WO2017211339A1

WO2017211339A1 - Hybrid transmission for a vehicle, method, and vehicle having the hybrid transmission

Info

Publication number: WO2017211339A1
Application number: PCT/DE2017/100310
Authority: WO
Inventors: Andreas Kinigadner; Thomas Mehlis
Original assignee: Schaeffler Technologies AG & Co. KG
Priority date: 2016-06-10
Filing date: 2017-04-19
Publication date: 2017-12-14

Abstract

The invention relates to hybrid vehicles, in which internal combustion motors and electric motors are used either jointly or alternatively to produce a traction torque for the hybrid vehicle. The transmissions of hybrid vehicles face the challenge of coupling the electric motor and/or the internal combustion motor into the drive train for torque transmission in accordance with the desired operating states. Furthermore, appropriate gear ratios matched to the internal combustion motor and appropriate gear ratios matched to the electric motor must be provided by the transmission, because the internal combustion motor and the electric motor have considerably different motor characteristic curves. In the design of the transmissions, there is conflict between the goals of greatest possible driving comfort of the hybrid vehicle and of a simple and economical design of the transmission. The problem addressed by the invention is that of proposing a hybrid transmission for a vehicle that provides a balanced solution in the conflict between driving comfort and complexity of the hybrid transmission. This problem is solved by a hybrid transmission (2), which enables a large number of operating states by means of few actuators.

Description

Hvbridaetrlebe for a vehicle. Procedure as well as vehicle with the

Hvbridaetriebe

The invention relates to a hybrid transmission for a vehicle, a method for operating the hybrid transmission and a vehicle with the hybrid transmission.

In hybrid vehicles, internal combustion engines and electric motors are optionally used together or alternatively to produce a traction torque for the hybrid vehicle. To the gearboxes of the hybrid vehicles, this poses the challenge of coupling the electric motor and / or the internal combustion engine into the drive train for torque transmission in accordance with the desired operating states. Furthermore, the transmission must be provided with corresponding translations, which are each tuned to the internal combustion engine and the electric motor, since they have significantly different engine characteristics. When designing the gearbox results in a field of tension between the greatest possible comfort when driving the hybrid vehicle and at the same time the desire for a simple and inexpensive construction of the transmission.

It is an object of the invention to provide a hybrid transmission for a vehicle, which provides a balanced solution in the tension between driving comfort and complexity of the hybrid transmission.

This object is achieved by a hybrid transmission with the Merkmaien of claim 1 and by a method having the features of claim 8. Preferred or advantageous embodiments of the invention will become apparent from the dependent claims, the following description and the accompanying drawings.

The subject of the invention is thus a hybrid transmission, which is suitable and / or designed for a vehicle. The vehicle is for example as a Passenger cars, lorries, buses, etc. trained. Preferably, the hybrid transmission is the only drive gear in the vehicle.

The hybrid transmission is designed to couple at least or exactly one electric motor and at least or exactly one internal combustion engine - also called an internal combustion engine - in order to direct its torque as traction torque to driven wheels of the vehicle.

The hybrid transmission has a first input shaft for coupling to the internal combustion engine. Optionally, the internal combustion engine forms part of the hybrid transmission. Between the first input shaft and the internal combustion engine, for example, damper or an intermediate gear can be arranged. Particularly preferably, the first input shaft is always rotationally coupled to an output shaft of the internal combustion engine. In particular, between the internal combustion engine and the first input shaft is not a completely separating element, such as a friction clutch or the like. In modified embodiments, on the contrary, it is possible to provide a starting clutch between the engine and the input shaft.

The hybrid transmission has a second input shaft for coupling to the electric motor. Optionally, the electric motor forms part of the hybrid transmission. The electric motor may be arranged coaxially with the second input shaft, but it is also possible for the electric motor to be offset in parallel or aligned at a different angle to the second input shaft. In these cases, respective intermediate gear are provided.

