DE102021114641A1 - Drive unit and drive arrangement - Google Patents

Abstract

The invention relates to a drive unit for a drive train of an electrically driven motor vehicle, in particular a hybrid motor vehicle, and a drive arrangement.
The drive unit (1) comprises a first electric rotary machine (10) and a second electric rotary machine (20) and a first shaft (40) and a second shaft (41), a rotor (11) of the first electric rotary machine (10) being non-rotatable is connected to the first shaft (40) and the drive unit (1) also has a first separating clutch (50), it being provided according to the invention that the drive unit (1) also has a second separating clutch (120) with which a rotor (21 ) of the second rotary electric machine (20) for torque transmission to the second shaft (41) can be connected or is connected.
The drive unit according to the invention and the drive arrangement ensure efficient operation in a cost-effective design and in a way that saves installation space.

Description

The invention relates to a drive unit for a drive train of an electrically driven motor vehicle, in particular a hybrid motor vehicle, and a drive arrangement.

Various drive units are known from the prior art, which are integrated in drive arrangements or drive series trains.

the DE 11 2015 006 071 T5 discloses a hybrid vehicle propulsion system having a generator capable of generating electric power using power from an internal combustion engine; an electric motor driven by electric power to drive wheels; a case accommodating the generator and the electric motor, and a power control unit for controlling the generator and the electric motor. The generator and the electric motor are arranged side by side on the same axis in the housing.

In the WO 2019 101 264 A1 a powertrain for a hybrid motor vehicle is disclosed. The drive train includes a transmission input shaft that is operatively related via a first drive train to a first electric machine and an internal combustion engine for torque transmission and is operatively related to a second drive train with a second electric machine for torque transmission. The two electrical machines are arranged coaxially and axially adjacent to one another.

the U.S. 2016/0218584 A1 describes a control unit which is used to control electrical machines, the control unit being mounted on a housing of the drive unit comprising the electrical machines. In this case, the drive unit comprises two electrical machines which are arranged coaxially and axially adjacent to one another.

EP 1502791 B1 and EP1847411B1 each disclose a hybrid transmission for a hybrid vehicle having a plurality of rotary electric machines. The electrical machines are arranged in a radially nested manner. The radially outer electrical rotary machine is designed as an external rotor.

Integrating a drive unit with several electric rotating machines in a drive arrangement that is intended for a hybrid motor vehicle is subject to strict installation space requirements, particularly in the axial direction.

In particular when using such a drive unit in so-called front-transverse arrangements in motor vehicles, in which the electric rotary machines and the internal combustion engine are used as front drives and a respective axis of rotation of an electric rotary machine and the internal combustion engine is arranged transversely to the longitudinal direction of the motor vehicle, an axial is particularly special short building drive assembly advantageous.

Among other things, so-called hybrid transmissions with two electrical machines are known, which enable switching between serial operation and parallel operation. In serial operation, an internal combustion engine drives a first electric machine that works as a generator. The electrical energy thus generated is used to drive the second electrical machine, the torque of which is transmitted to the wheels of a motor vehicle equipped with the hybrid transmission.

In parallel operation, the torque of a connected internal combustion engine is directed to the wheels of a motor vehicle equipped with the hybrid transmission, with the second electric machine running idle, supporting the driving operation or also recuperating.

• Eine Verbrennungskraftmaschine 110 ist über eine erste Übersetzungsstufe 70 direkt mit einer als Generator laufenden ersten elektrischen Rotationsmaschine 10 verbunden, die hier als Innenläufer ausgelegt ist.

In 1 such a conventional concept is shown with two electrical systems in a nested arrangement:

• An internal combustion engine 110 is connected via a first transmission stage 70 directly to a first electrical rotary machine 10 running as a generator, which is designed here as an internal rotor.

A second electric rotary machine 20 serving as an electric traction drive is defined here as an external rotor and two further transmission stages 71 , 72 are connected to the wheel drive shafts 103 .

In the torque transmission path between the two rotary electric machines 10, 20 there is a first separating clutch 50, which enables serial driving in the open state and parallel driving in the closed state.

The disadvantage of this arrangement is that with parallel operation, the second electrical rotary machine 20 often runs idle, generates corresponding resistance through induction and therefore even has to be actively rotated, for which purpose electrical energy has to be used. This reduces the efficiency.

Proceeding from this, the object of the present invention is to provide a drive unit and a drive arrangement equipped therewith which ensure efficient operation in a cost-effective design and in a manner that saves installation space.

The object is achieved by the drive unit according to claim 1 according to the invention. Advantageous configurations of the drive unit are specified in dependent claims 2 to 9.

In addition, a drive arrangement, which has the drive unit, according to claim 10 is provided.

