EP2559879A1 - Drive unit with two couple-able cooling circuits to preheat a combustion engine and method - Google Patents

Abstract

The unit (1) has a combustion engine (2) and a power electronics unit (5) connected with first and second cooling circuits (10, 20) exhibiting cooling devices (6, 7). The cooling circuit of the combustion engine and the cooling circuit of the power electronics unit are connected through a connector (9) to form a common third cooling circuit (30). An electric motor (4) is connected to one of the cooling circuits, where waste heat occurred by the operation of the electric motor and transported via one of the cooling circuits is used for preheating the combustion engine. An independent claim is also included for a method for preheating a combustion engine of a drive unit for driving a vehicle with electrical energy.

Description

The present invention relates to a drive unit for driving a vehicle drivable with electrical energy according to the preamble of claim 1 and to a method for preheating an internal combustion engine of this drive unit according to the preamble of claim 6.

With electric power operable vehicles, so-called electric vehicles or hybrid vehicles, such as motor vehicles, aircraft, two-wheelers or watercraft, can on the one hand purely electrically, by at least one electric motor as a Tranktionsmotor the drive of the vehicle to be driven automatically accepts, or even in alternating operation, namely once only the electric motor and another time with a run on conventional fuels internal combustion engine.

Purely electrically driven vehicles are known to have no long range, so that after only a few kilometers - depending on the size of the electric motor supplying the battery and the construction of the vehicle - the electric motor due to the discharge of the battery no electrical energy can be supplied. In this case, either an internal combustion engine, such as a diesel, petrol or Wankel engine is switched on, which either takes over the task of the electric motor as a new traction motor and drives the vehicle or in the form of a range extender drives a generator, which the battery or the electric motor generated electrical energy is available to continue to drive the vehicle electrically.

In both cases, it is possible to increase the range of the vehicle from, for example, 30-100km to, for example, 200-400km.

If an internal combustion engine is used as a range extender for expanding the uninterrupted driving operation or for increasing the range, the vehicle additionally has a generator in addition to the internal combustion engine and the electric motor, which is mechanically coupled to the internal combustion engine. The unit of internal combustion engine and generator, which is also referred to as an energy-generating charging device is preferably switched on or activated for the realization of a locally emission-free operation, when the battery for supplying the electric motor with electrical energy can no longer provide sufficient electrical energy.

Furthermore, it is known from the general state of the art that an internal combustion engine which is used as a range extender or traction motor should be operated at a temperature of about 100 ° C. for optimum emission and consumption values.

In contrast, the optimum temperature level of a power electronics, which is also arranged in the vehicle and is used for example for controlling the electric motor and / or the internal combustion engine or the generator, as well as, for example, an electric motor even below 60 ° C. That is, while the electrical system, consisting of the power electronics and the electric motor should be operated at low or low temperatures as possible, it is desirable for the internal combustion engine system, such as the internal combustion engine due to emission and consumption to achieve a defined target temperature as quickly as possible and uphold.

Accordingly, it is the object of the present invention to provide a drive unit and a method by means of which an internal combustion engine of an electrically driven vehicle is preheated substantially continuously during operation of the electric motor by the waste heat, to optimize the emission and / or fuel consumption to achieve while preferably a power electronics unit of the vehicle undergoes optimized cooling.

This object is achieved by the present invention by means of the drive unit according to claim 1 and the method according to claim 6.

Advantageous embodiments and further developments are the subject of the dependent claims.

A drive unit according to the invention for driving a vehicle that can be driven by electrical energy has at least one electric motor driving the motor, at least one generator generating electrical energy, at least one internal combustion engine driving the generator and at least one power electronics unit for driving and / or regulating the electric motor.

The vehicle may be, as mentioned above, an electric vehicle or hybrid vehicle from the fields of motor vehicles, aircraft, watercraft, bicycles or the like.

Preferably, the vehicle is driven purely electrically via at least one electric motor, wherein also each axle of the vehicle may have one or more electric motors for driving the vehicle. In this case, the internal combustion engine can also serve, for example, as a range extender, which is only activated to drive a generator connected to the internal combustion engine in such a way that it generates electrical energy or converts the mechanical energy supplied to it into electrical energy which either the electric motor and / or or the battery is supplied.

As a result, a staggered operation of electric motor operation and internal combustion engine operation takes place. Preferably, the electric motor is also active during operation of the internal combustion engine.