The first and second Eingangsswelie are, in particular with respect to the axis of rotation, aligned coaxially with each other. In particular, the first and the second input shaft are positioned in alignment with each other. The first and the second input shaft are preferably arranged next to one another. Furthermore, the hybrid transmission has an output field, wherein the output shaft can be operatively connected to the driven wheels, for example with a differential device for distributing the transmitted drive torque, or it can be coupled by transmission technology. The output shaft, in particular the axis of rotation of the output shaft, is arranged parallel, in particular offset in parallel, to the first and / or second input shaft. In this arrangement results in a very compact construction of the hybrid transmission.

It should be pointed out that the term "Sx", where x can be any index number, is used exclusively for the assignment and identification of the respective components the other wave can be transmitted.

The hybrid transmission has a S1-Doppelgetriebstufe and an S1 -Schalteinrichtung. The S1-Doppelgetriebestufe has a first and a second S1 gear stage, wherein it is preferred that they have different gear ratios. The S1-switching device may optionally, in particular controlled and / or selectively, the first input shaft via the first S1-gear stage or the first Eingangswelie via the second S1-gear stage with the output shaft gearbox connect. It is particularly preferred that the S1 Schaiteinrichtung can assume a neutral position, so that no connection between the first input shaft and the output shaft is made either on the first or on the second S1-gear stage. In particular, the first and the second S1-gear stage are arranged parallel to each other.

The hybrid transmission has an S2 gear stage and an S2 shift unit. The S2 shift device can optionally connect the second input shaft with the S2 gear stage or, alternatively, the second input shaft with the first input shaft by transmission technology. Particularly preferably, the S2 Schaiteinrichtung assume a neutral position. The hybrid transmission has an S3 dual-gear stage with an S3 shift device. The S3 double-gear stage has a first and a second S3 gear stage, which are preferably arranged parallel to each other. The SS switching device makes it possible to selectively connect the second input shaft via the first S3 gear stage or via the second S3 gear stage with the output shaft gearbox. Particularly preferably, the S3 switching device can assume a neutral position.

The hybrid transmission has a double gear, which can also be referred to as a two-lane, exactly two-lane or at least two-lane gear. The double gear has an S1 gear portion and an S2 gear portion, wherein the two gear portions are rotatably coupled together. Each of the gear portions is formed as a wheel, preferably as a gear, in particular with a straight toothing or helical toothing. It is envisaged that the S1-Zahnradabschnitt forms part of the S1 -Doppelgetriebestufe and the S2 tooth gear portion forms part of the S2 gear stage. In particular, the respective gear portion forms a torque transmitting wheel in one of the gear stages of the S1-Doppelgetriebstufe or in the S2 gear stage.

It is a consideration of the invention that can be implemented by a small number of switching devices, in the preferred case of maximum or exactly three actuators, in particular a power shiftable hybrid transmission. This is implemented by a transmission structure with two input waveforms and an axis-parallel output shaft. Both input times are arranged coaxially and can be interconnected by means of the switching devices. This constellation makes it possible to operate the internal combustion engine six-speed, with only three actuators are used, in particular exactly three actuators are used. In this constellation, it is possible that the electric motor can be operated both via the internal combustion engine gear ratios, that is, in parallel operation, as well as purely electrically. The internal combustion engine can then be decoupled from the drive train by means of the S1 -Schalteinrichtung and S2-switching device. Optionally, it is possible that the electric machine is operated in parallel during internal combustion engine speed change and supports the drive torque, so that can be switched without interruption. Correspondingly reversed process is the electromotive gear change. In addition, a generator operation is possible. The starting and / or reversing preferably takes place electrically, so that no friction clutches are necessary for this purpose. In particular, the hybrid transmission is formed friction clutch.

In a preferred embodiment of the invention, the double gear is formed as a loose wheel on the output shaft. Thereby, it is possible that the double gear can be arranged as a bridge member between components of the first and the second input shaft.