The features of the claims can be combined in any technically meaningful way, with the explanations from the following description and features from the figures also being able to be used for this purpose, which include supplementary configurations of the invention.

In the context of the present invention, the terms “axial” and “radial” always refer to the axis of rotation of the drive unit, which corresponds to the axis of rotation of at least one of the electric rotary machines comprised by the drive unit.

The invention relates to a drive unit for a drive train of an electrically driven motor vehicle, in particular a hybrid motor vehicle. The drive unit comprises a first rotary electric machine and a second rotary electric machine and a first shaft and a second shaft, with a rotor of the first rotary electric machine being connected to the first shaft in a torque-proof manner. The drive unit also has a first separating clutch, with which the rotor of the first electric rotary machine can be connected or is connected to the second shaft for torque transmission. According to the invention, it is provided that the drive unit also has a second separating clutch, with which a rotor of the second electric rotary machine can be connected or is connected to the second shaft for torque transmission.

By opening the second separating clutch, the second electric rotary machine can thus be decoupled from the drive axles or wheels of the vehicle in its capacity as a drive machine. Accordingly, the driving operation can be guaranteed with a pure internal combustion engine drive without having to accept efficiency losses caused by the second electric rotary machine.

The second separating clutch makes it possible to quickly switch the second electric rotary machine back into the torque transmission path by closing it and consequently to bring the drive unit into a series connection of the electric rotary machines, e.g. in order to carry out high accelerations.

In this case, one of the two electric rotary machines can be arranged at least in regions radially and axially within a space that is radially delimited by the other electric rotary machine in each case.

The first separating clutch is arranged in a torque transmission path running from the first electric rotary machine to the second shaft or is set up to open and close this torque transmission path. Advantageously, the axes of rotation of the rotors of the rotary electric machines are positioned coaxially.

The radial nesting of the two electrical rotary machines has the advantage that in the production of the individual sheets of the rotor packet and the stator packet of both electrical rotary machines from a circuit board with a punching stroke, both a sheet metal of the rotor of the radially inner electric rotary machine and of the stator of the radially inner rotary electric machine and also the stator of the radially outer rotary electric machine and the rotor of the radially outer rotary electric machine can be cut out.

For the purpose of its connection to the second shaft, the rotor of the radially outer electric rotary machine can be carried by a rotor carrier, which is connected to the second shaft via the second separating clutch, the rotor of the second electric rotary machine being connected to the rotor carrier in a non-positive and/or positive manner .

For the purpose of rotatably mounting the first shaft and/or the second shaft, the drive unit can have a central bearing or a central bearing unit which is designed in one or more parts and by means of which the first shaft and/or the second shaft is mounted on a housing of the drive unit are. The rotor carrier of the radially outer electrical rotary machine can be mounted directly on the central bearing or indirectly on the second shaft on the central bearing. The central bearing is designed, for example, as a roller, ball or angular contact ball bearing.

The drive unit may include a fastener which is bolted to the first or second shaft to secure the Position of the rotor carrier of the radially outer rotary electric machine in relation to the position of the second shaft.

Advantageously, the radially inner rotary electric machine can be operated as a generator. The rotor of the radially inner rotary electric machine is relatively small and thus has a lower mass moment of inertia than the rotor of the radially outer rotary machine.

Accordingly, the radially outer electrical rotary machine can advantageously be used as a drive unit, since the rotor of this electrical rotary machine is relatively large and can generate a correspondingly large torque.

This does not rule out the possibility that both the radially inner electric rotary machine and the radially outer electric rotary machine can be used for the purpose of driving a motor vehicle equipped with the drive unit.

For example, the radially inner rotary electric machine can be used to conduct torque to an input side of the drive unit, so that an internal combustion engine that can be connected to the input side can be started. Alternatively, one or both electrical rotary machines can also provide torque and, together with a connected internal combustion engine, implement hybrid operation of the drive unit.

In particular, the second separating clutch can be a dog clutch and/or the first separating clutch can be a multi-plate clutch.

The present invention is not restricted to these embodiments of the clutches, but instead the second separating clutch can also be a multi-plate clutch and/or the first separating clutch can be a dog clutch, or both separating clutches are designed as dog or multi-plate clutches. When the second separating clutch is designed as a claw clutch, it is provided that when this clutch is closed, the speeds of the input side and the output side or a first engagement element and a second engagement element are adapted to one another by adjusting the speed of the second rotary electric machine, so that the claw clutch only has a low Speed difference is actuated.

Likewise, if the second separating clutch is designed as a multi-plate clutch, differential speeds can also be synchronized via the second rotary electric machine.

Furthermore, the drive unit can have an actuating system with which the first separating clutch can be closed and the second separating clutch opened at the same time.