However, it is also conceivable that the vehicle is operated in alternating operation. That is, the vehicle is driven purely electrically, only by the electric motor or a plurality of electric motors during the first few kilometers of driving the vehicle and the internal combustion engine only takes over the drive of the vehicle and possibly a simultaneous charging of the battery when the battery so discharged is that this can no longer provide the electric motor with electrical energy.

The power electronics unit or power electronics preferably has components, such as control devices for controlling and / or regulating the electric machine or the electric motor. These control units include, for example, AC and rectifier for rotating field and DC machines or motors, such as for driving pumps, Fans and for positioning tasks, etc. Also DC converters can be integrated in the vehicle in order to operate preferably consumers with different voltage levels in the electrical energy network can.

In the drive unit according to the invention, at least the internal combustion engine and the power electronics unit are each connected to a cooling circuit having its own cooling device, the first cooling circuit of the internal combustion engine and the second cooling circuit of the power electronics unit being operatively connected to one another via a connecting element to form a common third cooling circuit and at least the electric motor is connected to one of the cooling circuits, that the resulting from the operation of the electric motor and transported over at least one of the cooling circuits waste heat for preheating the internal combustion engine is used.

That is, the internal combustion engine is connected with its own cooling circuit with a cooling device arranged in the cooling circuit, this cooling circuit of the internal combustion engine being referred to as the first cooling circuit.

In addition, the power electronics is also connected to its own, not the first cooling circuit of the engine associated and independently acting cooling circuit, which is referred to as a second cooling circuit and preferably also has its own cooling device.

Consequently, the drive unit of the vehicle has two independently operating cooling circuits, namely the first cooling circuit and the second cooling circuit, in order to be able to cool the internal combustion engine and the power electronics unit separately from one another to a defined temperature or to maintain it at a defined temperature level.

That is, due to different optimum temperature ranges of the internal combustion engine and the power electronics unit, different cooling circuits having different temperature levels are installed in the vehicle.

According to the invention, the first cooling circuit, namely the cooling circuit of the internal combustion engine with the second cooling circuit, namely the cooling circuit of the power electronics unit via a connecting element can be coupled or connected. This connecting element For example, is a supply or discharge and preferably consists of two lines to form a third cooling circuit.

The third cooling circuit is thus composed of the first and the second cooling circuit and the connecting element.

Preferably, a valve element is arranged on the connecting element in order to interrupt or enable the operative connection between the first cooling circuit of the internal combustion engine and the second cooling circuit of the power electronics unit.

That When the valve element or the valve is opened, the first cooling circuit and the second cooling circuit act together as a third cooling circuit, so that in a purely electrical operation of the vehicle, i. during operation of the vehicle exclusively with the electric motor, at least the power electronics unit and preferably also in addition the electric motor can be cooled by means of two cooling devices from two cooling circuits. Thus, the electrical system comprising the power electronics unit and the electric motor, operated for a longer time at low temperatures and thus better efficiencies due to the higher heat capacity of the interconnected cooling circuits, as if the electrical system, only a cooling circuit, such as only the second cooling circuit, would be available.

Only by optimized cooling of the electrical system in contrast to conventionally cooled electrical systems, for example, an increase in efficiency of approximately up to 5% is achieved, which accordingly also the range of the vehicle or the time of uninterrupted driving operation is increased.

In a preferred embodiment, at least the electric motor is connected to the first cooling circuit of the internal combustion engine for substantially direct preheating of the internal combustion engine or to the second cooling circuit of the power electronics unit for substantially indirect preheating of the internal combustion engine via the third cooling circuit.

This means that the electric motor can either be connected to the first cooling circuit, ie the cooling circuit of the internal combustion engine or to the second cooling circuit, ie to the cooling circuit of the power electronics unit.

If the electric motor is connected to the first cooling circuit, the waste heat of the electric motor, which arises during operation of the electric motor, is introduced directly into the first cooling circuit of the internal combustion engine, whereby the temperature level of the first cooling circuit increases. Thus, the internal combustion engine is preheated substantially directly by the waste heat or heat loss of an active consumer connected to the same cooling circuit in that the entire cooling circuit reaches a defined temperature level.

Since preferably an electric motor, as well as a power electronics unit should be operated at temperatures below 60 ° C, it would be conceivable that the temperature level of the first cooling circuit rises to up to 60 ° C and is preferably regulated at this temperature level. As a result, the internal combustion engine is preheated to 60 ° C. and requires a relatively short time until it reaches its optimum operating temperature of, for example, 100 ° C., so that the consumption and emission values of the internal combustion engine are clearly different from the operation of an internal combustion engine which has not been preheated was, can be reduced.

