DE102016114743A1 - Method for operating a hybrid drive system and motor vehicle with a hybrid drive system - Google Patents

Abstract

The invention relates to a method for operating a hybrid drive system (1) of a motor vehicle (2), wherein the hybrid drive system (1) has at least one main motor (3) and a first electric motor (4) and a second electric motor (5) Main motor (3) and the first electric motor (4) via a first transmission (6) and the second electric motor (5) via a decoupling device (7) and via a second transmission (7) with a common drive axle (8, 8a, 8b) or with separate drive axles (8, 8a, 8b) of the motor vehicle (2) are coupled. Furthermore, the invention relates to a motor vehicle (2) with a hybrid drive system (1), wherein the hybrid drive system (1) is designed for carrying out the method according to the invention.

Description

The invention relates to a method for operating a hybrid drive system of a motor vehicle, wherein the hybrid drive system has at least one main motor and a first electric motor and a second electric motor, wherein the main motor and the first electric motor via a first transmission and the second electric motor via a second transmission with a common drive axle or with separate drive axles of the motor vehicle are coupled. Furthermore, the invention relates to a motor vehicle with a hybrid drive system.

In addition to vehicles with conventional drive systems, which are based on the principle of combustion of an energy source, in particular fossil origin, a variety of alternative drive concepts is known in which a drive torque is at least partially realized by an electric motor. Alternative drive systems which, in addition to a conventional internal combustion engine, additionally have at least one electric motor coupled to the drive train, are also referred to as hybrid drive systems.

In hybrid vehicles, a distinction is essentially made between three hybrid vehicle types, the micro-hybrid, mild hybrid and full hybrid vehicles. The micro-hybrid here represents an exception, since an electric motor built in the vehicle is designed in particular for the recovery of braking energy and for starting the internal combustion engine. The drive torque is provided in micro-hybrid vehicles without the assistance of the electric motor from the internal combustion engine. Mild hybrid vehicles basically have the same features as micro hybrid vehicles, wherein the electric motor is also designed to support the internal combustion engine in the provision of the drive torque. The electric motor thus serves to increase the power of the vehicle, but is not suitable for driving the motor vehicle without support of the internal combustion engine. A complete provision of the drive torque by the electric motor, however, is possible in a full hybrid vehicle.

Furthermore, modern hybrid or purely electric drive concepts are known in which a plurality of electric motors for driving the vehicle are present. The motors can be designed to deliver the drive torque to a vehicle axle or to different vehicle axles. In a known drive concept, an internal combustion engine and a first electric motor are coupled via a first transmission with a first vehicle axle and a second electric motor via a second transmission with a second vehicle axle. To reduce vehicle costs, the second transmission is equipped with only one gear, wherein the first transmission is a multi-speed transmission.

According to a known method for operating such a drive concept, when the vehicle is driven for maximum acceleration, at least the second electric motor and the internal combustion engine are operated at maximum power up to a first time. From the first point in time, the engine power of the second electric motor is reduced to zero with a high gradient to a second time to allow the second electric motor to decouple from the vehicle axle. Between the second time and a third time, the second electric motor is decoupled from the second vehicle axle so as not to exceed a maximum speed of the second electric motor. During the reduction of the engine power of the second electric motor, an engine power of the first electric motor is possibly increased in combination with the internal combustion engine, unless these components are already operated at their power limit and / or not yet the max. permissible transmission input torque has been reached. This method has the disadvantage that as soon as the power reduction at the second electric motor can not be completely compensated by the first electric motor and / or internal combustion engine or is carried out with an unfavorable torque gradient during the uncoupling process, a noticeable jerk of the vehicle occurs for the driver, as a result of which driving comfort is adversely affected.

It is therefore the object of the present invention to provide a method for operating a hybrid drive system of a motor vehicle as well as a motor vehicle with a hybrid drive system, which eliminate or at least partially remedy the above disadvantages. Accordingly, it is the object of the present invention to provide a method for operating a hybrid drive system of a motor vehicle and a motor vehicle with a hybrid drive system, which ensure a simple and cost-effective manner improved comfort when disengaging an electric motor during acceleration of the motor vehicle.

