DE102020131906B4 - Hybrid drivetrain for a hybrid-powered vehicle - Google Patents

Abstract

Hybrid drive train for a hybrid-driven vehicle, with an electric machine (5) and an internal combustion engine (1), the power output shaft (10) of which drives alternately either to a first input shaft (7) or to a second input shaft (9) of a dual clutch transmission (3) via two power-shiftable separating clutches (K1, K2) of a dual clutch, wherein a first partial transmission (I) or a second partial transmission (II) can be activated by means of the input shafts (7, 9), and wherein fixed and loose gears are arranged on the two input shafts (7, 9) and a common output shaft (13) axially parallel thereto in exactly four gear planes (R1 to R4), which are combined to form gear stages (1, 2, 3, 4) to form gear sets in which the loose gears can be switched by means of switching elements (S24, S13), wherein the electric machine (5) is connected to one of the two input shafts (7, 9) in a torque-transmitting manner, wherein the electric machine (5) is arranged axially parallel with an axle distance (a) to the first input shaft (7), and wherein the electric machine (5) acts on the first input shaft (7) via a gear (11) which bridges the axle distance (a), characterized in that the hybrid drive train is designed for an all-wheel drive in which both the front axle (VA) and the rear axle (HA) of the vehicle can be driven by means of the transmission (3).

Description

The invention relates to a hybrid drive train for a hybrid-powered vehicle according to the preamble of claim 1.

An example hybrid drive train has an electric machine, an internal combustion engine and a dual clutch transmission, in which a power output shaft of the internal combustion engine drives alternately either to a first input shaft or to a second input shaft of the dual clutch transmission via two power-shiftable separating clutches of a dual clutch. A first partial transmission or a second partial transmission of the dual clutch transmission can be activated using the input shafts. Fixed and loose gears are arranged in exactly four gear planes on the two input shafts and a common output shaft parallel to the axis. These are combined to form gear stages to form gear sets in which the loose gears can be coupled to the shafts using switching elements. The electric machine can act on one of the two input shafts.

From the EN 10 2014 223 339 A1 and from the EN 10 2014 223 340 A1 A torque transmission device is known in each case. From the WO 2016 / 075 334 A1 , from the WO 2016 / 075 335 A1 , from the WO 2016 / 075 336 A1 and from WO 2016 / 075 337 A1 Other torque transmission devices are known. EN 10 2016 221 060 A1 A hybrid drive train is known. From the EN 10 2016 221 097 A1 A torque transmission device for hybrid drives is known.

From the EN 10 2015 201 458 A1 is a generic hybrid drive train for a motor vehicle. The EN 10 2016 207 221 A1 reveals a dual-clutch transmission in countershaft design. From the GB 2 506 601 A is an electronically assisted dual-clutch transmission. The EN 10 2017 223 758 A1 discloses a gear arrangement. From the EN 10 2009 025 094 A1 A gear unit and an electrical supplementary unit are known. The EN 10 2010 006 043 A1 reveals a hybrid powertrain.

The object of the invention is to provide a hybrid drive train for a hybrid-powered vehicle which, in comparison to the prior art, has a reduced number of components, a simple design and a structurally favorable transmission structure, while offering a greater number of degrees of freedom in terms of functionality (i.e. shifting strategy) and in the design of the gear ratios.

The object is solved by the features of patent claim 1. Preferred developments of the invention are disclosed in the subclaims.

The transmission according to the invention with exactly four gear planes and the drive-side electric machine connection realizes a transmission functionality with little gear technology effort and with little installation space requirement that can only be achieved in the prior art with a dual clutch transmission that has a much larger number of gear planes, about eight gear planes. Such a conventional dual clutch transmission is therefore much more complex in design and has a large axial length.

In contrast to this, the invention relates to a hybrid drive train that is axially short and has the smallest possible switching elements. The hybrid drive train is therefore suitable for both longitudinal and transverse installation in the vehicle.

Overall, the four combustion engine forward gears and two additional electric motor forward gears can be switched using just two switching elements with the lowest possible gear technology effort. The invention provides a drive-side electric machine connection. According to claim 1, the electric machine is arranged parallel to the axis with an axle distance from the input shaft. The electric machine acts on the input shaft via a countershaft for torque conversion, which bridges the axle distance. The countershaft preferably has a countershaft gearwheel that is mounted on an electric machine shaft, in particular in a rotationally fixed manner, and which meshes with a drive-side gearwheel of one of the four gear levels.