In a preferred constructional realization, the S1-switching device is arranged on the output shaft. Thus, the S1 switching device can set the double gear in rotation with the output shaft. By contrast, it is preferred that the first and second S1 gear stages each have a fixed gear on the first input shaft. If the S1-switching device is switched to the rotationally fixed coupling with the double gear, so there is a gearbox connection between the first Eingangswelie on the second S1 gear stage with the Ausgangswelie. If the idler gear of the first S1 gear stage is rotationally fixed by the S1 shift device, then a gearbox-type connection of the first input shaft via the first S1 gear stage to the output shaft results.

In a further development of the invention, it is preferred that the S2-switching device is arranged on the first input shaft and can set a loose wheel of the S2-gear stage with the first input shaft rotationally fixed, wherein the idler gear meshes with the S2 gear portion of the double gear. In one switching position thus the first and second input shaft are rotatably set together, in the other switching position, the idler gear is rotatably set with the second input field, so that a torque path is formed via the double gear. In this second switching position components of the first and the second input shaft via the double gear are connected to each other by transmission technology.

In a further development of the invention, the S 3-Sch a Heinrich tu ng arranged on the output shaft and can set either a loose wheel of the first S3 gear stage or a loose wheel of the second S3 ~ gear stage with the output rotation. The first and second S3 gear stages each have a fixed gear on the second input shaft. Thus, in the first shift position, a transmission connection can be implemented via the first S3 gear stage and in the second shift position via the second S3 gear stage.

In a preferred embodiment of the invention, the Schaiteinrichtungen, in particular the S1 -Schalteinrichtung, the S2-switching device and / or the S3-switching device, are designed as exclusively positive-locking shaft device. In particular, these are realized as unsynchronizing or unsynchronized switching device. For example, these are designed as a sliding sleeve device. After the hybrid transmission has the coupling of two engines, namely the internal combustion engine and the electric motor, each switching operation of the switching devices can be supported by the motors so that initially takes place a speed adjustment and subsequently without synchronization devices in the switching devices, the switching operation can be enforced. Another advantage of this embodiment is that the hybrid transmission is also loadschaitfähig and / or zugkraftunterbrechungsfrei switchable.

In a preferred embodiment of the invention, the hybrid transmission can be switched according to one, some or all of the following modes. In the table, an "X" means that a gear stage forms an operative connection or that a connection has been completed.

Another object of the invention relates to a method for operating the hybrid transmission, as described above or according to one of the preceding claims. It is envisaged that in the context of the method at least one of the switching devices is switched. In a preferred embodiment of the invention, the switching of the switching devices takes place under load. In this connection, it is particularly preferred that the switching devices are synchronized via the control of the internal combustion engine and / or the electric motor and, in particular, have no synchronizer devices which are based on frictional contact.

Another object of the invention relates to a vehicle with the hybrid transmission, as described above or according to one of the preceding claims and / or for carrying out the method, as described above.

Further features, advantages and effects of the invention will become apparent from the following description of a preferred embodiment of the invention and the accompanying figures. Showing:

Figure 1 is a schematic structure of a hybrid transmission as an embodiment of the invention;

FIGS. 2 to 12 different operating states with the torque path of the hybrid transmission shown in FIG. 1.

1 shows a schematic representation of a vehicle 1 with a hybrid transmission 2 as an embodiment of the invention. The vehicle 1 or the hybrid transmission 2 has an internal combustion engine 3 and an electric motor 4 as traction motors. The electric motor 4 can also be used as a generator. The hybrid transmission 2 forms a drive train, which passes the driving torques of the internal combustion engine 3 and / or the electric motor 4 to driven wheels 5 of the vehicle 1. In this case, the distribution of the drive torques via a differential device 6 take place.

The hybrid transmission 2 has a first input shaft 7, which is operatively connected to the internal combustion engine 3. The first input shaft 7 is permanently and preferably inseparably coupled to the internal combustion engine 3. Optionally, damper, deflection gear, etc. may be arranged between the first input shaft 7 and the internal combustion engine 3.