The actuation system can include an axially displaceable pressure piece with which a force can be applied to a disk pack of the first separating clutch designed as a disk clutch during axial displacement, so that it is compressed and the first separating clutch is thereby closed. This pressure piece can be mechanically connected or is connected to a first engagement element of the second separating clutch designed as a claw clutch, with the axial displacement of the pressure piece causing the first separating clutch being engaged canceling the engagement of the first engagement element with a second engagement element of the claw clutch, thereby opening the second separating clutch.

The exertion of force on the first separating clutch can take place indirectly, in particular via an engagement bearing which is arranged between the pressure piece and the disk set.

In the reverse mode of operation, the actuating system can be depressurized so that a spring element reverses the described axial movement again, so that the first engagement element of the second separating clutch is engaged with the second engagement element again and the second separating clutch, which is designed as a claw clutch, is closed. At the same time, this moves the pressure piece away from the disk pack of the first separating clutch, so that the latter is opened.

In one embodiment, the first rotary electric machine is arranged at least in some areas both radially and axially within a space radially delimited by the second rotary electric machine, the first rotary electric machine being designed as an internal rotor motor and the second rotary electric machine being designed as an external rotor motor, and the stator of the first Electrical rotary machine and the stator of the second electrical rotary machine are mechanically fixed to each other.

Accordingly, one embodiment provides that the rotor of the first rotary electric machine is arranged within a space that is radially delimited by the stator of the second rotary electric machine.

It can be that the stators of the two electric rotary machines are arranged on a common stator carrier.

The stator carrier is in turn fixed to a housing of the drive unit.

In particular, this stator carrier can be arranged between the stators of the two electric rotary machines with regard to its radial position and can be mechanically connected to them, so that the stator carrier fixes both stators.

If necessary, according to an alternative embodiment, the stators of the two electric rotary machines are integral components of a stator unit. This stator unit can in turn be fixed to a housing of the drive unit. This alternative embodiment therefore does not use an extra stator carrier between the individual stators, but instead includes a compact unit that is only formed by the two stators.

The fixing of the stator unit to a housing of the drive unit can be realized by several screw connections. A respective screw of a screw connection is passed through the stator unit in particular in the axial direction and is screwed into a housing of the drive unit.

In one embodiment of the drive unit, it comprises a first housing and a second housing, which together define a housing interior in which the two rotary electric machines are arranged and in which the first shaft and the second shaft are arranged at least in regions. In particular, a common stator carrier or a stator unit is mechanically connected to the first housing, with the rotors of the two rotary electric machines being mounted on the second housing.

In particular, the second shaft can be mounted on the second housing, it being possible for the first shaft to be mounted on the first housing and on the second shaft. In addition, power electronics for controlling the electric rotary machines can be carried by the second housing.

In a structurally advantageous embodiment, the two shafts are arranged coaxially.

For this purpose, provision is made in particular for the second shaft to be designed as a hollow shaft and for the first shaft to run in sections within the second shaft.

In one embodiment, it is provided that the first electric rotary machine is set up for generator operation.

This means that the radially inner rotary electric machine can advantageously be operated as a generator. The rotor of the radially inner rotary electric machine is relatively small and thus has a lower mass moment of inertia than the rotor of the radially outer rotary machine.

The second rotary electric machine can be set up for drive motor operation.

Correspondingly, the second rotary electric machine can be set up for drive motor operation. This means that the radially outer rotary electric machine can advantageously be used as a drive unit, since the rotor of this rotary electric machine is relatively large and can generate a correspondingly large torque.

Furthermore, the drive unit can include a first gear ratio, the first gear ratio being formed by a connecting element of the drive unit, which includes an internally toothed gear, and the first shaft, which has an element with external teeth, and wherein the teeth of the internally toothed gear and the External teeth mesh with each other for the purpose of transmitting the rotary movement from the connecting element to the first shaft.

Accordingly, the drive unit according to the invention is designed as a so-called hybrid transmission. This means that the drive unit also includes a gearbox in addition to the electric rotary machines and the shafts. In particular, the element with the external toothing can be a gearwheel arranged in a rotationally fixed manner on the first shaft.

Furthermore, the drive unit can have a second transmission stage, which is formed by teeth, in particular external teeth, of the second shaft and a first gear meshing with the teeth of the second shaft.

In one embodiment, in which the drive unit has a gear, the first gear wheel can be coupled in a torque-proof manner to an intermediate shaft of the gear. This gear can include a differential gear in the output area. An external toothing of the intermediate shaft can mesh with an input gear wheel of the differential gear, resulting in a third gear ratio tion stage is realized. The second shaft thus functions here as a transmission input shaft and is operatively connected to the transmission, so that a torque made available by the second shaft or the rotational movement realized by the second shaft is transferred via the transmission to a further transmission unit of a motor vehicle can be, or can be routed directly to the drive wheels of a motor vehicle.