The four forward gears of the combustion engine can be implemented as direct forward gears, each of which uses only one gear plane.

The drive-side electric machine connection according to the invention has the following advantages: The drive-side electric machine connection enables purely electric motor driving (for example, parking pilot, traffic jam pilot, electric creeping, among others). Boost operation in the low or high torque range is also guaranteed. An optimal transmission ratio for the representation of the electric driving functions is also possible. In addition, sailing operation and, if necessary, an internal combustion engine start or an internal combustion engine start as well as a cold start are possible. The drive-side electric machine connection also enables a Support for synchronization in the dual clutch transmission.

In a compact design variant, all four gear planes can be arranged in a sequence in the axial direction between the internal combustion engine and the electric machine. The first gear plane can be positioned on the transmission side facing the internal combustion engine. In contrast, the fourth gear plane can be positioned on the transmission side facing the electric machine.

In common practice, the even gears and the odd gears are preferably arranged in pairs in each sub-gearbox. Otherwise, the allocation of the combustion engine gears to the respective gear levels can be freely varied (e.g. 1-3-2-4, 3-1-2-4,...).

Within the scope of the invention, several options for connecting the electric machine to the gear planes can be implemented. In order to reduce the installation space, the countershaft can preferably be connected to the fourth gear plane facing the electric machine. In this case, the countershaft gear can mesh with a gear wheel designed as a fixed gear wheel on the fourth gear plane facing the electric machine. The electric machine therefore acts on the immediately adjacent fourth gear plane via the countershaft gear.

An essential aspect of the invention relates to the reduction of the gear stage gear planes to exactly four gear planes and a greatly reduced number of shifting elements. Preferably, exactly two gear planes and exactly one shifting element can be arranged in each partial transmission. In contrast to the partial transmissions, the countershaft can preferably be completely free of further shifting elements. With such a transmission structure, the hybrid drive train therefore has a total of only two shifting elements. These can preferably be implemented as double synchronous clutches that can be switched axially on both sides. The respective shifting element can thus be arranged axially between the two gear stage gear planes of the partial transmission in order to couple an idler gear of the gear plane to be switched with one of the input shafts or with the output shaft.

The switching elements can be arranged either on the drive shaft or on the output shaft. In order to reduce drag torques, it is particularly preferred if the output-side gears of all four gear levels are mounted as loose gears on the output shaft. In contrast, the drive-side gears of all gear levels can be arranged as fixed gears on the respective input shaft in a rotationally fixed manner. In this case, the output shaft is free of gears, i.e. the output shaft does not have a gear arranged on it in a rotationally fixed manner, but rather only the coupling teeth of the two switching elements.

In order to achieve a simple and space-saving transmission structure, it is also preferable if the output shaft drives an axially parallel drive shaft of an axle differential via an axially short spur gear stage. The spur gear stage can be structurally positioned in the axial direction between the double clutch and the first gear stage gear plane. The drive shaft of the axle differential can be designed as an axle differential pinion shaft of the vehicle axle.

To easily implement a reverse gear, the electric machine of the hybrid drive train can be operated in the opposite direction of rotation, forming an electric motor reverse gear, so that an additional reverse gear wheel plane, as would be required for a mechanical reverse gear, is eliminated.

The hybrid drive train according to the invention can be installed both longitudinally and transversely in the vehicle. A particularly preferred longitudinal installation situation of the hybrid drive train in the vehicle is described below: In the longitudinally installed hybrid drive train, the transmission shafts can be aligned in the longitudinal direction of the vehicle. Especially in the case of a front-side longitudinal installation in the vehicle, the electric machine can be positioned in the longitudinal direction of the vehicle behind the transmission (for example, in a vehicle tunnel for optimal installation space). The electric machine can be positioned in partial lateral overlap with the transmission in the transverse direction of the vehicle or, alternatively, can be positioned behind the transmission without lateral overlap.