The above problem is solved by the claims. Accordingly, the object is achieved by a method for operating a hybrid drive system of a motor vehicle according to independent claim 1 and by a motor vehicle having a hybrid drive system according to independent claim 10. Other features and details of the invention will become apparent from the dependent claims, the description and the Drawings. In this case, features and details that are described in connection with the method according to the invention for operating a hybrid drive system of a motor vehicle, of course, in connection with the motor vehicle according to the invention with a hybrid drive system and in each case vice versa, so that with respect to the disclosure of the individual invention aspects always mutually Reference is or can be made.

• – Registrieren eines Beschleunigungsbefehls für das Kraftfahrzeug mittels einer Steuereinheit,
• – Ansteuern des Hauptmotors sowie des zweiten Elektromotors zum Übertragen eines Antriebsmoments auf mindestens eine der Antriebsachsen zum Beschleunigen des Kraftfahrzeugs, wobei das Ansteuern mittels der Steuereinheit sowie auf Basis des Beschleunigungsbefehls erfolgt,
• – Ermitteln eines dritten Zeitpunkts zu dem der zweite Elektromotor bei aktueller Beschleunigung eine Grenzmotordrehzahl, die geringer als eine Maximalmotordrehzahl des zweiten Elektromotors ist, erreichen würde, wobei das Ermitteln mittels einer Kontrolleinheit erfolgt,
• – Berechnen eines zweiten Zeitpunkts zum Initiieren eines Abkuppelns des zweiten Elektromotors von der Antriebsachse derart, dass der zweite Elektromotor zum dritten Zeitpunkt von der Antriebsachse entkoppelt ist, wobei das Berechnen mittels der Kontrolleinheit erfolgt,
• – Bestimmen eines ersten Zeitpunkts zum Initiieren einer Motorleistungsreduktion des zweiten Elektromotors derart, dass der zweite Elektromotor zum zweiten Zeitpunkt drehmomentfrei mit der Antriebsachse dreht und der Gradient zur Reduzierung der Motorleistung, der aus der Kenntnis der gangabhängigen Schwingungseigenschaften des Triebstrangs in Kombination mit dem Fahrzeug bestimmt wird, keine komfortbeeinträchtigenden Längsschwingungen verursacht, wobei das Bestimmen mittels der Kontrolleinheit erfolgt,
• – Reduzieren der Motorleistung des zweiten Elektromotors ab dem ersten Zeitpunkt bis zum zweiten Zeitpunkt mit einem ersten Drehmomentgradienten derart, dass der zweite Elektromotor zum zweiten Zeitpunkt drehmomentfrei oder im Wesentlichen drehmomentfrei mit der Antriebsachse dreht, wobei das Reduzieren mittels der Steuereinheit erfolgt,
• – Erhöhen der Motorleistung des ersten Elektromotors ab dem ersten Zeitpunkt mit einem zweiten Drehmomentgradienten vor dem zweiten Zeitpunkt derart, dass der erste Elektromotor zum zweiten Zeitpunkt eine Motorleistung bereitstellt, die einer Motorleistung des zweiten Elektromotors zum ersten Zeitpunkt entspricht oder im Wesentlichen entspricht, wobei das Erhöhen mittels der Steuereinheit erfolgt, und
• – Initiieren eines Auskuppelvorgangs einer Kupplung, über die der zweite Elektromotor mit der Antriebsachse gekoppelt ist, zum zweiten Zeitpunkt mittels der Steuereinheit derart, dass der zweite Elektromotor zum dritten Zeitpunkt von der Antriebsachse abgekuppelt ist.

According to a first aspect of the invention, the object is achieved by a method for operating a hybrid drive system of a motor vehicle. The hybrid drive system has at least one main engine and a first electric motor and a second electric motor, wherein the main motor and the first electric motor via a first transmission and the second electric motor via a second transmission with a common drive axle or with separate drive axles of the motor vehicle are coupled. The method comprises the following steps:

• Registering an acceleration command for the motor vehicle by means of a control unit,
• Driving the main motor and the second electric motor for transmitting a drive torque to at least one of the drive axles for accelerating the motor vehicle, the drive being effected by means of the control unit and on the basis of the acceleration command,
• Determining a third point in time at which the second electric motor would achieve a limit engine speed, which is lower than a maximum engine speed of the second electric motor, with current acceleration, the determination taking place by means of a control unit,
• Calculating a second time for initiating decoupling of the second electric motor from the drive axle such that the second electric motor is decoupled from the drive axle at the third time, wherein the calculation is performed by means of the control unit,
• Determining a first time for initiating engine power reduction of the second electric motor such that the second electric motor rotates torque-free with the drive axle and the gradient for reducing engine power determined from knowledge of the driveline's gear-dependent vibration characteristics in combination with the vehicle , causes no comfort-impairing longitudinal vibrations, wherein the determination is carried out by means of the control unit,
• Reducing the engine power of the second electric motor from the first time to the second time with a first torque gradient such that the second electric motor rotates torque-free or substantially torque-free with the drive axle at the second time, wherein the reduction takes place by means of the control unit,
• Increasing the engine power of the first electric motor from the first time with a second torque gradient before the second time such that the first electric motor provides engine power at the second time corresponding to or substantially equal to engine power of the second electric motor at the first time, the increasing by means of the control unit, and
• Initiate a disengaging operation of a clutch, via which the second electric motor is coupled to the drive axle, at the second time by means of the control unit such that the second electric motor is disconnected from the drive axle at the third time.

The main engine is preferably as an internal combustion engine, e.g. as a diesel or gasoline engine trained. The main engine and the first electric motor are coupled via a first transmission with a drive axle of the motor vehicle. The second electric motor is coupled via a second transmission to a drive axle of the motor vehicle, which is preferably different from the drive axle, which is coupled to the main engine. The first transmission is preferably designed as a multi-stage transmission. The second transmission is preferably designed as a single-stage transmission.

By means of a control unit of the motor vehicle, an acceleration command for the motor vehicle is registered. An acceleration command is, for example, an operation of an accelerator pedal or an input to an on-board computer of the motor vehicle.

On the basis of the acceleration command, the main motor, possibly in combination with the first electric motor, and the second electric motor are actuated by the control unit for accelerating the motor vehicle. According to the invention, additional current driving data, such as e.g. Vehicle speed, vehicle acceleration or the like are taken into account. By driving the main motor, possibly in combination with the first electric motor and the second electric motor drive torques are generated by these motors and passed on to the respective drive axle.

By means of a control unit of the motor vehicle, a third time is determined at which the second electric motor would achieve a limit engine speed at a current acceleration, which is less than a maximum engine speed of the second electric motor. The maximum engine speed of the second electric motor is a speed that should not exceed the second electric motor or may otherwise the risk of damage to the second electric motor consists. The limit engine speed is defined as an engine speed that is close to the maximum engine speed, such as 90%, better 95%, and ideally 98% of the maximum engine speed, with no risk of damaging the second electric motor at the limit engine speed. The third time is therefore a point in time at which the second electric motor should be disconnected from the drive axle in order to avoid the danger of damage to the second electric motor with certainty. Thus, the risk of damage to the second electric motor is reduced by the inventive method.

Furthermore, a second point in time is calculated by means of the control unit, to which a decoupling of the second electric motor from the drive axle is to be initiated so that the second electric motor is decoupled from the drive axle at the third time. The second time is therefore before the third time. For the determination of the second time point, for example, a minimum disengaging period of a clutch is considered, via which the second electric motor is coupled to the drive axle or the second transmission. The term "minimum disengaging duration" is understood to mean a period of time which the clutch at least requires in order to get from an engaged state to a disengaged state. It is preferred that this time span is chosen as low as possible. The minimum disengaging period is essentially defined by the construction of the coupling. When calculating the second time, it is preferable that a safety factor is taken into account. This can for example be done so that a Auskuppeldauer is based, which is at least slightly longer than an actual minimum Auskuppeldauer the clutch by means of a safety surcharge. In this way, a security of the method is increased.

Furthermore, a first time is determined by means of the control unit, to which a reduction of the engine power of the second electric motor is to take place so that the second electric motor rotates torque-free with the drive axle at the second time. The first time is therefore before the second time. Torque-free or load-free referred to in the context of the invention, a state in which a disengaging of the clutch of the second electric motor can be initiated easily, without causing damage to the clutch and / or without causing a Fahrkomfortmindernden jerk during disengaging. In this case, a degree of reduction of the engine power is preferably taken into account, taking into account the gear ratio acting in each case in the two transmissions, in which the ride comfort is not adversely affected, in particular in which no jerk reducing the driving comfort occurs.

