DE102016204939A1 - Drive device for a hybrid motor vehicle and a method for operating the drive device - Google Patents

Abstract

The invention relates to a drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, comprising an internal combustion engine (13), a first electric machine (10) which is connected to a crankshaft (12) of the internal combustion engine (13). is coupled, and a second electric machine (20) which is coupled to a vehicle drive (21) of the hybrid motor vehicle is executed, wherein the drive device comprises a control unit (17) which is adapted to decouple the first electric machine (10) from the crankshaft (12) of the internal combustion engine (13) above a limit speed of the hybrid motor vehicle and / or above a limit speed of the second electric machine (20) to initiate, and wherein the limit speed and / or the limit speed depending on a required electric power (G) in the hybrid motor vehicle and / or efficiencies of the first electric machine (10) and / or the two iten electrical machine (20) for providing this electrical power (G) and / or by a generator power (L) of the second electric machine (20) is determined.

Description

The invention relates to a drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, with an internal combustion engine, a first electric machine which can be coupled to a crankshaft of the internal combustion engine, and a second electric machine which is connected to a Vehicle drive of the hybrid motor vehicle can be coupled. The invention also relates to a corresponding method.

Modern motor vehicles with an internal combustion engine and a (first) electric machine in the belt drive connected to a crankshaft of the internal combustion engine are known in principle. The electric machine or the belt drive can be coupled by a coupling to a crankshaft of the internal combustion engine. The electric machine can be operated in a generator mode (including recuperation) in order to supply an electric vehicle electrical system of the motor vehicle with electrical energy and to charge a battery. Also, in an engine mode, the electric machine can assist the engine (boost). A clutch between the belt drive and the crankshaft of the internal combustion engine can be closed for these modes of the electric machine. Further, the clutch can be opened to decouple the belt drive from the speed of the engine and thereby reduce the drag losses of the belt drive, whereby the efficiency of the internal combustion engine can be increased. A further (second) electric machine can be operated in a generator mode (including recuperation) in order to supply an electric vehicle electrical system of the motor vehicle with electrical energy and to charge a battery. Also, the second electric machine in a motor mode, the engine support (boosting) and also be used for a purely electric driving. Electromotive powers of about 5 to 15 kW / t are referred to as a mild hybrid motor vehicle.

It has been found to be a disadvantage that the driving behavior and the efficiency of the motor vehicle can be affected by unfavorable operation of the clutch. In particular, it is disadvantageous that two electric machines are always in use with the clutch and the belt drive coupled thereto, the first electric machine, in combination with the losses in the belt drive, reducing the useful mechanical power output by the internal combustion engine and thus leading to increased fuel consumption. On the other hand, it is disadvantageous that some units that are driven by the belt drive, such. As a mechanical air compressor, can not be operated with the clutch open without engine operation of the first electric machine.

The invention is therefore based on the object, at least partially overcome a known from the prior art disadvantage. In particular, it is an object of the present invention to provide an improved drive device and a corresponding method for operating the drive device, which optimize an actuation or switching of a clutch between a first electric machine and the internal combustion engine and an improved driving operation, in particular an improved operation the drive device, and ensure increased ride comfort.

The invention in this case provides a drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, which is provided with an internal combustion engine, a first electric machine that can be coupled to a crankshaft of the internal combustion engine, and a second electrical machine, which is coupled to a vehicle drive or in a transmission of the hybrid motor vehicle is executed. For example. in a parallel hybrid concept, the arrangement of the second electric machine takes place between the drive clutch of the transmission and the wheel.

Furthermore, it can be provided according to the invention that the second electric machine can be coupled directly to the vehicle drive of the hybrid motor vehicle. In this case, it can advantageously be achieved that the second electric machine can be arranged close to the wheel in order to record the kinetic energy with optimum efficiency directly from the drive axle in a generator mode.

Alternatively, the second electric machine can be arranged with the vehicle drive on a non-driven by the engine drive axle or vehicle axle (front / rear) (for example, electrically driven axle with differential and drive shafts to the wheels). Alternatively, the function of the second electric machine can be represented by a plurality of electric machines (for example two wheel hub motors).