However, it is also known that it may be electric motors and power electronics units, i. There are electrical systems which can be operated at higher temperatures, such as over 60 to 100 ° C and higher. In the presence of such electrical systems, it is therefore possible to preheat the internal combustion engine through the first cooling circuit to 100 ° C and more, so that it already at the beginning of its operation has an optimum temperature level.

When connecting the electric motor to the first cooling circuit, it is conceivable that the second cooling circuit is separated by activation of the valve element from the first cooling circuit to allow a fast and sufficient slope of the temperature level of the first cooling circuit and thus an optimal preheating of the internal combustion engine.

However, it is also possible that both cooling circuits one and two are connected to each other, that is, that the valve element is opened to connect the first cooling circuit and the second cooling circuit to the third cooling circuit. Then, the electric motor and the power electronics unit, which is connected to the second cooling circuit, heat the third cooling circuit together to a defined temperature level by delivery their waste heat during their operation, so as to preheat the non-operating internal combustion engine.

On the other hand, it is also possible that the electric motor with the second cooling circuit, i. the cooling circuit of the power electronics unit is connected. In this case, preferably, the valve element is opened so that an operative connection between the first cooling circuit and the second cooling circuit is formed. Both, i. The power electronics unit and the electric motor are consequently cooled in pure electrical operation of the vehicle of two cooling devices, namely the cooling means of the first cooling circuit and the second cooling means of the second cooling circuit and collectively increase by means of their waste heat the temperature level of the third cooling circuit to preheat the internal combustion engine.

Accordingly, the internal combustion engine is preheated indirectly via consumers, which are arranged on a cooling circuit other than the cooling circuit of the internal combustion engine, via a forming common third cooling circuit.

In a further preferred embodiment, the generator is connected together with the electric motor to the first cooling circuit of the internal combustion engine or to the second cooling circuit of the power electronics unit.

As described above, the drive unit also has a generator for generating electrical energy, which is preferably mechanically connected to the internal combustion engine. However, the generator does not have to be connected to the same refrigeration cycle as the internal combustion engine.

The generator is in purely electrical operation, ie, when only the electric motor during operation and the engine is still deactivated, no waste heat, since it is preferably activated only when an activation of the internal combustion engine to generate electrical energy or mechanical energy in to convert electrical energy.

On the other hand, it is conceivable that the generator is connected separately from the electric motor with the first cooling circuit of the internal combustion engine or with the second cooling circuit of the power electronics unit.

Accordingly, for example, the generator would be connected to the first cooling circuit of the internal combustion engine and the electric motor to the second cooling circuit of the power electronics unit or vice versa.

Furthermore, a method for preheating an internal combustion engine of a drive unit for driving a vehicle drivable with electrical energy is claimed, wherein the drive unit further comprises at least one electric power generating generator and at least one power electronics unit for driving and / or regulating the electric motor.

According to the method according to the invention, at least the internal combustion engine and the power electronics unit are each connected to a cooling circuit having its own cooling devices, the first cooling circuit of the internal combustion engine and the second cooling circuit of the power electronics unit being operatively connected to each other via a connecting element to form a common third cooling circuit and at least the electric motor is connected to one of the cooling circuits, that the waste heat generated by the operation of the electric motor is transported via at least one of the cooling circuits and used for preheating the internal combustion engine.

That is, the waste heat of the consumer, such as preferably the electric motor and / or the power electronics unit, which are connected depending on the configuration of the drive unit with one of the cooling circuits, preferably via the third cooling circuit or even the first cooling circuit is transported to the engine to this to heat to a defined temperature or a defined temperature level.

That is to say, in a preferred embodiment, the electric motor, when connected to the first cooling circuit of the internal combustion engine, heats the internal combustion engine essentially directly via the first cooling circuit, provided at least one valve element arranged on the connection element is closed, and thus an operative connection between the first cooling circuit and the first cooling circuit second cooling circuit prevented.

If a valve element located or arranged on the connecting element is open and allows an operative connection between the first cooling circuit and the second Cooling circuit, the electric motor is therefore connected not only to the first cooling circuit, but also with the third cooling circuit.

Consequently, the waste heat of the electric motor is enabled not only via the first refrigeration cycle but also via the third refrigeration cycle resulting from the first refrigeration cycle, the second refrigeration cycle and the connecting element.

In another preferred embodiment, according to which the electric motor is connected to the second cooling circuit of the power electronics unit, the electric motor heats the internal combustion engine essentially indirectly via the third cooling circuit.