By means of the control unit, the engine power of the second electric motor is reduced from the first time until the second time such that the second electric motor rotates torque-free or substantially torque-free with the drive axle at the second time. Within the same time interval, the engine power of the first electric motor is increased by means of the control unit in such a way that the first electric motor provides an engine power at the second time which corresponds or essentially corresponds to an engine power of the second electric motor at the first time. In other words, a reduction of the engine power of the second electric motor is compensated by an increase in the engine power of the first electric motor, possibly in combination with an increase in the engine power of the internal combustion engine. A total power of the hybrid drive system is thus constant or substantially constant. Between the first time and the second time, the drive torque is provided by the main motor, the second electric motor and the first electric motor.

At the second time, a disengaging operation of a clutch is initiated by means of the control unit, via which the second electric motor is coupled to the drive axle or to the second transmission, so that the second electric motor is decoupled from the drive axle at the third time. At the third time, the drive torque is thus provided by the main motor and the first electric motor.

The method according to the invention for operating a hybrid drive system has the advantage over prior art methods that a substantially constant additional drive torque is provided by the first electric motor and the second electric motor to the main motor during the acceleration process. Thus, in particular during the decoupling process of the second electric motor, no drive torque step occurs which greatly reduces the ride comfort. Due to the complete or essentially complete compensation of the drive torque of the second electric motor by the first electric motor at the time of disengagement of the second electric motor, a jerk is effectively avoided and the ride comfort during this operating range is thus increased.

Preferably, reducing the engine power of the second electric motor from the amount corresponds to increasing the engine power of the first electric motor. In this way it is ensured that a sum of the drive torques of the first electric motor and the second electric motor is constant and the drive torque of the second electric motor is thus completely compensated by the first electric motor. This has the advantage that a particularly high ride comfort is provided.

It can be inventively provided that the reduction of the engine power of the second electric motor with a constant second gradient and / or that the increase of the motor power of the first electric motor is carried out with a constant first gradient. The reduction and increase in engine power is therefore linear or constant and thus particularly advantageous for ride comfort.

Further preferably, when determining the gradients, a gear-dependent vibration behavior of the drive axles coupled to the electric motors is taken into account such that vibrations of the drive axles are reduced. A reduction of the engine power of the first and / or second electric motor causes at unfavorably selected gradient swinging coupled to the respective electric motor drive axle. An amplitude of this oscillation depends on the respective gradient. Too large an amplitude has a negative impact on ride comfort. In order to increase the driving comfort, a vibration behavior of the respective drive axle must therefore be taken into account when selecting the two respectively controlled gradients.

In an advantageous embodiment of the method, the flatter one of the two calculated gradients, which is decisive for the time period t1-t2, is taken into account for calculating the first time. In this way, a particularly accurate calculation of the first time is possible.

According to a preferred embodiment of the method according to the invention is for determining the third time a loading state of the motor vehicle and / or a gradient or a gradient of a slope of a road and / or air resistance of the motor vehicle and / or an actual speed of the motor vehicle and / or a Rolling resistance and / or a Reifenlatsch and / or a performance characteristic of the drive system and / or a theoretical acceleration command for a maximum acceleration considered. These parameters can influence an acceleration behavior of the motor vehicle. The air resistance depends in particular on the cw value, a transverse surface area of the motor vehicle, the air density and the vehicle speed. By taking into account such parameters, a particularly accurate determination of the third time point is possible in an advantageous manner.

Preferably, the second electric motor is controlled before reducing the engine power in such a way that the engine power provided by the second electric motor corresponds to or at least substantially corresponds to a maximum engine power of the first electric motor. In this way, a complete or almost complete compensation of the drive torque of the second electric motor by the first electric motor is possible. Furthermore, thus the main motor an additional drive torque can be provided, which is constant over the entire acceleration process and has no drive torque jump. Furthermore, this provides a particularly high level of ride comfort.

It is preferred that the second electric motor via the second transmission has a lower maximum speed than the first electric motor via the first transmission. The second transmission preferably has only one gear, wherein the second electric motor with the second transmission is preferably designed for starting the motor vehicle and for medium speeds. Such a drive system is particularly inexpensive.