Furthermore, it can be provided according to the invention that the first electric machine can be coupled in the belt drive or directly with the crankshaft of the internal combustion engine. Thus, advantageously different structural embodiments of the drive device can be realized, such. B. a parallel hybrid with a spaced first electric machine on a same drive axle or with a spaced first electric machine in the belt drive. Depending on the vehicle model and space requirements in the motor vehicle, one or the other embodiment of the drive device may be advantageous.

According to the invention, the drive device has a control unit which is designed to initiate a decoupling of the first electric machine from the crankshaft of the internal combustion engine above a limit speed of the hybrid motor vehicle, the limit speed depending on a required electrical power in the hybrid motor vehicle, the efficiencies all components involved for the provision of this electrical power and / or is determined by the representable generator power of the second electric machine. Alternatively, the drive device according to the invention a control unit which is adapted to initiate a decoupling of the first electric machine from the crankshaft of the internal combustion engine above a limit speed of the second electric machine of the hybrid motor vehicle, wherein the limit speed of the second electric machine depending on a required electric power in the hybrid motor vehicle, the efficiencies of all components involved for the provision of this electrical power and / or is determined by the representable generator power of the second electric machine.

Under a mild hybrid plus motor vehicle according to the invention a mild hybrid motor vehicle understood, which has two electrical machines. In this case, the first electric machine can start the internal combustion engine, for example during a cold start, a start at standstill and / or a start from the electric drive. The second electric machine can in this case allow a purely electric driving, for example. When the engine is switched off. Both electric machines can be used for boosting, d. H. for electrically increasing the drive torque in addition to the internal combustion engine. Furthermore, both electrical machines can be used for recuperation. The second electric machine can recuperate without the internal combustion engine and the first electric machine with the internal combustion engine.

The control unit according to the invention may be a central control unit in the hybrid motor vehicle, for example an engine control unit, which according to the invention can be upgraded with appropriate software and / or a computer program product to provide an inventive, improved coupling and uncoupling of the first electric machine to the internal combustion engine to enable. Nevertheless, however, the control unit according to the invention can be a specially designed control unit which can enable an inventive, improved coupling and uncoupling of the first electric machine to the crankshaft of the internal combustion engine.

The idea of the invention lies in optimally using the two electric machines in the hybrid motor vehicle in order to increase the efficiency of the overall system and to increase the availability of vehicle air conditioning. For this purpose, a coupling between the first electric machine and the internal combustion engine is opened above a certain limiting speed or limit speed of the second electric machine, which is selected depending on a required electrical power and the overall efficiency in the motor vehicle, and decouples the first electric machine ,

In a decoupled first electric machine, the power generation and supply of the electrical consumers in the hybrid motor vehicle (power requirement) is preferably by the second electric machine (eg. When moving hybrid motor vehicle) or only by way of an energy storage (eg. When stationary hybrid motor vehicle ) accepted. This happens according to the invention always when the second electric machine can supply all consumers in the hybrid motor vehicle efficiently, or in the case when the second electric machine can not be operated as a generator, for. B. when it is used for electric driving or at a standstill of the motor vehicle, only if the energy storage can cover the power needs. The control unit according to the invention monitors the performance of the two electrical machines, their efficiency and / or the state of charge of the energy store. The control unit also monitors the power and energy requirements in the hybrid motor vehicle. The performance of the power generation of the second electric machine (generator power) is in addition to the machine characteristics themselves (torque / power / efficiency characteristics) also dependent on a selected gear ratio. According to the invention, the decoupling time is selected by the control unit in such a way that the gear ratio is taken into account and preferably automatically adapted for a favorable recuperation.

Furthermore, the belt drive / the first electric machine is coupled below a certain, according to the invention specifically determined minimum speed or minimum speed of the second electric machine, which is selected depending on a required electric power in the motor vehicle. For this purpose, a clutch closed between the first electric machine and the internal combustion engine.