That is, the valve element must be opened so as to allow an operative connection between the first cooling circuit and the second cooling circuit, whereby a third cooling circuit is formed, thus the waste heat of the electric motor and preferably in addition the waste heat of the power electronics, which also with the second Cooling circuit is connected to be able to transport to the first cooling circuit of the engine and in particular directly to the engine and in addition to ensure optimized cooling of the electrical system.

As a result, the power electronics unit, the electric motor and the internal combustion engine are equally connected to the third cooling circuit.

In a further preferred embodiment, it is conceivable that a valve element arranged on the connecting element is opened during a pure operation of the electric motor, in order to additionally cool the power electronics unit additionally with the first cooling circuit of the internal combustion engine.

That is, the power electronics unit not only with the cooling device of the second cooling circuit, with which the power electronics is connected, cooled or regulated to a defined temperature level, but also with the support of the first cooling circuit of the internal combustion engine. Accordingly, the power electronics unit, which is thus connected to the third cooling circuit, cooled by means of at least two cooling means of the third cooling circuit, whereby an optimized cooling of the power electronics and possibly the electric motor is carried out to the efficiency of the increase electrical system.

Furthermore, it is conceivable that a valve element arranged on the connecting element is closed when the second cooling circuit of the electronic power unit has a temperature above a defined maximum temperature level during operation of the internal combustion engine.

This offers the possibility of overheating of the power electronics and optionally of the electric motor, if it is connected to the second cooling circuit of the power electronics unit to prevent by the internal combustion engine is disconnected from the second cooling circuit of the power electronics unit. As a result, no waste heat from the internal combustion engine is transferred to the power electronics and optionally the electric motor via the third cooling circuit, so that the cooling device of the second cooling circuit can regulate the temperature of the power electronics unit or the temperature level of the second cooling circuit again to an optimum value.

Further advantages, objects and characteristics of the present invention will be explained with reference to the following description of the appended drawing, in which exemplary embodiments of the drive unit according to the invention with at least two cooling circuits are shown.

Components which at least substantially coincide in the figures with respect to their function may in this case be identified by the same reference symbols, these components not having to be identified and explained in all figures.

Fig.1

eine Prinzipskizze einer ersten Ausführungsform einer erfindungsgemäßen Antriebseinheit; und

Fig.2

eine Prinzipskizze einer zweiten Ausführungsform einer erfindungsgemäßen Antriebseinheit.

In the figures show:

Fig.1

a schematic diagram of a first embodiment of a drive unit according to the invention; and

Fig.2

a schematic diagram of a second embodiment of a drive unit according to the invention.

Fig.1 shows a schematic diagram of a first embodiment of a drive unit 1 according to the invention, which is an internal combustion engine 2, a generator 3, an electric motor 4, a power electronics unit 5, a first cooling device 6 and a second cooling device 7.

The internal combustion engine 2, the cooling device 6 and the electric motor 4 and the generator 3 are connected in common with a first cooling circuit 10. In this first cooling circuit 10, a cooling medium, which may have a liquid or gaseous state, transported via corresponding lines 10a to 10d, to absorb waste heat consumers 2, 3, 4 and the cooling device 6, which absorbs the heat and to the Environment gives off.

During operation of the electric motor 4 and of the internal combustion engine 2 and consequently also of the generator 3, waste heat is generated which, if it is not to be used to increase the temperature level of the first cooling circuit 10, for example via cooling medium of the cooling device 6 flowing in the lines 10a and 10b supplied and discharged from this to the environment. In this case, the cooling device 6 operates as a kind of heat exchanger. The cooled by the cooling device 6 cooling medium, which consequently the waste heat of consumers 2, 3, 4 was withdrawn, now flows over, for example, the lines 10c and 10d to the consumers 2, 3, 4 back to absorb waste heat from these can and can Consequently, to cool them or to regulate their temperature.

Preferably, before activation of the internal combustion engine 2, the waste heat of the electric motor 4 in operation - the generator 3 is also deactivated - not discharged via the cooling device 6 to the environment, but used to increase the temperature level of the first cooling circuit 10. In other words, the cooling medium absorbs the waste heat emitted by the electric motor 4 until it reaches a defined temperature level and preferably delivers it to the internal combustion engine 2 in order to preheat it substantially continuously even during non-operation of the internal combustion engine 2.