The drive unit according to the invention has the advantage that due to the axial nesting of the electric rotary machines, significantly less installation space is required axially than in conventional drive units with two electric rotary machines.

Furthermore, according to the invention, a drive arrangement is provided which has a drive unit according to the invention and an internal combustion engine, wherein an output element of the internal combustion engine is coupled or can be coupled in a rotationally fixed manner to the rotor of the first electric rotary machine.

• - Elektrisches Fahren und Rekuperieren:
  • Die erste Trennkupplung ist geöffnet, wodurch die zweite elektrische Rotationsmaschine von der ersten elektrischen Rotationsmaschine und der Verbrennungskraftmaschine abgekoppelt ist. Die zweite Trennkupplung ist geschlossen. Die zweite elektrische Rotationsmaschine wird somit separat als Traktionsmaschine oder als Generator angesteuert. Die Verbrennungskraftmaschine und die erste elektrische Rotationsmaschine sind nicht in Betrieb.
• - Seriell Fahren und Laden:
  • Die erste Trennkupplung ist geöffnet. Die Verbrennungskraftmaschine wird mittels der ersten elektrischen Rotationsmaschine gestartet, wobei die Verbrennungskraftmaschine die erste elektrische Rotationsmaschine antreiben kann und folglich die erste elektrische Rotationsmaschine als Generator angesteuert wird, um die Batterie des Kraftfahrzeugs zu laden. Die zweite Trennkupplung ist geschlossen. Die zweite elektrische Rotationsmaschine wird als Traktionsmaschine angesteuert.
• - Parallel Hybridantrieb, Laden und Boosten:
  • Die erste Trennkupplung und die zweite Trennkupplung sind geschlossen, wodurch die erste elektrische Rotationsmaschine, die zweite elektrische Rotationsmaschine sowie die Verbrennungskraftmaschine miteinander gekoppelt sind. Das Kraftfahrzeug wird mittels der Verbrennungskraftmaschine und / oder einer oder beider elektrischen Rotationsmaschinen angetrieben. Die beiden elektrischen Rotationsmaschinen können hier als Traktionsmaschine oder als Generator angesteuert werden.

During the operation of a motor vehicle, in particular a hybrid vehicle, with a drive arrangement according to the invention, comprising a drive unit according to the invention and an internal combustion engine, the following driving modes, for example, are made possible:

• - Electric driving and recuperation:
  • The first separating clutch is open, as a result of which the second rotary electric machine is decoupled from the first rotary electric machine and the internal combustion engine. The second separating clutch is closed. The second electric rotary machine is thus controlled separately as a traction machine or as a generator. The internal combustion engine and the first rotary electric machine are not in operation.
• - Serial driving and charging:
  • The first separating clutch is open. The internal combustion engine is started by means of the first electric rotary machine, the internal combustion engine being able to drive the first electric rotary machine and consequently the first electric rotary machine being activated as a generator in order to charge the battery of the motor vehicle. The second separating clutch is closed. The second electric rotary machine is controlled as a traction machine.
• - Parallel hybrid drive, charging and boosting:
  • The first separating clutch and the second separating clutch are closed, as a result of which the first electric rotary machine, the second electric rotary machine and the internal combustion engine are coupled to one another. The motor vehicle is driven by the internal combustion engine and/or one or both electric rotary machines. The two electrical rotary machines can be controlled here as a traction machine or as a generator.

In a further embodiment, the drive arrangement also comprises at least one wheel drive shaft, on which wheels of a motor vehicle equipped with the drive arrangement are to be arranged, and which is connected to the second shaft of the drive unit via the transmission of the drive unit, so that a rotational movement implemented by the second shaft is carried out by the transmission can be transferred to the wheel drive shaft and thus to the wheels.

According to one embodiment of the drive arrangement, the drive arrangement can have a vibration damper connected non-rotatably to the connection element of the drive unit and a housing element mechanically connected to the internal combustion engine, the vibration damper being arranged in the housing element.

The housing element is advantageously connected to the second housing of the drive unit.

A pump actuator of a cooling circuit of the drive unit can be mounted in the housing element.

Provision can furthermore be made for the intermediate shaft and/or the wheel drive shaft to be mounted axially on the one hand in the housing element and on the other hand in the second housing.

• 1: eine schematische Darstellung einer Antriebsanordnung mit Antriebseinheit gemäß Stand der Technik,
• 2: eine schematische Darstellung einer erfindungsgemäßen Antriebsanordnung mit erfindungsgemäßer Antriebseinheit,
• 3: einen Ausschnitt der erfindungsgemäßen Antriebsanordnung in geschnittener Seitenansicht,
• 4: einen vergrößerten Ausschnitt der erfindungsgemäßen Antriebseinheit,
• 5: einen stärker vergrößerten Ausschnitt der erfindungsgemäßen Antriebseinheit im Bereich der geschlossenen zweiten Trennkupplung, und
• 6: einen stärker vergrößerten Ausschnitt der erfindungsgemäßen Antriebseinheit im Bereich der geöffneten zweiten Trennkupplung.

