network T1 and the safety-relevant components of the second partial energy network T2. The coupling element has the reversible separation function for the reversible and non-destructive separation of the partial energy networks T1 and T2. In order to realize the reversible separation function, the coupling element K can include, for example, a semiconductor switch which, depending on a physical value of the first partial energy network T1, is electrically conductive in a switched-on switching state or is electrically non-conductive in a switched-off switching state, or vice versa. The physical value represents a current and / or a voltage and / or a temperature of the first partial energy network T1. The semiconductor switch is switched to the non-conductive switching state when the physical value is outside a predetermined value range. In other words, the first partial energy network T1 is, so to speak, electrically separated from the second partial energy network T2 when the physical value either exceeds or falls below a predetermined limit value.

In the case of the aforementioned short circuit in the infotainment system INF, the previously described voltage drop in the first partial energy network T1 would result. This voltage drop could, for example, be detected by the coupling element K and the semiconductor switch of the coupling element K could change its switching state so that the first partial energy network is electrically separated from the second partial energy network. Alternatively, in the event of a short circuit through the coupling element K, an increased current flow from the second partial energy network T2 to the first partial energy network T1 could also be detected. In this case too, the semiconductor switch could disconnect the connection between the first power grid T1 and the second power grid T2.

On the other hand, if, for example, a malfunction in the INF infotainment system due to a software error in the control of the infotainment system ment systems INF are caused, the infotainment system INF, so in particular the infotainment system control, could for example overheat. The overheating of the infotainment system INF could also be detected by the coupling element K. In order to avoid mechanical destruction of the infotainment system INF following overheating, for example, and to counteract the resulting consumer feedback on the safety-relevant components of the second partial energy network T2, the coupling element K, the first partial energy network T1 and the second partial energy network T2 could also be electrically electrical at an early stage in this case separate from each other. The infotainment system control could then be restarted, for example, to rectify the malfunction of the infotainment system INF. This could eliminate the software error in the control of the INF infotainment system and the INF infotainment system would be functional again after the restart. The temperature of the infotainment system INF would drop and the physical value of the first partial energy network would again be in the specified value range. Accordingly, the first partial energy network could be coupled again to the second partial energy network T2 through the coupling element K. The availability of the motor vehicle could thus be improved with the energy network described in FIG. 1.

As long as the two partial energy networks T1, T2 are separated from each other during the malfunction, the components of the second partial energy network T2 can be supplied with energy at least temporarily with the help of the battery B2. This also applies analogously to the battery B1 of the first power supply network in the event that, for example, the floch voltage network FIV fails.

FIG. 2 also shows the schematic block diagram of the energy network E as shown in FIG. In Fig. 2, however, an alternative design of the coupling element K is shown. In the exemplary embodiment shown in FIG. 2, not only the entire partial energy network T1 can be separated from the entire partial energy network T2, that is to say the supply potential KL30.B from the second supply potential KL30.A through the coupling element K. Instead, with the exception of batteries B2, any of the components nenten are separated separately from the supply potential KL30.A. For this purpose, the coupling element K has a large number of switching elements S1 to S5. The switching element S1 is connected between the supply potential KL30.A and the supply potential KL30.B, the common connection of the non-safety-relevant components of the first partial power network T1 being connected to the supply potential KL30.B. In FIG. 2, the optional battery B2 is also connected to the common connection of the non-safety-relevant components of the first partial energy network T1. The switching elements S2, S3, S4 and S5 are arranged analogously between the respective first connection of the brake control system BRS, the steering system EPS, the wiper control Wl and the light control LI and the supply potential KL30.A. By activating the switching elements S1 to S5, each of the components mentioned can thus be separately connected to or separated from the supply potential KL30.A.