According to the invention, the hybrid drive train is designed for all-wheel drive, in which both the front and rear axles of the vehicle can be driven via the transmission. A space-saving and structurally simple implementation of the all-wheel drive is of crucial importance: Against this background, the output shaft can be designed in two parts, namely with an output hollow shaft on which the gear wheels of all four gear levels are arranged, and with an output inner shaft on which the output hollow shaft is coaxially rotatably mounted. In the installed position, the output hollow shaft can extend in the vehicle's longitudinal direction to the rear of the vehicle beyond the transmission housing with a shaft The shaft end piece of the hollow output shaft can be extended axially. The shaft end piece of the hollow output shaft can be connected to an input side of an intermediate differential. From the two output sides of the intermediate differential, an end shaft leads to the rear of the vehicle towards the rear axle of the vehicle and the inner output shaft to the front axle differential. In this case, the inner output shaft can be connected to a drive shaft of the front axle differential via the spur gear stage.

In an arrangement that saves space, both the electric motor and the intermediate differential can be arranged axially parallel to one another. In addition, both the electric motor and the intermediate differential can be positioned axially behind the transmission, in particular by being flanged to a transmission housing wall.

In a specific design variant of the dual clutch transmission, a second input shaft can be a hollow shaft that is coaxially rotatably mounted radially on the outside of the first input shaft. The second partial transmission assigned to the second input shaft can face the dual clutch in the axial direction. In contrast, the first partial transmission assigned to the first input shaft can be axially spaced from the dual clutch with the second partial transmission in between. All even combustion engine gears can be assigned to one partial transmission, while all odd combustion engine gears can be assigned to the other partial transmission.

An embodiment of the invention is described below with reference to the accompanying figures.

• 1 und 2 eine Getriebestruktur des Hybridantriebsstrangs sowie ein Schaltschema.

Show it:

• 1 and 2 a transmission structure of the hybrid powertrain and a shift diagram.

In the 1 a hybrid drive train for a hybrid-driven vehicle is shown, which essentially consists of an internal combustion engine 1, a dual-clutch transmission 3 and an electric machine 5. The dual-clutch transmission 3 has a first input shaft 7 and a second input shaft 9. These are arranged coaxially and can be connected to a power output shaft 10 in a torque-transmitting manner via two, for example, hydraulically actuated power-shiftable separating clutches K1, K2 and via an upstream torsional vibration damper 8. The first input shaft 7 is in the 1 realized as a solid shaft which is guided coaxially within the second input shaft 9 realized as a hollow shaft.

The dual clutch transmission 3 has 1 a total of exactly four combustion engine forward gears 1 to 4. These are implemented in exactly four gear levels R1 to R4 by corresponding gear sets, each with one loose gear and one fixed gear, which can be switched via a total of exactly two switching elements S24 and S13 (i.e., for example, double synchronous clutches). The output-side gears of the gear levels R1 to R4 forming the gear levels are in the 1 all arranged on a common axially parallel output shaft 13. The output shaft 13 drives a drive shaft 19 of a front axle differential 21 via a gear stage 14 with spur gears 15, 17.

By means of the first and second input shafts 7, 9, a first partial transmission I and a second partial transmission II of the dual clutch transmission 3 can be activated. The first partial transmission I is assigned 1 all even forward gears 2, 4 are assigned, while all odd forward gears 1, 3 are assigned to the second partial transmission II. Accordingly, the even forward gears 2, 4 can be activated via the first input shaft 7 and the first separating clutch K1. In contrast, the odd forward gears 1, 3 of the second partial transmission II can be activated via the second input shaft 9 and the second separating clutch K2. The first partial transmission I is in the 1 , viewed in the axial direction, with the interposition of the second partial transmission II axially spaced from the double clutch K1, K2, which in the 1 is arranged at the left outer end of the transmission. The electric machine 5 is positioned at the opposite right axially outer end of the dual clutch transmission 3.

The electric machine 5 is in the 1 arranged axially parallel with an axial distance a to the input shaft 7. In addition, the electric machine 5 acts on the input shaft 7 via a countershaft 11 for torque conversion, which bridges the axial distance a. The countershaft 11 has a countershaft gear 12 which is mounted on an electric machine shaft 25 in a rotationally fixed manner and which meshes with a drive-side gear wheel of the fourth gear stage gear plane R4.