The hybrid transmission 2 further comprises a second input shaft 8, wherein the second input shaft 8 is operatively connected to the electric motor 4. Preferably, the second input shaft 8 is non-rotatably coupled to a rotor shaft, not shown, of the electric motor 4.

The first input shaft 7 and the second input shaft 8 are coaxial and arranged side by side in alignment with each other.

The hybrid transmission 2 has an output shaft 9, which is parallel to the first and the second input shaft 7, 8, but offset from this, is arranged. The output shaft 9 forms an input to the differential device 6.

The hybrid transmission 2 has an S1 section, an S2 section and an SS section, which are arranged side by side in the axial direction to the shafts. In the S1 section, an S1-switching device S1 (denoted by S1) and a S1-Doppelgetriebestufe 10 are arranged. The S1 dual-gear stage has a first S1 gear stage 11 and a second S1 gear stage 12. The first S1-gear stage 11 has a fixed gear 11.1, which is arranged on the first input shaft 7, and a loose wheel 11.2, which is arranged on the output shaft 9 and which meshes with the fixed gear 11.1.

The second S1 gear stage 12 has a fixed gear 12.1, which is arranged on the first Eingangsswelie 7, and a S1 gear wheel portion 12.2, which forms part of a double gear 13, wherein the double gear 13 is rotatably mounted on the Ausgangswelie 9. The S1-gear portion 12.2 meshes with the fixed gear 12.1. The S1 switching device is arranged on the output shaft 9 and designed, for example, as a sliding sleeve device. The 51-switching device makes it possible, either in a switch position A, the idler gear 11.2 of the first S1 gear stage 11 or in a show position B, the double gear 13 with the output shaft 9 rotatably set. In addition, the S1 switch can assume a neutral line pitch.

The double gear 13 thus forms with the S1 gear portion 12.2 part of the second S1 gear stage.

In the S2 section, an S2 gear 14 and an S2 switching device (denoted S2) are arranged. The S2 gear stage 14 has a loose wheel 14.1, which is rotatably arranged on the second input shaft 8. Furthermore, the S2 gear stage 14 has an S2 gear portion 14.2, which forms part of the double gear 13 and thus rotatably coupled to the S1-gear portion 12.2. The S2-switching device is disposed on the second input shaft 8 and formed analogous to the S1-switching device, so reference is made to the relevant description. The switching device S2 can set in a Schaltsteliung C, the first input shaft 7 and the second input shaft 8 with each other rotationally fixed. In a Schaltsteliung D, the S2-switching device, the idler gear 14.1 with the second input shaft 8 rotatably set. Furthermore, the S2-switching device can assume a neutral position.

The S3 section has an S3 dual-gear stage 15 with a first SS gear stage 16 and with a second S3 gear stage 17. Further, the S3 section has an S3 switching device (labeled S3) disposed on the output shaft 9. The formation of the S3 switching device can be realized as described above for the S1 switching device. The first SS gear 16 has a fixed gear 16.1, which is arranged on the second input shaft 8. Furthermore, the first S3-gear stage 16, a loose wheel 16.2, which is rotatably mounted on the output shaft 9. The idler gear 16.2 meshes with the fixed gear 16.1. The second S3 gear stage 17 has a fixed gear 17.1, soft arranged on the second input shaft 8 and a loose wheel 17.2, which is rotatably mounted on the output shaft 9 and meshes with the fixed gear 17.1.

In a switching position E of the S3 switching device, the idler gear 16.2 of the first SS gear stage is rotatably coupled to the output shaft 9. In a shift position F, the idler gear 17.2 of the second S3 gear stage 17 is rotatably coupled to the output shaft 9. In addition, it is possible that the S3 switching device assumes a neutral position.