Furthermore, in the exemplary embodiment shown in FIG. 2, the coupling element also includes a detection device D by means of which, in particular, the physical value or individual physical values of each of the components of the first and second partial energy networks T1, T2 can be detected. The acquired physical value can then be transmitted from the acquisition device D to a control device C. The control device C is particularly preferably designed to evaluate the physical value and, so to speak, to check whether the physical value is in the predetermined value range. If the physical value of one of the components, for example the non-safety-relevant components of the first partial energy network T1, is outside the specified value range, the control device C can generate a respective control signal S to control the switching element S1 to S5 belonging to the component. By activating the switching element, the malfunctioning component can finally be separated from the supply potential KL30.A. 3 shows a schematic block diagram of an energy network E for a motor vehicle with a highly automated driving function. The high-voltage network HV, the first partial energy network T1 and the second partial energy network T2 are constructed analogously to the exemplary embodiment of the energy network E shown in FIGS. 1 and 2. Instead of the wiper control W1, however, the second partial energy network T2 has a radar system RA as a component.

In addition to the second partial energy network T2 with the safety-relevant components, the energy network E in the exemplary embodiment shown in FIG. 3 also has a third partial energy network T3 to enable the highly automated driving function of the motor vehicle. The third partial energy network T3 comprises electrical components that perform the same function as the electrical components of the second partial energy network T2. The third partial power network T3 is thus redundant to the second partial power network T2.

Correspondingly, the third partial energy network T3 comprises a second radar system RA2, a second brake control system BRS2, a second steering system EPS2 and a second light control LI2. The third partial energy network T3 also includes a battery B3. The battery B3, analogous to the battery B2, enables at least a temporary supply of the remaining components of the third partial energy network T3, in the event that the third partial energy network T3 is decoupled from the first partial energy network T1. All components of the third partial energy network T3 are connected to the components of the second partial energy network T2, each with a first connection to a third supply potential KL30.C and with a respective second connection to the ground potential GND. Between the second supply potential KL30.C and the ground potential GND, there is also approximately a potential of 12 volts in this case. Analogously to the second partial energy network T2, the third partial energy network T3 is also connected to the supply potential KL30.B via a second coupling element Kx. In the exemplary embodiment shown in FIG. 3, however, the coupling elements K and KX differ in their design. The coupling element K between the first partial energy network T1 and the second partial energy network T2 is designed, analogously to the coupling element in FIGS. 1 and 2, for example as an intelligent potential distributor. In contrast to this, the coupling element KX between the first partial energy network T1 and the third partial energy network T3 is designed as a controllable DC / DC converter. The coupling elements are thus also designed redundantly to one another. As an alternative to the embodiment shown in Fig. 3, the Kop pelelemente K and KX could also be designed the same. However, it is often the case that in an energy network E, different battery technologies are used for the batteries B2 and B3 of the second partial energy network T2 and the third partial energy network T3 in order to enable a highly automated driving function. In order to be able to set different voltage levels depending on the battery technology used in the second partial energy network T2 and the third partial energy network T3, it is customary in this case to also implement different coupling elements K and KX to implement the reversible disconnection function.

In the event that a malfunction occurs in one of the non-safety-relevant components of the first partial energy network T1 in the exemplary embodiment shown in FIG. 3, the second and third partial energy networks T2 and T3 can now also be used separately from the first partial energy network to avoid consumer feedback T 1 are decoupled.

FIG. 4 now shows a schematic flow diagram of individual procedural steps for operating an exemplary embodiment of an energy network, as is shown, for example, in one of FIGS. 1 to 3.

The method is started with a start step ST. Subsequently, in a first step 1, the physical value of the first partial energy network T1 is recorded. In a next step 2, the recorded physical value can then be evaluated. It then takes place in a Step 3, checking whether the physical value lies within or outside a predetermined value range. If the physical value is within the predefined value range, step 1 of acquiring a new physical value of the first partial energy network T1 can be carried out again next. If, on the other hand, the physical value is outside the specified value range, a control signal for the coupling element K, in particular for a switching element S1 to S5 of the coupling element K, is generated in a step 4. Subsequently, the coupling element K or the respective associated switching element S1 to S5 can be controlled with the control signal S to enable reversible decoupling of the first partial energy network T1 from the second partial energy network T2 or from the third partial energy network T3. The method is then ended in a step T. Overall, the examples show how the invention can provide a highly available energy network, in particular an energy network architecture, both for manual driving and also for highly automated driving.