In the 1 all four gear planes R1 to R4 are arranged in the axial direction in a sequence one after the other between the internal combustion engine 1 and the electric machine 5. The first gear plane R1 is positioned on the transmission side facing the internal combustion engine 1, while the fourth gear plane R4 is positioned on the transmission side facing the electric machine 5. Each of the two partial transmissions I, II has exactly two gear planes and exactly one switching element S24, S13. In the axial direction between the double clutch K1, K2 and the first gear plane R1 is in the 1 the spur gear stage 14 is positioned.

Between the two gear planes of each partial transmission I, II, exactly one switching element S24, S13 is arranged, with which an idler gear of the gear plane to be switched can be coupled to the output shaft 13.

With regard to a simple implementation of a reverse gear, the 1 the electric machine 5 can be operated in the opposite direction of rotation, thereby forming an electromotive reverse gear.

In the 1 The hybrid drive train is installed in a front-side longitudinal installation in the vehicle. In the longitudinally installed hybrid drive train, the transmission shafts 7, 9, 13 are aligned in the vehicle's longitudinal direction x. In the front-side longitudinal installation of the 1 the electric machine 5 is positioned in the vehicle longitudinal direction x behind the transmission 3, for example in a vehicle tunnel, wherein the electric machine 5 is arranged without lateral overlap with the transmission 3 or is flanged to a rear transmission outer wall 26.

In the 1 the hybrid drive train is designed for all-wheel drive, in which both the front axle VA and the rear axle HA of the vehicle can be driven by means of the transmission 3. For this purpose, the output shaft 13 is designed in two parts, namely with a hollow output shaft 22 and an inner output shaft 23. The gear wheels of all four wheel planes R1 to R4 are arranged on the hollow output shaft 22. The hollow output shaft 22 is coaxially rotatably mounted on the inner output shaft 23. The hollow output shaft 22 is axially extended in the vehicle's longitudinal direction x towards the rear of the vehicle with a shaft end piece. The shaft end piece is connected to an input side of an intermediate differential 29, which is flanged to the transmission housing wall 26. From its output sides, an end shaft 31 leads to the rear of the vehicle in the direction of the rear axle HA and the output inner shaft 23 (radially within the output hollow shaft 22) to the front axle differential 21. From the two output sides of the front axle differential 21, flange shafts 33 are guided in the vehicle transverse direction y to the vehicle front wheels (not shown).

In order to achieve a space-saving arrangement, both the electric motor 5 and the intermediate differential 29 are arranged axially parallel to one another and are positioned axially behind the transmission 3.

A regular shift sequence of the combustion engine gears can be: 1-2-3-4, with the first combustion engine gear being engaged via the closed second separating clutch K2 (partial transmission II) and the other gears being engaged by alternately closing the separating clutches K1, K2. As is known, the next gear can be preselected in the partial transmission with the open separating clutch, so that shifting can be done by switching the clutches K1, K2 without interrupting the traction. The shift sequence can be specified and/or manually adjusted via an electronic transmission control (not shown) depending on the operating data and driving parameters of the vehicle.

• Bei eingelegtem verbrennungsmotorischen ersten Gang V1 ist die zweite Trennkupplung K2 geschlossen und das Schaltelement S13 des zweiten Teilgetriebes II nach links (Schaltstellung S1) betätigt, so dass ein Loszahnrad der, die erste Gangstufe bildenden ersten Radebene R1 mit der Abtriebswelle 13 gekoppelt ist. Bei eingelegtem ersten Gang V1 ergibt sich somit ein Lastpfad von der Brennkraftmaschine 1 über die zweite Trennkupplung K2, die erste Radebene R1 bis zur Abtriebs-Hohlwelle 22. Von dort führt der Lastpfad weiter bis zum Zwischendifferenzial 29, in der eine Momentenverteilung auf die Endwelle 31 und auf die Abtriebs-Innenwelle 23 stattfindet. Von der Abtriebs-Innenwelle 23 führt der Lastpfad über die Stirnradstufe 14 weiter bis zum Vorderachsdifferenzial 21.