In a coupled first electric machine, the power generation and supply of the electrical consumers in the hybrid motor vehicle (electricity demand) by one of the two or possibly by the combination of the two electrical machines (eg. When moving hybrid motor vehicle) or only in the alternative by a Energy storage (eg. When stationary hybrid motor vehicle) taken. The control unit according to the invention monitors the performance of the two electrical machines, their efficiency and / or the state of charge of the energy store. The control unit also monitors the power and energy requirements in the hybrid motor vehicle. The power generation of the two electric machines (generator power) depends not only on the machine characteristics themselves (torque / power / efficiency characteristics) but also on a selected gear ratio or engaged gear of the gearbox. According to the coupling time is selected by the control unit so that the gear ratios are taken into account and preferably automatically adapted for a favorable recuperation.

Furthermore, it is provided according to the invention that hystereses with respect to. Entprellzeit (1s, 5s, 10s), speed (500 1 / min, 1000 1 / min, 1500 1 / min) of the second electric machine, driving speed (5 km / h, 10 km / h, 15 km / h) are taken into account in order to positively influence the driveability or comfort.

Furthermore, in the context of the invention, an air conditioning compressor may be coupled to the belt drive. The drive device according to the invention offers the advantage that components integrated into the belt drive, such as the air conditioning compressor, can be operated via the first electric machine in engine mode and via the belt drive, independently of the rotational speed of the internal combustion engine. In this case, the supply of the first electric machine via the second electric machine in the generator mode and / or via the energy storage can take place. As a result, depending on the cooling power requirement, a free choice of the operating point of the mechanical air conditioning compressor can take place, and thus the cooling capacity can be provided with the best possible efficiency, taking into account the efficiencies and the performance characteristics of the first electric machine, the second electric machine and the air conditioning compressor. The invention offers this advantage, in particular in conjunction with stepped transmissions (manual transmission, automated manual transmission, dual-clutch transmission, torque converter automatic transmission), which do not permit stepless adjustment of the engine speed. Furthermore, a combination with internal combustion engines is advantageous, which reach their maximum power at high speeds (eg MPI). There, with low cooling power requirements and high engine performance (eg. At high speeds or uphill with trailer) the speed of the air compressor can be significantly reduced. Thus, a desired climate performance can always be provided and the ride comfort can thus be significantly improved.

According to the invention, it is provided that the first electric machine can be coupled by a coupling to the crankshaft of the internal combustion engine. The advantage of a switchable coupling between the first electric machine or the belt drive and the crankshaft according to the invention is that while driving, when power can be generated via the second electric machine, or in engine standstill, the belt drive can still be operated. Thus, on the one hand, the belt drive and possibly an air compressor integrated therein can be operated independently of the internal combustion engine and, on the other hand, the internal combustion engine can be relieved while driving, whereby the fuel consumption and pollutant emissions can be reduced. Here, the coupling can be made electrically, hydraulically or electromagnetically switchable. The coupling can, for example. As a non-positive coupling, such as. B. a friction clutch, or as a positive clutch, such. As a jaw clutch be configured. The advantage of a friction clutch is that it can be closed quickly even with speed differences between the engine and the belt drive. The advantage of a positive coupling is that it can be easily and inexpensively designed with low auxiliary energy consumption and good efficiency.

In addition, it is inventively conceivable that the second electric machine can be coupled by a coupling to the vehicle drive of the hybrid motor vehicle. The advantage lies in the fact that, if the second electric machine is not needed, it can be decoupled from the vehicle drive in order to avoid the wear of the second electric machine and at least to reduce drag losses through the second electric machine. It is conceivable that the second electrical machine can be redundantly disconnected from the vehicle drive of the hybrid motor vehicle. In this case, it is conceivable that the second electric machine can be designed as a permanent-magnet synchronous machine, an asynchronous machine, a stepping machine or the like. Thus, the advantage can be achieved that the second electric machine can be operated as an alternative. In addition, it is conceivable that the second electric machine may have a switchable freewheel to the from Vehicle drive of the hybrid motor vehicle torque-free, without a mechanical clutch to be decoupled, and not to affect the mileage.