The invention described above is explained in detail below against the relevant technical background with reference to the accompanying drawings, which show preferred embodiments. The invention is in no way limited by the purely schematic drawings, it being noted that the exemplary embodiments shown in the drawings are not limited to the dimensions shown. It is shown in

• 1 : a schematic representation of a drive arrangement with a drive unit according to the prior art,
• 2 : a schematic representation of a drive arrangement according to the invention with a drive unit according to the invention,
• 3 : a section of the drive arrangement according to the invention in a sectional side view,
• 4 : an enlarged section of the drive unit according to the invention,
• 5 : a more enlarged section of the drive unit according to the invention in the area of the closed second separating clutch, and
• 6 : a more enlarged section of the drive unit according to the invention in the area of the opened second separating clutch.

on 1 was already received to explain the state of the art.

In 2 a schematic representation of a drive arrangement 100 according to the invention with a drive unit 1 according to the invention is shown.

The drive unit 1 comprises a first rotary electric machine 10, a second rotary electric machine 20, a first shaft 40 and a second shaft 41.

Furthermore, the drive arrangement 100 includes an internal combustion engine 110 and a vibration damper 101 , an output element 111 of the internal combustion engine 110 being coupled to the vibration damper 101 . The vibration damper 101 is also connected to a connection element 4 of the drive arrangement 1 which acts as an input side 2 of the drive arrangement 1 . The internal combustion engine 110 is thus coupled to the drive arrangement 1 via the vibration damper 110 .

The connection element 4 is coupled to the first shaft 40 in such a way that a first transmission stage 70 is formed between the connection element 4 and the first shaft 40 .

A rotor 11 of the first electric rotary machine 10 is connected in a torque-proof manner to the first shaft 40 and a rotor 21 of the second electric rotary machine 20 is connected or can be connected to the second shaft 41 via a second separating clutch 120 . The rotor 11 of the first rotary electric machine 10 is connected to the first shaft 40 in such a way that the rotor 11 of the first rotary electric machine 10 is arranged directly on the first shaft 40 . The rotor 21 of the second rotary electric machine 20 , on the other hand, is carried by a rotor carrier 30 and the rotor carrier 30 is connected to the second shaft 41 via the second separating clutch 120 .

The first electric rotary machine 10 is arranged radially and in some areas axially within a space delimited radially by the second electric rotary machine 20 . The first rotary electric machine 10 is designed as an internal rotor motor and the second rotary electric machine 20 is designed as an external rotor motor, with a stator 12 of the first rotary electric machine 10 and a stator 22 of the second rotary electric machine 20 being mechanically fixed to one another.

A first separating clutch 50 of the drive unit 1 is connected to the first shaft 40 by its input side 51 and to the second shaft 41 by its output side 52 . The first separating clutch 50 thus serves to transmit torque between the first shaft 40 and the second shaft 41. Accordingly, a torque transmission path between the rotor 11 of the first rotary electric machine 10 and the rotor 21 of the second rotary electric machine 20 can be opened or getting closed.

The second shaft 41 is designed as a hollow shaft and the first shaft 40 runs radially in sections inside the second shaft 41. The two shafts 40, 41 thus run coaxially with one another, with the rotors 11, 21 of the two electric rotary machines 10, 20 also being coaxial with one another and are arranged coaxially to the shafts 40,41.

The second shaft 41 is connected to an intermediate shaft 81 via a second transmission stage 71 . The intermediate shaft 81 runs parallel to the second shaft 41.

The intermediate shaft 81 is connected via a third transmission stage 72 to an input element of a differential gear 80 of the drive unit 1 for the purpose of transmitting torque. The differential gear 80 forms an output side 3 of the drive unit 1.

Wheel drive shafts 103, on which wheels of a motor vehicle equipped with drive assembly 100 are to be arranged, form the output of differential gear 80, so that a rotational movement implemented by second shaft 41 is transmitted via second gear ratio 71 and third gear ratio 72 and via differential gear 80 to the Wheel drive shaft 103 and thus can be transmitted to the wheels.