The following are based on the 2 The following driving modes are described in the circuit diagrams shown:

• When the internal combustion engine's first gear V1 is engaged, the second separating clutch K2 is closed and the shifting element S13 of the second partial transmission II is actuated to the left (shifting position S1), so that an idler gear of the first gear plane R1 forming the first gear stage is coupled to the output shaft 13. When the first gear V1 is engaged, a load path is thus created from the internal combustion engine 1 via the second separating clutch K2, the first gear plane R1 to the hollow output shaft 22. From there, the load path continues to the intermediate differential 29, in which a torque distribution takes place to the end shaft 31 and to the inner output shaft 23. From the inner output shaft 23, the load path continues via the spur gear stage 14 to the front axle differential 21.

In the combustion engine's first gear V1, hybrid operation, such as boost operation, is possible. If the driver so wishes, acceleration can take place in boost operation (i.e. when increased power is required, for example when overtaking) with an additional boost torque provided by the electric machine 5. In this case, the electric machine 5 can be used as an auxiliary drive source. According to the 1 Two hybrid gears H1a, H1b are available for the engaged first gear V1: When the switching element S24 is moved to the left (switch position S2), the gear plane R3 forming the second gear is integrated into a first boost load path in which boosting is carried out via the second gear (i.e. high torque). When the switching element S24 is moved to the right (switch position S4), the gear plane R4 forming the fourth gear is integrated into a boost load path in which boosting is carried out via the fourth gear (i.e. low torque).

When the second internal combustion engine gear V2 is engaged, the first separating clutch K1 is closed and the first switching element S24 is actuated to the left (switching position S2), so that a loose gear of the gear plane R3 forming the second gear is coupled to the output shaft 13. When the second gear V2 is engaged, a load path results from the internal combustion engine 1 via the first separating clutch K1, the third gear plane R3 to the output hollow shaft 13 and then continues as described for the first gear V1.

In the second combustion engine gear V2, hybrid operation, such as boost operation, is also possible (hybrid gear H2). For this purpose, the electric motor 5 is revved up so that power is added in the third gear plane R3, in which the boost torque is added to the combustion engine torque.

When the third internal combustion engine gear V3 is engaged, the second separating clutch K2 is closed and the switching element S13 of the second partial transmission II is actuated to the right (switching position S3), so that a loose gear of the second gear plane R2 forming the third gear is coupled to the output shaft 13. When the third gear V3 is engaged, this results in a load path from the internal combustion engine 1 via the second separating clutch K2, the second gear plane R2 to the hollow output shaft 22. From there, the load path continues as described for the first gear V1. In the third internal combustion engine gear V3, hybrid operation, such as boost operation, is possible, which can be implemented in a similar way to that described for the first gear V1 (hybrid gear H3a, H3b).

When the fourth internal combustion engine gear V4 is engaged, the first separating clutch K1 is closed and the first switching element S24 is actuated to the right (switching position S4), so that a loose gear of the gear plane R4 forming the fourth gear is coupled to the output shaft 13. When the fourth gear V4 is engaged, a load path results from the internal combustion engine 1 via the first separating clutch K1, the fourth gear plane R4 to the output hollow shaft 13. From there, the load path continues as described for the first gear V1.

Boost operation is also possible in the combustion engine's fourth gear V4. For this purpose, the electric motor 5 is revved up so that power is added in the fourth gear plane R4, in which the boost torque is added to the combustion engine torque.

For purely electric driving, purely electromotive gears E1 and E2 can be engaged, with the internal combustion engine 1 shut down. When the first electromotive gear E1 is engaged, the first switching element S24 is actuated to the left (switch position S2). This results in a load path in which the electromotive torque is guided from the electric machine 5 via the gear reducer 11 and via the gear plane R3 forming the second gear to the output hollow shaft 22. From there, the load path continues as described for the first gear V1.

When the second electromotive gear E2 is engaged, the first shift element S24 is actuated to the right (shift position S4). This results in a load path in which the electromotive torque is guided from the electric machine 5 via the gear reduction gear 11 and via the gear plane R4 forming the fourth gear to the output hollow shaft 22. From there, the load path continues as described for the first gear V1.

In addition, stand-by charging is possible. This can be activated when the vehicle is stationary, for example at a traffic light or in a traffic jam. In stand-by charging mode, the first separating clutch K1 is closed and the two switching elements S24 and S13 are in the load-free neutral position. This results in a load path in which a combustion engine torque is transmitted to the electric machine 5 via the first closed separating clutch K1, the first input shaft 7 and the gear box 11.