• a) Abkoppeln der ersten elektrischen Maschine von der Kurbelwelle des Verbrennungsmotors oberhalb einer Grenzgeschwindigkeit des Hybrid-Kraftfahrzeuges, wobei die Grenzgeschwindigkeit in Abhängigkeit von einer erforderlichen elektrischen Leistung im Hybrid-Kraftfahrzeug, der Wirkungsgrade aller beteiligten Komponenten zur Bereitstellung dieser elektrischen Leistung und/oder von einer Generatorleistung der zweiten elektrischen Maschine bestimmt wird.

Furthermore, the object of the invention is achieved by a method for operating a drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, wherein the drive device with an internal combustion engine, a first electric machine which can be coupled to a crankshaft of the internal combustion engine is, and a second electric machine which is coupled to a vehicle drive of the hybrid motor vehicle is designed. The method according to the invention comprises at least one step:

• a) decoupling the first electric machine from the crankshaft of the internal combustion engine above a limit speed of the hybrid motor vehicle, the limit speed depending on a required electrical power in the hybrid motor vehicle, the efficiencies of all the components involved to provide this electrical power and / or of a Generator power of the second electric machine is determined.

Thus, the advantage can be achieved that the electrical and mechanical power is optimally distributed in the hybrid motor vehicle. Furthermore, it is advantageous that a decoupling time is always selected in such a way that both optimum driving behavior and comfort and optimum overall efficiency can be ensured. In particular, it is advantageous that as soon as the second electric machine or, if the second electric machine is required for electrical drive, an energy store is used to supply the electrical consumers in the motor vehicle. Thus, the engine can be relieved and the fuel consumption can be reduced. Of course, other benefits include the same advantages as in the case of the drive device according to the invention which has been described above, to which advantages full reference is made.

• a‘) Ankoppeln der ersten elektrischen Maschine von der Kurbelwelle des Verbrennungsmotors unterhalb einer Mindestgeschwindigkeit des Hybrid-Kraftfahrzeuges und/oder einer Mindestdrehzahl der zweiten elektrischen Maschine,

wobei die Mindestgeschwindigkeit und/oder die Mindestdrehzahl in Abhängigkeit von einer erforderlichen elektrischen Leistung im Hybrid-Kraftfahrzeug, der Wirkungsgrade aller beteiligten Komponenten zur Bereitstellung dieser elektrischen Leistung und/oder von einer Generatorleistung der zweiten elektrischen Maschine bestimmt werden kann. Furthermore, it can be provided according to the invention that the method can have at least one further step:

• a ') coupling the first electric machine from the crankshaft of the internal combustion engine below a minimum speed of the hybrid motor vehicle and / or a minimum speed of the second electric machine,

wherein the minimum speed and / or the minimum speed can be determined as a function of a required electrical power in the hybrid motor vehicle, the efficiencies of all components involved for providing this electrical power and / or a generator power of the second electric machine.

• b) Bestimmen der erforderlichen elektrischen Leistung im Hybrid-Kraftfahrzeug aus einem Bordnetz-Bedarf, einem optionalen Bedarf eines elektrischen Klimakompressors und/oder aus einem Nachlade-Bedarf eines Energiespeichers.

Furthermore, it can be provided according to the invention that the method can have at least one further step:

• b) determining the required electrical power in the hybrid motor vehicle from an onboard power supply requirement, an optional requirement of an electric air conditioning compressor and / or from a recharging requirement of an energy storage device.

In this case, mechanical and electrical properties of the electrical consumers in the hybrid motor vehicle can advantageously be taken into account. The power requirement of the hybrid motor vehicle is composed, for example, together of the need for a 12V vehicle electrical system for most consumers in the motor vehicle (on-board supply), via a DC / DC converter to the network of the two electrical machines (hybrid electrical system) can be connected, from the needs of other consumers who work at the voltage level (or in the voltage range) of the hybrid electrical system, such. B. optional electric air conditioning compressor, electric heater or the like, and from the recharging needs of an energy storage device (hybrid battery), if this previously (eg) by a purely electrical route (partially) was unloaded. On the basis of the total power requirement (12V consumers, 48V or HV consumers, recharge power of the hybrid battery) can finally be determined whether the electrical energy can be efficiently generated at the current driving speed only by the second electric machine or for the internal combustion engine coupled first electrical machine must be used. In this case, the first electric machine can achieve higher generator outputs even at low vehicle speeds due to its configuration or short ratio to the crankshaft. In addition, a division of the generator power to both electrical machines is possible, especially when very high power requirements must be met.