A torque provided by internal combustion engine 110 is transmitted via vibration damper 101 and via first transmission stage 70 to first shaft 40 of drive unit 1 transfer. If the first separating clutch 50 is disengaged, the torque of the internal combustion engine 110 is only passed to the rotor 11 of the first rotary electric machine 10 . In this way, the first electric rotary machine 10 can be used in generator mode to charge a battery. If the first separating clutch 50 is closed, the torque provided by the internal combustion engine 110 is transmitted from the first shaft 40 to the second shaft 41 . The torque of the internal combustion engine 110 is passed from the second shaft 41 via the second transmission stage 71 to the intermediate shaft 81 and via the third transmission stage 72 into the differential gear 80 . The torque reaches the wheels of a motor vehicle equipped with the drive arrangement 100 by means of the wheel drive shaft 103 via the differential gear 80 .

A torque provided by the rotor 11 of the first rotary electric machine 10 can be transmitted to the internal combustion engine 110 via the first transmission stage 70 when the first separating clutch 50 is disengaged. When the first separating clutch 50 is closed, the torque is transmitted via the second transmission stage 71 and the third transmission stage 72 to the differential gear 80 and thus to the wheel drive shaft 103 .

A torque provided by the rotor 21 of the second rotary electric machine 20 is transmitted independently of a shift of the first separating clutch 50 via the second separating clutch 120 and the second transmission stage 71 and the third transmission stage 72 to the differential gear 80 and thus to the wheel drive shaft 103.

Accordingly, the drive arrangement 100 can be operated in a large number of driving operating modes.

By opening the second separating clutch 120, the second electric rotary machine 20 can be decoupled from the operation of the first electric rotary machine 10 and the internal combustion engine 110, so that no energy is required to rotate the rotor 21 of the second electric rotary machine 20.

3 shows a detail of the drive assembly 100 according to the invention in a sectional side view.

the 2 is a more detailed representation of some of the in 1 indicated components, where in 2 the internal combustion engine is not shown and the output element 111 of the internal combustion engine coupled to the vibration damper 101 is only partially shown.

In 3 A first housing 60, a second housing 61 and a housing element 62 can be seen, which are connected to one another and form an overall housing of the drive arrangement 100 or of the drive unit 1. The first and second housings 60, 61 serve to accommodate the two rotary electric machines 10, 20, with the housing element 62 serving to couple the first housing 60 and the second housing 61 to a housing of the internal combustion engine (not shown). For this purpose, the first housing 60 is fixedly connected to the second housing 61 in the axial direction, with the housing element 62 being fixedly connected to the second housing 61 on the side of the second housing 61 axially opposite the first housing 60 .

The first shaft 40 is mounted with its first axial end area 42 via a single-row support bearing 92 in the first housing 60 and is mounted with its second axial end area 43 by means of needle bearings radially inward on a second axial end area 45 of the second shaft 41 .

The second shaft 41 is mounted on the first shaft 40 with its first axial end area 44 and with its second axial end area 45 .

Furthermore, a common stator carrier 32 carrying the stators 12, 22 of the electric rotary machines 10, 20 is fixedly connected to the first housing 60, so that the stators 12, 22 of the electric rotary machines 10, 20 as a stator unit 31 can be supported by the first housing 60 are worn.

The stator unit 31 is fixed to the first housing 60 by a support screw 33 which is passed through the entire stator unit 31 in the axial direction and is screwed in the first housing 60 in the axial direction.

The rotor carrier 30 of the rotor 21 of the second electric rotary machine 20 is mounted on the second housing 61 via a rotor flange 35 by means of the central bearing unit 90 . This central bearing unit 90 comprises two coaxially arranged roller bearings which are positioned axially close together.

A transmitter element of a rotor position sensor 34 is also connected to rotor carrier 30, with a detector element of rotor position sensor 34 being connected to second housing 61, so that an angular position and/or a rotational speed of rotor 21 of second electric rotary machine 20 or of the Rotor carrier 30 can be carried out by the rotor position sensor 34 .

The intermediate shaft 81 and the wheel drive shaft 103 are each mounted in the second housing 61 on their axial side facing the rotary electric machines 10, 20 and mounted in the housing element 62 on their opposite axial side. The connecting element 4 of the drive unit 1 is mounted on the housing element 62 via a double-row bearing unit 93 . This double-row bearing unit 93 comprises two coaxially arranged roller bearings which are positioned axially close together. The vibration damper 101 is arranged in the housing element 62 .

Furthermore, power electronics 102 are arranged radially on the outside on the first and second housing 60, 61, with the power electronics 102 being set up to control the electrical rotary machines 10, 20. A heat exchanger 105 of a cooling circuit for cooling at least one of the rotary electric machines 10, 20 on the second housing 61 is also arranged between the second housing 61 and the power electronics 102. A pump actuator 104 of this cooling circuit is carried by the housing element 62 .

3 also shows a detailed structure of the transmission stages 70, 71, 72. The first transmission stage 70 is designed in such a way that the connection element 4 comprises an internally toothed gear 5 which meshes with external teeth 46 on the second axial end region 43 of the first shaft 40.