More preferably, the third time is set such that a speed of the second electric motor at the third time is 90%, better 95% and ideally 98% of the maximum permissible speed of the second electric motor. In this way it is ensured that the second electric motor does not reach the maximum speed during operation of the motor vehicle or that the maximum speed does not come too close. This is particularly advantageous when factors influencing the acceleration behavior, such as e.g. Wind conditions, gradient or the like, are present and are not taken into account in the determination of the third time.

According to a second aspect of the invention, the object is achieved by a motor vehicle having a hybrid drive system. The hybrid drive system has at least one main engine and a first electric motor and a second electric motor, wherein the main motor and the first electric motor via a first transmission and the second electric motor via a second transmission with a common drive axle or with separate drive axles of the motor vehicle are coupled. The hybrid drive system is designed to carry out the method according to the invention.

The motor vehicle according to the invention has the same advantages as have already been described above for the method for operating a hybrid drive system. Accordingly, the motor vehicle according to the invention has the advantage that the main motor during the acceleration process, a substantially constant additional drive torque from the first electric motor and the second electric motor is available. In this way, in particular during the disengaging operation of the second electric motor, a drive torque step, which greatly reduces the ride comfort, especially when cornering, can be avoided. By the complete or substantially complete compensation of Drive torque of the second electric motor by the first electric motor at the time of disengagement of the second electric motor, a jerk is effectively avoidable and the ride comfort during this operating range can be improved.

The motor vehicle according to the invention and the method according to the invention for operating a hybrid drive system of a motor vehicle are explained in more detail below with reference to drawings. Each show schematically:

1 in a plan view of an inventive motor vehicle with a hybrid drive system;

2 a performance diagram of a hybrid drive system, which is operated according to a method according to the prior art; and

3 a performance diagram of a hybrid drive system, which is operated according to a method according to the invention.

1 shows in a plan view schematically a motor vehicle according to the invention 2 with a hybrid drive system 1 , The car 2 has two drivable drive axles 8th . 8a . 8b on which a first drive axle 8a in this illustration right and a second drive axle 8b is shown on the left in this illustration. The car 2 has a main motor 3 on, which is preferably designed as an internal combustion engine, such as a gasoline engine or diesel engine. The main engine 3 is together with a first electric motor 4 via a first transmission 6 with first drive axle 8a coupled. Thus, the electric motor 4 always the same speed as the main engine 3 on. The first transmission 6 is preferably designed as a switchable multi-speed transmission. Furthermore, the motor vehicle 2 a second electric motor 5 up, over a clutch 11 with a second gear 7 coupled, wherein the second transmission with the second drive axle 8b is coupled. The second transmission 7 is preferably designed as a single-gear transmission and designed such that a through the second electric motor 5 Assisted starting and driving at medium speed of the motor vehicle 2 is easily possible without the second electric motor 5 turns too high or reaches its maximum speed. For driving at higher speeds is the second electric motor 5 by means of the coupling 11 from the second gear 7 and thus from the second drive shaft 8b uncoupled. Alternatively, the clutch 11 also between gears 6 and drive axle 8b be arranged, resulting in the advantage that, with decoupled second electric motor 5 In addition, the transmission losses of the transmission 7 be eliminated (the gear incl. The gears do not continue to turn) and thus results in an additional fuel economy.

To carry out the method according to the invention, in particular for monitoring and for controlling the hybrid drive 1 , shows the hybrid drive system 1 a control unit 9 and a control unit 10 on, especially with the first electric motor 4 and the second electric motor 5 and a battery 12 of the motor vehicle 2 are connected. According to the invention, it may be provided that the control unit 9 and / or the control unit 10 are coupled to one or more sensors of the motor vehicle, to thus determine operating data of the motor vehicle, such as vehicle speed, vehicle acceleration or the like, for operating the hybrid drive system.

2 schematically shows a performance diagram of a hybrid drive system, which is operated according to a method according to the prior art. In this performance diagram, the time (t) on the abscissa and the power (P) and speed (v) of the vehicle is plotted on the ordinate. The performance diagram starts at the start time (t ₀ ) at which the motor vehicle ( 2 ) already has a ground speed. The vehicle speed curve (v _F ) is shown schematically with a sectionally constant slope. A main engine actual power curve (P _H ) is shown as running parallel to the abscissa straight line. This means that one of the main engine ( 3 ) provided drive power in the illustrated period in the exemplary driving situation is constant.