Claims

PATENT CLAIMS:

1. Energy network (E) for a motor vehicle, comprising:

- a first partial energy network (T1) that is connected to a supply potential (KL.30.B),

- a second partial energy network (T2), and

- a coupling element (K, Kx), which couples the second partial energy network (T2) to the supply potential (KL.30.B) via the first partial energy network (T1),

characterized in that

- The coupling element (K, Kx) has a reversible separating function, so that the coupling element (K, Kx) is designed, depending on a physical value of the first partial energy network (T1), the first partial energy network (T1) from the second partial energy network ( T2) reversible to be decoupled.

2. Energy network (E) according to claim 1,

characterized in that

the physical value of the first partial energy network (T1) represents an electrical value and / or a temperature value.

3. Energy network (E) according to one of the preceding claims,

characterized in that

- The first partial energy network (T1) comprises at least one non-safety-relevant component (KLE, INF, NAV, RAD) for providing a function of a motor vehicle, and

- The second partial energy network (T2) comprises at least one safety-relevant component (BRS, BRS2, EPS, EPS2, Wi, Li, Li2, Ra, Ra2) for providing a function of a motor vehicle.

4. Energy network (E) according to one of the preceding claims,

characterized in that

the coupling element (K, Kx) is designed as a DC / DC converter or as a switchable potential distributor.

5. energy network (E) according to any one of the preceding claims, characterized in that

the coupling element (K, Kx) for providing the separation function at least one controllable switching element (S1 -S5), a detection device (D) for detecting the physical value, and a control device (C) for generating a control signal depending on the physical Includes value for controlling the switching element (S1 -S5).

6. Energy network (E) according to one of the preceding claims,

characterized in that

the coupling element (K, Kx) is designed to decouple the first partial energy network (T1) from the second partial energy network (T2) only as a function of the physical value when the physical value either exceeds or falls below a predetermined limit value.

7. Energy network (E) according to one of the preceding claims,

characterized in that

- The energy network (E) comprises a low-voltage network (NV) and a high-voltage network (HV), which are coupled to one another via a converter element (W), wherein

- The high-voltage network (HV) is formed, the low-voltage network (NV) with

To provide energy, and

- The first partial energy network (T1), the second partial energy network (T2) and the coupling element (K, Kx) are part of the low-voltage network (NV).

8. energy network (E) according to claim 7,

characterized in that

the high-voltage network (HV) is connected to the supply potential (KL.30.B) via the converter element (W).

9. Energy network (E) according to claim 7 or 8,

characterized in that

- A battery (B2) is assigned to the second partial energy network (T2) for supplying energy, wherein

- In normal operation of the energy network (E), the first partial energy network (T1) and the second partial energy network (T2) are supplied with energy from the high-voltage network (HV), and

- only in the event that the first partial energy network (T1) is reversibly decoupled from the second partial energy network (T2), the second partial energy network (T2) is supplied with energy from the second battery (B2).

10. A method for operating an energy network (E) for a motor vehicle, the energy network (E) comprising:

- a first partial energy network (T1) that is connected to a supply potential (KL.30.B),

- a second partial energy network (T2), and

- a coupling element (K, Kx), which couples the second partial energy network (T2) to the supply potential (KL.30.B) via the first partial energy network (T1),

characterized by the following steps:

a) recording (1) a physical value of the first partial energy network (T1),

b) as a function of the physical value: generating (4) a control signal (S) for the coupling element (K, Kx), and

c) as a function of the control signal (S): reversible decoupling (5) of the first partial energy network (T1) from the second partial energy network (T2).