A cooling device 7 comparable to the cooling device 6 as well as a power electronics unit 5 are shown in FIG Fig.1 connected to the second cooling circuit 20. Via lines 20a and 20b, a cooling medium is transported between the cooling device 7 and the power electronics unit 5 in order, for example, to absorb waste heat generated by the operation of the power electronics unit 5 and to transport it via the line 20a to the cooling device 7.

In particular, in the case of a closed or deactivated valve 8 or valve element 8, there is no active connection via the connecting element 9 between the first cooling circuit 10 and the second cooling circuit 20. Thus, the waste heat generated by the power electronics unit 5 is transported directly to the cooling device 7 by means of the cooling medium and discharged from it to the environment. Accordingly, the cooling device 7 of the second cooling circuit 20 operates as a kind of heat exchanger to release the heat extracted from the cooling medium to the environment, so that the cooling medium, for example via the line 20b back to the consumer 5, i. the power electronics unit 5 can be transported in order to again absorb waste heat of the power electronics unit 5 there.

The third cooling circuit 30 is primarily formed in an activated or open valve element 8, which is an operative connection, i. allows a flow or a movement of the cooling medium from the first cooling circuit 10 to the second cooling circuit 20 and back and from the second cooling circuit 20 to the first cooling circuit 10 and back.

In this case, the cooling media of the cooling circuits 10 and 20 flow via a connecting element 9, which preferably comprises two lines 9a and 9b transporting the cooling media.

As a result, the third cooling circuit 30 consists of the first cooling circuit 10, the second cooling circuit 20 and the connecting element 9 and accordingly of the lines 10a, 10b, 10c, 10d, 20a, 20b, 9a, 9b of the cooling circuits 10, 20, 30th

For measuring temperatures at the consumers 2, 3, 4.5 or temperature levels of the cooling circuits 10, 20, 30 preferably heat sensors (not shown here) are used, which either directly in the range of a consumer 2, 3, 4, 5 or a line 10a, 10b, 10c, 10d, 20a, 20b, 9a, 9b of one of the cooling circuits 10, 20, 30 may be arranged.

Furthermore, ventilation elements 11, 12 may be arranged on the cooling circuits 10, 20, 30 and preferably in the area of the cooling devices 6 and 7 in order, for example, to dissipate the heat given off by the cooling devices 6 and 7 to the environment in such a way that they do so is not moved in the direction of the consumer 2, 3, 4, 5, which should be cooled if necessary.

According to the embodiment of the Fig.1 is in a purely electrical operation, ie during the period in which only the electric motor 4 is active, the waste heat of the electric motor 4 at a closed valve element 8 via the first cooling circuit 10 and an open valve element 8 via the third cooling circuit 30 to the engine 2 to preheat this. Also, the waste heat of the power electronics unit 5 is transferred at an open valve element 8 via the third cooling circuit 30 also to the engine 2 for preheating the latter.

The electric motor 4 and the power electronics unit 5 are also cooled by two cooling devices 6 and 7 with an open valve element 8, whereby the efficiency of these consumers 4 and 5 can be increased.

In the Fig.2 a schematic diagram of a second embodiment of the drive unit 1 according to the invention is shown, which differs from the embodiment of the Fig.1 differs in that the electric motor 4 and the generator 3 are connected to the second cooling circuit 20 of the power electronics unit 5. By way of a cooling medium also flowing through the corresponding lines 20b, 20d of the second cooling circuit 20, the waste heat of the consumers 3 and / or 4 in operation is transported to the cooling device 7.

If only the electric motor 4 and the power electronics 5 are in operation to drive the vehicle, the valve element 8, for example, is opened in order to establish an operative connection with the first cooling circuit 10, with which now only the internal combustion engine 2 is connected.

The electric motor 4 and the power electronics 5 are consequently connected via the third cooling circuit 30 to the internal combustion engine 2 in order to preheat it by means of its waste heat, which is transported via the cooling medium or the cooling media and, consequently, to be cooled simultaneously by means of two cooling circuits.

According to the embodiment of the Fig.2 Consequently, the internal combustion engine 2 is preheated substantially indirectly via the third cooling circuit by the waste heat of the consumers 4 and 5 in order to enable optimized emission and consumption values when the internal combustion engine 2 is put into operation.

After reaching a maximum temperature of the second cooling circuit 20, the valve element 8 is preferably closed and the first cooling circuit 10 separated from the second cooling circuit 20 or disconnected to overheat the electrical system 4, 5 or the power electronics unit 5 and / or the electric motor to prevent.

This is also in the embodiment of the drive unit 1 according to the invention according to the Fig.1 possible.