Further measures which improve the invention are described in more detail below with the description of the preferred exemplary embodiments of the invention with reference to the figures. The features mentioned in the claims and in the description may each be essential to the invention individually or in any desired combination. It should be noted that the figures have only descriptive character and are not intended to limit the invention in any way. Show it:

1 a schematic representation of a drive device according to the invention,

2 a schematic representation of two exemplary Abkoppelpunkten according to a method of the invention, and

3 a performance curve of a mechanical air compressor.

In the different figures, the same parts are always provided with the same reference numerals, which is why they are usually described only once.

The 1 shows a drive device according to the invention for a mild hybrid plus motor vehicle, which two electric machines 10 . 20 having. The control unit according to the invention 17 can be designed as an engine control unit, in which the inventive method can be implemented in the form of software or a computer program product. The control unit 17 is thus designed according to the invention, an electrical system 30 to monitor in the hybrid motor vehicle, an optimal time to disconnect and / or to couple a first electric machine 10 from a crankshaft 12 an internal combustion engine 13 to determine to make optimum use of the electrical and mechanical performance in the motor vehicle.

A first electric machine 10 is in the illustrated embodiment of the invention as a starter generator in the belt drive 11 to the internal combustion engine 13 coupled. Alternatively, it is also conceivable that the first electric machine 10 directly to the crankshaft 12 on a same drive axle 12 can be coupled. In both cases, a clutch 14 used, for example, can be designed as a friction clutch. A second electric machine 20 is also to the vehicle drive 21 can be coupled, whether by a mechanical coupling ( 22 ) or a torque-free shutdown or a switchable freewheel.

The first electric machine 10 can the internal combustion engine 13 start. The second electric machine 20 in turn, a purely electric driving over the open clutch 15 of the transmission 16 uncoupled combustion engine 13 enable. Both electrical machines 10 . 20 can be used to increase the drive torque in addition to the internal combustion engine 13 (Boosten) and / or used for recuperation. The second electric machine 20 can do without the internal combustion engine 13 and the first electric machine 10 with the internal combustion engine 13 recuperate in tow mode. The towing mode means that mechanical energy by turning the internal combustion engine 13 is dissipated.

The internal combustion engine 13 is thereby by a driving clutch 15 to a transmission 16 coupled. The crankshaft 12 of the internal combustion engine 13 determined in the illustrated embodiment of the invention, a first drive axle 12 and the vehicle drive 21 a second drive axle 21 (Differential central axis 21 ) The first drive axle 12 and the second drive axle 21 run parallel to each other and are seen in the vehicle longitudinal direction, slightly spaced, one behind the other. According to this embodiment of the invention, the drive device may have seen a compact design in a vehicle transverse direction. Nevertheless, it is also conceivable that the internal combustion engine 13 , The gear 16 and the second electric machine 20 can lie on a same drive axle to reduce the space in the vehicle longitudinal direction.

According to the invention, the second electric machine 20 coupled to the vehicle drive 21 executed. This can either be a classic mechanical coupling 22 be provided or the second electric machine 20 itself can be designed to be redundant and / or torque-free and / or have a switchable freewheel to be switched torque-free. Thus, unnecessary wear of the second electric machine 20 and drag losses through the second electric machine 20 be at least partially reduced.