• So ist vor dem Schaltvorgang, d.h. bei noch eingelegtem ersten Gang V1, die zweite Trennkupplung K2 geschlossen und die ersten Trennkupplung K1 noch geöffnet. Zudem ist die Elektromaschine 5 stillgelegt, so dass die erste Eingangswelle 7 und die Gangzahnräder der, den zweiten Gang bildenden dritten Radebene R3 stillstehen. Zum Vorwählen des zweiten Gangs V2 kann eine Synchronisation erfolgen, bei der die Elektromaschine 5 hochgefahren wird, bis das Loszahnrad der dritten Radebene R3 in etwa mit gleicher Drehzahl dreht wie die Abtriebswelle 13. Mit Erreichen der Drehzahlgleichheit wird der zweite Gang V2 vorgewählt, d.h. das Schaltelement S24 wird in der 1 nach links gerückt (Schaltstellung S2). Anschließend wird die Elektromaschine 5 wieder stillgelegt. Dann erfolgt eine Lastübertragung, bei der die zweite Trennkupplung K2 geöffnet wird und gleichzeitig die erste Trennkupplung K1 geschlossen wird.

With the drive-side electric machine connection according to the invention, synchronization can also be achieved when shifting from first gear V1 to second gear V2 and when shifting from third gear V3 to fourth gear V4. A shifting process from first gear V1 to second gear V2 is described below as an example:

• Thus, before the gear shift, i.e. when the first gear V1 is still engaged, the second separating clutch K2 is closed and the first separating clutch K1 is still open. In addition, the electric machine 5 is shut down, so that the first input shaft 7 and the gear wheels of the third gear plane R3 forming the second gear are stationary. To preselect the second gear V2, a synchronization can be carried out, in which the electric machine 5 is started up until the idler gear of the third gear plane R3 rotates at approximately the same speed as the output shaft 13. When the speeds are equal, the second gear V2 is preselected, i.e. the switching element S24 is in the 1 moved to the left (switch position S2). The electric machine 5 is then shut down again. A load transfer then takes place, during which the second separating clutch K2 is opened and the first separating clutch K1 is closed at the same time.

LIST OF REFERENCE SYMBOLS.

1

internal combustion engine

3

Double clutch

5

Electric machine

7

first input shaft

8th

Torsional vibration damper

9

second input shaft

10

Power output shaft

11

Countershaft

12

Electrical machine gear

13

Output shaft

14

Spur gear stage

15, 17

Spur gears

19

drive shaft

21

Front axle differential

22

Output hollow shaft

23

Output inner shaft

25

Electric machine shaft

26

Gearbox housing wall

29

Intermediate differential

31

End shaft (connection to the cardan shaft)

a

Axial distance

K1, K2

power-shift clutches

S13, S24

Switching elements

R1 to R4

Wheel levels

33

Flange shafts

I, II

Partial transmission

VA

Front axle

HA

Rear axle

V1 to V4

combustion engine gears

E1, E2

electromotor gears

H

Hybrid gears

SL

Stand shop

S1, S2, S3, S4

Switch positions

Claims (12)