Between the start time (t ₀ ) and a first time (t ₁ ) runs a second actual power curve (P ₂ ) of the second electric motor ( 5 ) also parallel to the abscissa and corresponds to almost a maximum of the second electric motor ( 5 ) achievable drive power. A first actual power curve (P ₁ ) of the first electric motor ( 4 ) runs in this time interval on the abscissa. Accordingly, the first actual power of the first electric motor ( 4 ) in this period zero. The first electric motor ( 4 ) thus rotates with the main motor ( 3 ) load-free or power-free or at least substantially free of load with. An overall actual power curve (P _G ) is the sum of the main engine actual power curve (P _H ), the first actual power curve (P ₁ ) and the second actual power curve (P ₂ ). Consequently, the total actual power curve (P _G ) in this period is parallel to the abscissa. The increase in the vehicle speed curve (v _F ) or the vehicle speed and thus the vehicle acceleration is maximum in this time interval.

From the first time (t ₁ ) falls the second actual power curve (P ₂ ) of the second electric motor ( 5 ) linearly with a large negative slope and is zero from the second time point (t ₂ ). Thus, the second electric motor ( 5 ) at the second time (t ₂ ) without load or without power or at least substantially free of load with the second drive axle ( 8b ) With. At the same time, the first actual power curve (P ₁ ) has a strong linear increase in this time interval. System-conditioned by the limited max. Power of the first electric motor ( 4 ) reaches the first actual power curve (P ₁ ) of the first electric motor ( 4 ) at the second time (t ₂ ) to a lower level than the second actual power curve (P ₂ ) at the first time (t ₁ ). It can clearly be seen that the overall actual power curve (P _G ) between the first time (t ₁ ) and the second time (t ₂ ) also drops, since the output from the first electric motor ( 4 ) propulsive power not to compensate for the drive power of the second electric motor ( 5 ) is sufficient. This power deficit will be perceived by the driver of the motor vehicle as a spontaneously reduced vehicle acceleration and represents a noticeable loss of driving comfort. The increase in the slope of the vehicle speed curve (v _F ) or the vehicle speed is less in this time interval than in the previous time interval.

From the second time (t ₂ ), the first electric motor ( 4 ) a constant maximum drive torque ready, therefore, the first actual power curve (P ₁ ) from the second time point (t ₂ ) is parallel to the abscissa. Between the second time (t ₂ ) and the third time (t ₃ ) takes place a decoupling operation of the second electric motor ( 5 ) of the second gear ( 7 ) instead of. The second electric motor ( 5 ) thus rotates with the second drive axle until the third time (t ₃ ) without torque or load 8b ) With. The total actual power curve (P _G ) thus again runs parallel to the abscissa. The increase in the vehicle speed curve (v _F ) or the vehicle speed is again lower in this time interval than in the previous time interval.

3 schematically shows a performance diagram of a hybrid drive system, which is operated in accordance with a method according to the invention. In this performance diagram, the time (t) is also plotted on the abscissa and the power (P) and speed (v) of the vehicle as already on the ordinate. The performance diagram likewise begins at the start time (t ₀ ) at which the motor vehicle ( 2 ) already has a ground speed. The vehicle speed curve (v _F ) is shown for driving on a constant slope. The car ( 2 ) is accelerated in the illustrated period with a constant drive power curve (P _G ) or drive power. A main engine actual power curve (P _H ) is shown as running parallel to the abscissa straight line. This means that one of the main engine ( 3 ) provided drive power in the illustrated period is constant.

Between the start time (t ₀ ) and a first time (t ₁ ) runs a second actual power curve (P ₂ ) of the second electric motor ( 5 ) also parallel to the abscissa and corresponds to a maximum of the first electric motor ( 4 ) maximum achievable drive power. A first actual power curve (P ₁ ) of the first electric motor ( 4 ) runs in this time interval, for example, on the abscissa. Accordingly, the first actual power of the first electric motor ( 4 ) in this period zero. The first electric motor ( 4 ) thus rotates with the main motor ( 3 ) load-free or power-free or at least substantially free of load with. An overall actual power curve (P _G ) is the sum of the main engine actual power curve (P _H ), the first actual power curve (P ₁ ) and the second actual power curve (P ₂ ). Consequently, the total actual power characteristic (P _G) extends in the same period in parallel to the abscissa.