The second shaft 41 also has external teeth 47 on its second axial end region 45, with which it meshes with a first gear wheel 82, with the first gear wheel 82 being arranged on the intermediate shaft 81 in a rotationally fixed manner, so that the second transmission stage 71 is between the second shaft 41 and the intermediate shaft 81 is formed.

An external toothing 84 of the intermediate shaft 81 meshes with a second gear 83 as an input element of the differential gear 80, as a result of which the third transmission stage 72 is formed between the intermediate shaft 81 and the differential gear 80.

As magnified in 4 shown, the first separating clutch 50 corresponds to a frictionally lockable multi-disk clutch, the input side 51 of which is formed by outer disks, which are arranged axially next to the rotor 11 of the first rotary electric machine 10 on the first shaft 40, the inner disks of the first separating clutch 50 being non-rotatable and axially displaceable as the output side 52 of which is connected to an external toothing of the second shaft 41 . An actuating system 53 for actuating the first separating clutch 50 and also the second separating clutch 120 on the second housing 61 is arranged radially outside of the central bearing unit 90 . The actuation system 53 includes a hydraulic slave unit 54, which can be subjected to oil pressure by means of a transmitter unit that is not described in detail. When this pressure is applied, a piston 55 moves in the cylinder 56 and displaces a thrust bearing 57 which presses on the pressure piece 121 in the axial direction.

Pressure piece 121, designed as a pressure pot, of actuation system 53 reaches axially through rotor carrier 30 in order to transmit an actuation force provided by actuation system 53 to first separating clutch 50 for the purpose of closing it, while at the same time opening second separating clutch 120.

The second separating clutch 120 comprises an engagement bearing 122 arranged on the pressure piece 121, which is designed here as an axial ball bearing. In the embodiment shown here, the second separating clutch 120 is designed as a claw clutch. The input side 121 of the second separating clutch 120 is formed by a first engagement element 125 which has a plurality of axially aligned claws. In the closed state of the second separating clutch 120, these claws or these first engagement elements 125 engage in also axially aligned claws which, as the output side 124 of the second separating clutch 120, form the second engagement elements thereof. in the in 4 The state shown is that the second separating clutch 120 is closed, so that a torque transmission path from the rotor 22 of the second rotary electric machine 20 to the second shaft 41 is closed and the second rotary electric machine 20 is correspondingly connected for driving.

5 shows the second separating clutch 120 in an enlarged view. It can also be seen here that a spring element 130, designed as a disc spring and supported radially on the outside of the housing, is supported radially on the inside of the pressure piece 121 and applies a compressive force to it in a direction such that the second separating clutch 120 is closed, in that the input side 123 and the output side 124 of the second separating clutch 120 engage in one another.

5 shows the component positions at the operating point of serial driving. In the pressureless state, the piston 55 is held in the rearmost position by the spring element 130 .

The input side 123 of the second separating clutch 120 is non-rotatably connected to the output side 124 of the second separating clutch 120 .

In this position, the second electrical rotary machine 20 can drive the wheels, being supplied with electrical energy either via the first electrical rotary machine 10, which is driven by the internal combustion engine and operated as a generator, or via a battery.

The torque transmission path is indicated here by dashed lines.

6 now shows the state when the actuation system 53 is actuated and the component positions at the parallel driving operating point. This actuation of the actuation system 53 leads to an axial movement of the piston 55 so that it displaces the thrust bearing 57 . This presses on the pressure piece 121, which moves both the first engagement element 125, designed as a claw, of the second separating clutch 120 and the engagement bearing 122.

In this way, the engagement bearing 122 arranged on the pressure piece 121 presses axially against the disk set of the first separating clutch 50. As a result, the disks of the disk set are pressed together and the first separating clutch 50 is closed. Correspondingly, a torque can be transmitted from the input side 51 of the first separating clutch 50 to the output side 52, and thus to the second shaft 41.

The axial movement of the pressure piece 121 simultaneously disengages the input side 123 of the second separating clutch 120 or its first engagement elements 125 from the output side 124 of the second separating clutch 120 or its second engagement elements 126 . In other words, the claws of the second disconnect clutch are no longer engaged with each other in this state. In 6 this is clearly evident from the axial distance between input side 123 and output side 124 of second separating clutch 120. Accordingly, second separating clutch 120 is opened as a result, so that a torque transmission path between second electric rotary machine 20 and second shaft 41 is interrupted. The second rotary electric machine 20 can be switched off.

A connected internal combustion engine drives the wheels in this position, with the first electric rotary machine 10 connected to it being able to be used as a generator for recuperation or as a motor for boosting. The torque transmission path is indicated here by dashed lines.