Hybrid drive train for a hybrid-driven vehicle, with an electric machine (5) and an internal combustion engine (1), the power output shaft (10) of which drives alternately either to a first input shaft (7) or to a second input shaft (9) of a dual clutch transmission (3) via two power-shiftable separating clutches (K1, K2) of a dual clutch, wherein a first partial transmission (I) or a second partial transmission (II) can be activated by means of the input shafts (7, 9), and wherein fixed and loose gears are arranged on the two input shafts (7, 9) and a common output shaft (13) parallel to the axis thereto in exactly four gear planes (R1 to R4), which are combined to form gear stages (1, 2, 3, 4) to form gear sets in which the loose gears can be switched by means of switching elements (S24, S13), wherein the electric machine (5) is connected to one of the two input shafts (7, 9) in a torque-transmitting manner, wherein the electric machine (5) is arranged axially parallel with an axle distance (a) to the first input shaft (7), and wherein the electric machine (5) acts on the first input shaft (7) via a gear (11) which bridges the axle distance (a), characterized in that the hybrid drive train is designed for an all-wheel drive in which both the front axle (VA) and the rear axle (HA) of the vehicle can be driven by means of the transmission (3). Hybrid powertrain according to Claim 1 , characterized in that the countershaft (11) has a countershaft gear (12) which is mounted in a rotationally fixed manner on an electric machine shaft (25) and which meshes with a drive-side gear gear of one of the four gear stage gear planes (R1 to R4). Hybrid powertrain according to Claim 1 or 2 , characterized in that all four gear stage gear planes (R1 to R4) are arranged in an order one behind the other in the axial direction between the internal combustion engine (1) and the electric machine (5), and that the first gear plane (R1) is positioned on the transmission side facing the internal combustion engine (1) and the fourth gear plane (R4) is positioned on the transmission side facing the electric machine (5). Hybrid powertrain according to Claim 3 , characterized in that the countershaft gear (12) meshes with a gear wheel designed as a fixed gear of the fourth gear plane (R4) facing the electric machine (5), so that the electric machine (5) acts on the immediately adjacent fourth gear plane (R4) via the countershaft gear (12). Hybrid drive train according to one of the preceding claims, characterized in that each partial transmission (I, II) has exactly two gear planes and exactly one shifting element (S24, S13), and/or that the gear reduction gear (11) is free of further shifting elements, and/or that the respective shifting element (S24, S13), namely a double synchronous clutch, can be switched axially on both sides and is arranged between the two gear planes of the partial transmission (I, II), so that a loose gear of the gear plane to be switched can be coupled to one of the input shafts (7, 9) or the output shaft (13). Hybrid powertrain according to Claim 5 , characterized in that the output-side gear wheels of all four wheel planes (R1 to R4) are rotatably mounted as loose gear wheels on the output shaft (13), and that the drive-side gear wheels of all four wheel planes (R1 to R4) are arranged as fixed gear wheels on the respective input shaft (7, 9) in a rotationally fixed manner. Hybrid drive train according to one of the preceding claims, characterized in that the output shaft (13) drives a drive shaft (19) of an axle differential (21) via a spur gear stage (14) with spur gears (15, 17), and that the spur gear stage (14) is positioned in the axial direction between the double clutch (K1, K2) and the first gear plane (R1). Hybrid drive train according to one of the preceding claims, characterized in that the electric machine (5) can be operated in the opposite direction of rotation, specifically with the formation of an electromotive reverse gear. Hybrid drive train according to one of the preceding claims, characterized in that the hybrid drive train is installed in a longitudinal installation in the vehicle, and that in the longitudinally installed hybrid drive train the transmission shafts (7, 9, 13) are aligned in the vehicle longitudinal direction (x), and that in a front-side longitudinal installation in the vehicle the electric machine (5) is positioned in the vehicle longitudinal direction (x) behind the transmission (3), specifically in the vehicle tunnel, specifically without lateral overlap between the electric machine (5) and the transmission (3) in the vehicle transverse direction (y). Hybrid drive train according to one of the preceding claims, characterized in that for the all-wheel drive the output shaft (13) is designed in two parts with an output hollow shaft (22) on which the gear wheels of all four wheel planes (R1 to R4) are arranged, and an output inner shaft (23) on which the output hollow shaft (22) is coaxially rotatably mounted, and that in the vehicle longitudinal direction (x) towards the rear of the vehicle the output hollow shaft (22) is axially extended with a shaft end piece which is connected to an input side of an intermediate differential (29), and that from the output sides of the intermediate differential (29) an end shaft (31) leads to the rear of the vehicle to the rear axle (HA) and the drive inner shaft (23) leads to the front axle differential (21). Hybrid powertrain according to Claim 10 , characterized in that the electric machine (5) and the intermediate differential (29) are arranged axially parallel to one another, and/or that the electric machine (5) and the intermediate differential (29) are positioned in the axial direction behind the transmission (3). Hybrid drive train according to one of the preceding claims, characterized in that the second input shaft (9) is a hollow shaft which is rotatably mounted coaxially on the first input shaft (7), and that the second partial transmission (II) assigned to the second input shaft (9), viewed in the axial direction, faces the double clutch (K1, K2), while the first partial transmission (I) assigned to the first input shaft (7) is axially spaced from the double clutch (K1, K2) with the second partial transmission (II) in between, and that all even combustion engine gears (2, 4) are assigned to one partial transmission (I) and all odd combustion engine gears (1, 3) are assigned to the other partial transmission (II).

Images