From the first time (t ₁ ) falls the second actual power curve (P ₂ ) of the second electric motor ( 5 ) with a defined moderate negative slope possibly linear and is from the second time (t ₂ ) zero. Thus, the second electric motor ( 5 ) at the second time (t ₂ ) without load or without power or at least substantially free of load with the second drive axle ( 8b ) With. At the same time, the first actual power curve (P ₁ ) in this time interval has an equally defined moderate increase, possibly also linear. The first actual power curve (P ₁ ) of the first electric motor ( 4 ) has at the second time (t ₂ ) the same height as the second actual power curve (P ₂ ) at the first time (t ₁ ). It can clearly be seen that the total actual power curve (P _G ) between the first time (t ₁ ) and the second time (t ₂ ) is still constant, since the output from the first electric motor ( 4 ) Provisionable drive power exactly to compensate for the drive power of the second electric motor ( 5 ) is sufficient. Consequently, there is no power deficit, so that, in particular, at the first time (t ₁ ), no signal from the driver of the motor vehicle ( 2 ) noticeable jerking occurs, which negatively affects the ride comfort.

From the second time (t ₂ ), the first electric motor ( 4 ) provide a constant drive power, the the drive power curve (P _G ) and the drive power of the second electric motor ( 5 ) corresponds to the first time (t ₁ ). Therefore, the first actual power curve (P ₁ ) from the second time point (t ₂ ) runs parallel to the abscissa. Between the second time (t ₂ ) and the third time (t ₃ ) takes place a decoupling operation of the second electric motor ( 5 ) of the second gear ( 7 ) instead of. The second electric motor ( 5 ) thus rotates with the second drive axle until the third time (t ₃ ) without torque or load 8b ) With. The overall actual power curve (P _G ) thus continues to run parallel to the abscissa.

As can be clearly seen from the diagrams, the method according to the invention makes it possible to provide a constant combined overall drive power of the electric motors ( 4 . 5 ) in conjunction with the internal combustion engine ( 3 ) during the disengaging operation of the second electric motor ( 5 ) when accelerating the motor vehicle ( 2 ). There is no jerking, whereby the ride comfort is significantly improved.

LIST OF REFERENCE NUMBERS

1

 hybrid drive system

2

 motor vehicle

3

 main engine

4

 first electric motor

5

 second electric motor

6

 first transmission

7

 second gear

8th

 drive axle

8a

 first drive axle

8b

 second drive axle

9

 control unit

10

 control unit

11

 clutch

12

 battery

P

 power

P ₁

 first actual performance

P ₂

 second actual performance curve

P _G

 Total actual performance history

P _H

 Main actual engine power curve

t

 Time

t ₀

 Start time

t ₁

 first time

t ₂

 second time

t ₃

 third time

v

 speed

v _F

 Vehicle speed course

Claims (9)