Preferably, the first cooling circuit 10 is referred to as a high-temperature circuit 10 and the second cooling circuit 20 as a low-temperature circuit 20.

The high-temperature circuit 10 may preferably have a higher temperature level than the low-temperature circuit 20.

The Applicant reserves the right to claim all features disclosed in the application documents as essential to the invention, provided that they are novel individually or in combination with respect to the prior art.

LIST OF REFERENCE NUMBERS

1

drive unit

2

internal combustion engine

3

generator

4

electric motor

5

Power electronics unit with

6, 7

cooling device

8th

valve element

9

connecting element

10

first cooling circuit

11, 12

ventilation element

20

second cooling circuit

30

third cooling circuit

Claims (10)

Drive unit (1) for driving a vehicle drivable with electrical energy with at least one electric motor (4) driving the vehicle, at least one generator (3) generating the electrical energy, at least one internal combustion engine (2) driving the generator (3) and at least one power electronics unit (5) for driving and / or regulating the electric motor (4),
characterized in that
at least the internal combustion engine (2) and the power electronics unit (5) are each connected to a cooling circuit (10, 20) having its own cooling device (6, 7), the first cooling circuit (10) of the internal combustion engine (2) and the second cooling circuit ( 20) of the power electronics unit (5) via a connecting element (9) in operative connection to form a common third cooling circuit (30) with each other and at least the electric motor (4) with one of the cooling circuits (10, 20, 30) is connected, that the by the operation of the electric motor (4) resulting and at least one of the cooling circuits (10, 20, 30) transported waste heat for preheating the internal combustion engine (2) is usable. Drive unit according to claim 1,
characterized in that
a valve element (8) is arranged on the connecting element (9) in order to interrupt or enable the operative connection between the first cooling circuit (10) of the internal combustion engine (2) and the second cooling circuit (20) of the power electronics unit (5). Drive unit according to one of the claims 1 or 2,
characterized in that
at least the electric motor (4) with the first cooling circuit (10) of the internal combustion engine (2) for substantially direct preheating the internal combustion engine (2) or with the second cooling circuit (20) of the power electronics unit (5) for Substantially indirect preheating the internal combustion engine (2) via the third cooling circuit (30) is connected. Drive unit according to one of the preceding claims,
characterized in that
the generator (3) is connected together with the electric motor (4) to the first cooling circuit (10) of the internal combustion engine (2) or to the second cooling circuit (20) of the power electronics unit (5). Drive unit according to one of the preceding claims
characterized in that
the generator (3) is connected to the first cooling circuit (10) of the internal combustion engine (2) or to the second cooling circuit (20) of the power electronics unit (5) separately from the electric motor (4). Method for preheating an internal combustion engine (2) of a drive unit (1) for driving a vehicle drivable with electrical energy, wherein the drive unit (1) additionally comprises at least one generator (3) generating electrical energy and at least one power electronics unit (5) for driving and / or or rules of the electric motor (4),
characterized in that
at least the internal combustion engine (2) and the power electronics unit (5) are each connected to a cooling circuit (10, 20) having its own cooling devices (6, 7), the first cooling circuit (10) of the internal combustion engine (2) and the second cooling circuit ( 20) of the power electronics unit (5) via a connecting element (9) in operative connection to form a common third cooling circuit (30) with each other and at least the electric motor (4) is connected to one of the cooling circuits (10, 20, 30), that the Waste heat produced by the operation of the electric motor (4) is transported via at least one of the cooling circuits (10, 20, 30) and used for preheating the internal combustion engine (2). Method according to claim 6,
characterized in that
the electric motor (4) when connected to the first cooling circuit (10) of the internal combustion engine (2) the internal combustion engine (2) heated substantially directly over the first cooling circuit (10). Method according to claim 6,
characterized in that
the electric motor (4), when connected to the second cooling circuit (20) of the power electronics unit (5), heats the internal combustion engine (2) substantially indirectly via the third cooling circuit (30). Method according to one of claims 6 to 8,
characterized in that
a valve element (8) arranged on the connecting element (9) is opened during a pure operation of the electric motor (4) in order to additionally cool the power electronics unit (5) with the first cooling circuit (10) of the internal combustion engine (2). Method according to one of claims 6 to 9,
characterized in that
a valve element (8) arranged on the connecting element (9) is closed when the second cooling circuit (20) of the power electronics unit (5) has a temperature above a defined maximum temperature level during operation of the internal combustion engine (2).

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