An electrical wiring system 30 in the motor vehicle has a traction line 31 from the first electric machine 10 , a traction line 32 from the second electric machine 20 , a wiring system distributor 33 , a DC / DC converter 34 to the vehicle electrical system, typically composed of various 12V consumers, and an energy storage 35 on. In addition, as an electrical consumer can at the voltage level of the two electrical machines 10 . 20 be arranged an air conditioning compressor. The air conditioning compressor is for simplicity in the 1 not shown. The total power requirement G in the motor vehicle is thus composed of the demand of the 12V vehicle electrical system (on-board supply), via the DC / DC converter 34 to the network of the two electrical machines 10 . 20 (Hybrid electrical system) is connected, from the needs of other consumers at the voltage level of the hybrid electrical system (48V or HV electrical system), such. As an optional electrified air conditioning compressor, electric heater or the like, and from a recharging needs of the energy storage 35 ,

The invention ensures that the total power requirement G (see the 2 ) can be reliably covered in any driving situation, and without any ride comfort or driving efficiency losses, so that, for example, the air conditioning can be operated on demand and fuel consumption is minimized. The idea of the invention lies in the fact that as soon as the entire power requirement G in driving only by the second electric machine 20 can be most efficiently provided, the clutch 14 between the belt drive 11 and the internal combustion engine 13 is opened. So on the one hand the internal combustion engine 13 On the other hand, the consumers in the belt drive 11 as the air conditioning compressor, regardless of the speed of the internal combustion engine 13 operate. The invention thus ensures that the electrical and mechanical power in the hybrid motor vehicle is optimally divided and utilized.

The 2 shows a characteristic of the maximum generator power L of the second electric machine 20 , The generator power L depends on the vehicle speed V. The characteristic of the maximum generator power L according to the invention in addition to the consideration of the efficiencies for the determination of a favorable belt drive Abkoppelpunktes or a coupling point of the clutch 14 depending on the total power requirement G used. Furthermore, the gear-dependent characteristics (L1, L2, L3, L4, ..., LN) of the maximum generator lines of the first electric machine 10 shown. Exemplary are in the 2 two (belt drive) Abkoppelpunkte P1, P2 for an exemplary vehicle speed V1 (eg, at the rate of 10 km / h) or another exemplary vehicle speed V2 (eg, at the rate of 20 km / h) corresponding to a first exemplary power consumption G1 (eg, at the rate of 1 kW) or a second exemplary power consumption G2 (eg, at the rate of 5 kW). For comparison, with a line GE is an electrical performance of the energy storage 35 shown. From the characteristic of the 2 can thus be determined from which certain vehicle speed V, the second electric machine 20 due to their performance characteristics can cover the entire vehicle electrical system requirements G In addition, the efficiency for the provision of the onboard power supply G is taken into account. If in these Abkoppelpunkten P1 and P2 or at these vehicle speeds V1 / V2 and the overall efficiency for generating the electrical system requirements solely by the second electric machine 20 is superior to the coupled variant, then the first electric machine 10 from the combustion engine 13 be decoupled and the entire power demand G can alone by the second electric machine 20 be covered, including the possibly required additional power consumption of the first electric machine 10 in motor mode to drive the mechanical air conditioning compressor. However, should the current demand G be the currently available maximum generator power L of the second electric machine 20 so can both the first electric machine 10 (the coupling 14 is closed again) the electrical supply in the generator mode as well as both electrical machines 10 . 20 combined to take over the electrical supply.

The 3 shows an exemplary characteristic of a maximum cooling capacity K of a mechanical air conditioning compressor in response to a rotational speed N of the air conditioning compressor. It can be seen that with increasing speed N, a recording power A of the air conditioning compressor increases. The power A is possible between a minimum speed N _min and a limit speed N _{max of} the belt drive. A coefficient C (coefficient of performance) shows the relationship between the cooling capacity K and the absorption capacity A. It can also be seen that this coefficient C is speed-dependent. The higher the value of the coefficient C, the better the efficiency of the air conditioning compressor. If, for example, the motor vehicle is traveling at rotational speed N _akt , but a lower cooling power K is required analogously to the requirement from a point K _opt , a speed reduction in the direction of N _opt is provided on the air-conditioning compressor. For this purpose, the clutch 14 be opened. The first electric machine 10 can then in the engine mode the belt drive 11 driving, with the electrical supply of the first electric machine 10 over the second electric machine 20 or with sufficient energy content and performance of the battery 35 can be done over this. Furthermore, it can also be seen that the motor vehicle with a low vehicle speed corresponding to the rotational speed N _opt can not reach the cooling power of a point K _akt . This can also be the clutch 14 be opened, the drive of the belt drive 11 can then over the first electric machine 10 and the supply of the first electric machine 10 over the second electric machine 20 or with sufficient energy content and performance of the battery 35 done over this. It is thus according to the invention a decoupling strategy for the belt drive 11 about the knowledge of the performance and efficiency relationships between the air conditioning compressor, the first electric machine 10 and the second electric machine 20 and the energy storage 35 proposed.