Method for operating a hybrid drive system ( 1 ) of a motor vehicle ( 2 ), wherein the hybrid drive system ( 1 ) at least one main engine ( 3 ) and a first electric motor ( 4 ) and a second electric motor ( 5 ), the main motor ( 3 ) as well as the first electric motor ( 4 ) via a first transmission ( 6 ) and the second electric motor ( 5 ) via a decoupling device ( 7 ) and a second transmission ( 7 ) with a common drive axle ( 8th . 8a . 8b ) or with separate drive axles ( 8th . 8a . 8b ) of the motor vehicle ( 2 ), comprising the steps of: - registering an acceleration command for the motor vehicle ( 2 ) by means of a control unit ( 9 ), - driving the main engine ( 3 ) optionally in combination with the first electric motor ( 4 ) and the second electric motor ( 5 ) for transmitting a drive torque to at least one of the drive axles ( 8th ) for accelerating the motor vehicle ( 2 ), wherein the driving by means of the control unit ( 9 ) and on the basis of the acceleration command, - determining a third point in time (t ₃ ) to which the second electric motor ( 5 ) at current acceleration a limit engine speed, which is less than a maximum engine speed of the second electric motor ( 5 ), wherein the determination by means of a control unit ( 10 ), - calculating a second time (t ₂ ) for initiating decoupling of the second electric motor ( 5 ) from the drive axle ( 8th . 8a . 8b ) such that the second electric motor ( 5 ) at the third time (t ₃ ) of the drive axle ( 8th . 8a . 8b ) is decoupled, wherein the calculation by means of the control unit ( 10 ), determining a first time (t ₁ ) for initiating a motor power reduction of the second electric motor ( 5 ) such that the second electric motor ( 5 ) at the second time (t ₂ ) torque-free with the drive axle ( 8th . 8a . 8b ), wherein the determination by means of the control unit ( 10 ), - reducing the engine power of the second electric motor ( 5 ) from the first time (t ₁ ) to the second time (t ₂ ) such that the second electric motor ( 5 ) at the second time (t ₂ ) torque-free or substantially torque-free with the drive axle ( 8th . 8a . 8b ), whereby reducing by means of the control unit ( 9 ), - increasing the engine power of the first electric motor ( 4 ) before the second time (t ₂ ) such that the first electric motor ( 4 ) provides an engine power at the second time (t ₂ ) that corresponds to an engine power of the second electric motor ( 5 ) corresponds or substantially corresponds to the first time (t ₁ ), wherein the increasing by means of the control unit ( 9 ), and - initiating a disengaging operation of a clutch ( 11 ), via which the second electric motor ( 5 ) with the drive axle ( 8th . 8a . 8b ) is coupled at the second time (t ₂ ) by means of the control unit ( 9 ) such that the second electric motor ( 5 ) at the third time (t ₃ ) of the drive axle ( 8th . 8a . 8b ) is uncoupled. A method according to claim 1, characterized in that reducing the engine power of the second electric motor ( 5 ) of the amount of increasing the engine power of the first electric motor ( 4 ) corresponds. A method according to claim 1 or 2, characterized in that reducing the engine power of the second electric motor ( 5 ) with a constant second gradient and / or that increasing the motor power of the first electric motor ( 4 ) takes place with a constant first gradient. A method according to claim 3, characterized in that in the determination of the first and the second gradient, a gear-dependent vibration behavior of the drive motor coupled to the respective axes ( 8th . 8a . 8b ) is taken into account such that vibrations of the drive axles ( 8th . 8a . 8b ) are reduced. A method according to claim 3 or 4, characterized in that for calculating the first time (t ₁ ) of the lower magnitude of the two gradients is taken into account. Method according to one of the preceding claims, characterized in that for determining the third time (t ₃ ) a loading state of the motor vehicle ( 2 ) and / or a gradient or a course of a gradient of a roadway and / or an air resistance of the motor vehicle ( 2 ) and / or an actual speed of the motor vehicle ( 2 ) and / or a rolling resistance and / or a tire lash and / or a performance characteristic of the drive system ( 1 ) and / or a theoretical acceleration command for maximum acceleration is taken into account. Method according to one of the preceding claims, characterized in that the second electric motor ( 5 ) is controlled prior to reducing the engine power such that the second electric motor ( 5 ) provided engine power of a maximum engine power of the first electric motor ( 4 ) corresponds or at least substantially corresponds. Method according to one of the preceding claims, characterized in that the third time (t ₃ ) is set such that a rotational speed of the second electric motor ( 5 ) at the third time (t ₃ ) max. 90%, better 95% and ideally 98% of the maximum permissible speed of the second electric motor ( 5 ) does not exceed. Motor vehicle ( 2 ) with a hybrid drive system ( 1 ), wherein the hybrid drive system ( 1 ) at least one main engine ( 3 ) and a first electric motor ( 4 ) and a second electric motor ( 5 ), the main motor ( 3 ) as well as the first electric motor ( 4 ) via a first transmission ( 6 ) and the second electric motor ( 5 ) via a decoupling device ( 7 ) and via a second transmission ( 7 ) with a common drive axle ( 8th . 8a . 8b ) or with separate drive axles ( 8th . 8a . 8b ) of the motor vehicle ( 2 ), characterized in that the hybrid drive system ( 1 ) is designed for carrying out a method according to one of claims 1 to 8.

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