If the second separating clutch 120 is to be closed again, i.e. to be switched over from parallel operation to serial operation, and the first separating clutch 50 is to be opened again, the second electric rotary machine only has to be rotated load-free up to a synchronous speed with the second shaft and to depressurize the actuating system 53 so that the pressure piece 121 is pushed back into the initial situation due to the compressive force realized by the spring element 130 .

Reference List

1

drive unit

2

Input side of the drive unit

3

Output side of the drive unit

4

Connection element of the drive unit

5

internally toothed gear wheel of the connecting element

10

first electric rotary machine

11

Rotor of the first rotary electric machine

12

Stator of the first rotary electric machine

20

second rotary electric machine

21

Rotor of the second rotary electric machine

22

Stator of the second rotary electric machine

30

Rotor carrier of the second rotary electric machine

31

stator unit

32

common stator carrier

34

rotor position sensor

35

rotor flange

40

first wave

41

second wave

42

first axial end portion of the first shaft

43

second axial end portion of the first shaft

44

first axial end portion of the second shaft

45

second axial end portion of the second shaft

46

External gearing of the first shaft

47

External gearing of the second shaft

50

first disconnect clutch

51

Input side of the first separating clutch

52

Output side of the first separating clutch

53

actuation system

54

hydraulic slave unit

55

Pistons

56

cylinder

60

first housing

61

second housing

62

housing element

70

first translation stage

71

second translation stage

72

third level of translation

80

differential gear

81

intermediate shaft

82

first gear

83

second gear

84

External gearing of the intermediate shaft

90

central storage unit

92

support bearing

93

double row bearing unit

100

drive arrangement

101

vibration damper

102

power electronics

103

wheel drive shaft

104

pump actuator

105

heat exchanger

110

internal combustion engine

111

Output element of the internal combustion engine

120

second disconnect clutch

121

Pressure piece

122

engagement bearing

123

Input side of the second separating clutch

124

Output side of the second separating clutch

125

first engagement element

126

second engagement element

130

spring element

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 112015006071 T5 [0003]
• WO 2019101264 A1 [0004]
• US20160218584A1 [0005]
• EP 1502791 B1 [0006]
• EP 1847411 B1 [0006]

Claims (10)

Drive unit (1) for a drive train of an electrically drivable motor vehicle, having a first electric rotary machine (10) and a second electric rotary machine (20) and a first shaft (40) and a second shaft (41), with a rotor (11) of the first electric rotary machine (10) is non-rotatably connected to the first shaft (40) and wherein the drive unit (1) also has a first separating clutch (50) with which the rotor (11) of the first electric rotary machine (10) for torque transmission with the second shaft (41) can be connected or is connected, characterized in that the drive unit (1) also has a second separating clutch (120) with which a rotor (21) of the second electric rotary machine (20) can be used to transmit torque to the second shaft (41 ) connectable or connected. drive unit after claim 1 , characterized in that the second separating clutch (120) is a dog clutch. Drive unit according to one of the preceding claims, characterized in that the first separating clutch (50) is a multi-plate clutch. Drive unit according to one of the preceding claims, characterized in that the drive unit has an actuating system (53) with which the first separating clutch (50) can be closed and the second separating clutch (120) opened at the same time. Drive unit according to claims 2 , 3 and 4 , characterized in that the actuating system (53) comprises an axially displaceable pressure piece (121) with which a force can be applied to a disk pack of the first separating clutch (50) designed as a disk clutch during axial displacement, so that this is pressed together and the first separating clutch (50) is thereby closed, and which can be mechanically connected or is connected to a first engagement element (125) of the second separating clutch (120) designed as a claw clutch, the axial displacement of the pressure piece (121) causing the closing of the first separating clutch (50). Engagement of the first engagement element (125) in a second engagement element (126) of the dog clutch and the second separating clutch (120) is thereby opened. Drive unit (1) according to one of the preceding claims, characterized in that the first electric rotary machine (10) is arranged at least in regions radially and axially within a space delimited radially by the second electric rotary machine (20), the first electric rotary machine (10) is designed as an internal rotor motor and the second electrical rotary machine (20) is designed as an external rotor motor, and wherein the stator (12) of the first electrical rotary machine (10) and the stator (22) of the second electrical rotary machine (20) are mechanically fixed to one another. Drive unit (1) according to one of the preceding claims, characterized in that the two shafts (40, 41) are arranged coaxially. Drive unit (1) according to one of the preceding claims, characterized in that the first electric rotary machine (10) is set up for generator operation. Drive unit (1) according to one of the preceding claims, characterized in that the second electric rotary machine (20) is set up for drive motor operation. Drive arrangement (100) with a drive unit (1) according to one of Claims 1 until 9 and with an internal combustion engine (110) which is coupled or can be coupled in a rotationally fixed manner to the rotor (11) of the first electric rotary machine (10) by means of an output element (111) of the internal combustion engine (110).

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