The 2 and 3 thus show that the electric machine 20 As a result of the arrangement close to the wheel, it has a maximum driving power-dependent maximum generator power. The electric machine 10 uses the gears of the transmission resulting in a lower dependence of the generator power on the driving speed. As the operation of the electric machine 10 but due to the rotating internal combustion engine and belt drive, this leads to additional losses. The electrical storage has a finite extraction capacity and energy, which is why this can not permanently meet the power requirements of consumers in the vehicle. To optimally control the interaction of these three components 2 and 3 the need to record the current power consumption G of the consumers or for recuperation, the current service offering and the current charging and discharging power of the energy storage and vehicle speed and climate performance needs. With this knowledge and the a priori knowledge of the efficiency relationships of the components used, the components and the clutch of the belt drive and the drive clutch of the transmission are controlled such that the fuel consumption is minimized and the ride comfort is increased.

In addition, it is conceivable that at a further limit speed of the motor vehicle, the maximum generator power L of the second electric machine 20 can be achieved. In this case, the clutch 14 be closed again to the electrical energy through both electrical machines 10 . 20 regain. Here, the generator power of the electrical machines 10 . 20 be dependent on the gear ratio. This can be taken into account when determining the above-mentioned vehicle speeds as a belt drive coupling point. The control unit according to the invention 17 In this case, the monitoring of the generator power L, the vehicle speed V and the total power requirement G in the motor vehicle and switches the clutch 14 on or off according to the method of the invention.

The above description of 1 to 3 describes the present invention solely in the context of examples. Of course, individual features of the embodiments, insofar as it is technically feasible, can be freely combined with one another without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

10

first electric machine

11

belt drive

12

crankshaft

13

internal combustion engine

14

clutch

15

clutch

16

transmission

17

control unit

20

second electric machine

21

Vehicle drive / second drive axle

22

mechanical or redundant coupling

30

electrical wiring system

31

Traction line from the first electric machine

32

Traction line from the second electric machine

33

Wiring distributor

34

DC / DC converter

35

energy storage

A

Recording power of the air conditioning compressor

C

coefficient

G

total electricity requirement

K

Cooling capacity of the air conditioning compressor

L

maximum generator power of the second electric machine

L1, L2, L3, L4, LN

 gear-dependent maximum generator power of the first electric machine

N

Speed of the air conditioning compressor

V

vehicle speed

Claims (11)

Drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, with an internal combustion engine ( 13 ), a first electrical machine ( 10 ) connected to a crankshaft ( 12 ) of the internal combustion engine ( 13 ) is coupled, and a second electrical machine ( 20 ) connected to a vehicle drive ( 21 ) of the hybrid motor vehicle can be coupled, wherein the drive device is a control unit ( 17 ), which is designed to disconnect the first electrical machine ( 10 ) from the crankshaft ( 12 ) of the internal combustion engine ( 13 ) above a limit speed of the hybrid motor vehicle and / or limit speed of the second electric machine ( 20 ), and wherein the limit speed of the hybrid motor vehicle and / or limit speed of the second electric machine ( 20 ) as a function of a required electrical power (G) in the hybrid motor vehicle and / or efficiencies of the first electric machine ( 10 ) and / or the second electric machine ( 20 ) for providing this electrical power (G) and / or from a generator power (L) of the second electric machine ( 20 ) is determined. Drive device according to claim 1, characterized in that the control unit ( 17 ) is adapted to a coupling of the first electrical machine ( 10 ) to the crankshaft ( 12 ) of the internal combustion engine ( 13 ) below a minimum speed of the hybrid motor vehicle and / or a minimum speed of the second electric machine ( 20 ), wherein the minimum speed and / or minimum speed of the second electric machine ( 20 ) as a function of a required electrical power (G) in the hybrid motor vehicle and / or efficiencies of the first electric machine ( 10 ) and / or the second electric machine ( 20 ) for providing this electrical power (G) and / or from a generator power (L) of the second electric machine ( 20 ) is determined. Drive device according to claim 1 or 2, characterized in that the first electric machine ( 10 ) in the belt drive ( 11 ) or directly with the crankshaft ( 12 ) of the internal combustion engine ( 13 ), and / or that the second electric machine ( 20 ) with the vehicle drive ( 21 ) of the hybrid motor vehicle can be coupled. Drive device according to one of the preceding claims, characterized in that an air conditioning compressor to the belt drive ( 11 ) can be coupled. Drive device according to one of the preceding claims, characterized in that the second electric machine ( 20 ) with the vehicle drive ( 21 ) of the hybrid motor vehicle on a second non-driven by the internal combustion engine drive shaft is coupled. Drive device according to one of the preceding claims, characterized in that the second electric machine ( 20 ) is represented by a plurality of fixedly coupled or couplable E-machines. Drive device according to one of the preceding claims, characterized in that the first electric machine ( 10 ) by a coupling ( 14 ) to the crankshaft ( 12 ) of the internal combustion engine ( 13 ), and / or that the second electric machine ( 20 ) by a coupling ( 22 ) to the vehicle drive ( 21 ) of the hybrid motor vehicle can be coupled. Drive device according to one of the preceding claims, characterized in that the second electric machine ( 20 ) redundant from the vehicle drive ( 21 ) of the hybrid motor vehicle can be decoupled, and / or that the second electric machine ( 20 ) has a switchable freewheel to the vehicle drive ( 21 ) of the hybrid motor vehicle decoupled torque-free. Method for operating a drive device for a hybrid motor vehicle, in particular for a mild hybrid plus motor vehicle, which is equipped with an internal combustion engine ( 13 ), a first electrical machine ( 10 ) connected to a crankshaft ( 12 ) of the internal combustion engine ( 13 ) is coupled, and a second electrical machine ( 20 ) connected to a vehicle drive ( 21 ) of the hybrid motor vehicle, is designed, comprising at least one step: a) decoupling the first electric machine ( 10 ) from the crankshaft ( 12 ) of the internal combustion engine ( 13 ) above a limit speed of the hybrid motor vehicle and / or a limit speed of the second electric machine ( 20 ) of the hybrid motor vehicle, wherein the limit speed and / or the limit speed as a function of a required electrical power (G) in the hybrid motor vehicle and / or efficiencies of the first electric machine ( 10 ) and / or the second electric machine ( 20 ) for providing this electrical power (G) and / or from a generator power (L) of the second electric machine ( 20 ) is determined. A method according to claim 9, characterized in that the method comprises at least one further step: a ') coupling the first electric machine ( 10 ) to the crankshaft ( 12 ) of the internal combustion engine ( 13 ) below a minimum speed of the hybrid motor vehicle and / or below a minimum speed of the second electric machine ( 20 ) of the hybrid motor vehicle, wherein the minimum speed of the hybrid motor vehicle and / or the minimum speed of the second electric machine ( 20 ) as a function of a required electrical power (G) in the hybrid motor vehicle and / or efficiencies of the first electric machine ( 10 ) and / or the second electric machine ( 20 ) for providing this electrical power (G) and / or from a generator power (L) of the second electric machine ( 20 ) is determined. A method according to claim 9 or 10, characterized in that the method comprises at least one further step: b) determining the required electrical power (G) in the hybrid motor vehicle from a vehicle electrical system requirement and / or an optional electric air compressor requirement and / or an optional electric heater and / or from a recharging requirement of an energy store ( 35 ).

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