The different operating states of the hybrid transmission 2 will be explained with reference to the following figures. As a summary of the operating conditions, reference is made to the table in the preceding description of the invention.

Gear 1

2 shows the hybrid transmission 2 in the operating state gear 1, wherein the S1-switching device is switched neutral, the S2-Scharteinrichtung is switched in the switching division D and the S3-switching device is switched in the switching position E. The torque path M1 of the internal combustion engine 3 passes through the first input shaft 7, the fixed gear 12.1 of the second S1 gear 12, via the double gear 13, via the second input shaft 8, via the idler gear 14.1 rotatably coupled via the S2-Schatteinrichtung to the first S3 From there, the torque path M1 extends via the first S3 gear stage 16 to the output shaft 9. The torque path M2 from the electric motor 4 passes via the second input shaft 8 to the first S3 gear stage 16 and subsequently to the output shaft 9.

Aisle 2

FIG. 3 shows the operating state gear 2, wherein the S1 shifting device is in the switching state A, the S2 shifting device is in a neutral state and the S3 shifting device is in the switching position E. Of the Momentenpfad MI of the internal combustion engine 3 via the first input world 7, the first S1 gear stage 1 1 to the output shaft 9. The second torque path M2 from the electric motor 4 via the second input world 8 and subsequently via the first S3 ~ gear stage 16 to the output shaft 9

Gear 3

FIG. 4 shows the service hitch gear 3 of the hybrid transmission 2, wherein the shift device S1 is in a neutral position, the shifter S2 is in the shift position C, so that the first and second input shafts 7, 8 are coupled to each other in a rotationally fixed manner and the SS -SchalteinriGhtung in the switching position E is. The torque path MI from the internal combustion engine 3 passes via the first input shaft 7, the second input shaft 8 and subsequently via the first SS gear stage 16 to the output line 9. The second furniture path M2 from the electric motor 4 extends via the second input shaft 8, the first SS Gear 16 to the output shaft. 9

Gear 4 / Alternative 1

In the figure 5 is the Betriebszu stand gear 4 / Äiternative 1 is shown; In this operating state, the Si-switching device is in the switching position B, the S2-Sehalteinriehtung in a Neuiralstellung and the S3-switching device in the switching position E. The first torque path MI extends from the internal combustion engine 3 via the first input world 7 to the second Sl - gear stage 12 and then to the output line 9. The second torque path M2 extends from the electric motor 4 via the second connection shaft 8, the first SS gear stage 16 to the output line 9,

Operating condition gear 4 / AStemative 2

FIG. 6 shows the operating state aisle 4 / external element 2, the S1 switching device being in the switching position B, the S2 switching device being in neutral pitch, and the S3 being in the switching position F. The first Mömentenpfad MI is identical to the alternative 1, on the other hand runs the second Momentenpfad M2 of the electric motor 4 via the second input shaft 8 to the second S3-gear stage 17 and then to the output shaft. 9

Operating condition gear 5

In the figure 7, the operating state is shown gear 5, wherein the S1 -Schalteinrichtung is in neutral position, the S2-switching device in the switching division C and the SS-switching device in the switching position F is. The first torque path M1 now extends from the internal combustion engine 3 via the first input shaft 7 to the second input shaft 8 and from there via the second S3 gear 17 to the output shaft 9. The second torque path M2, however, runs from the electric motor 4 via the second input shaft 8, the second S3 gear stage 17 to the output shaft. 9

Operating condition gear 6

In the figure 8 the operating state gear 6 is shown. In this case, the S1 Schaiteinrichtung in the neutral position, the S2 switching device in the switching position D and the S3 switching device in the switching position F. The first torque path M1 extends from the internal combustion engine 3 via the first input shaft 7, the second S1 gear 12 in the double gearwheel 13 and from there into the S2 gearbox 14, is transmitted from there to the second input shaft 8 and then runs via second S3 gear stage 17 to Ausgangsweile 9. The second torque path M2 extends from the electric motor 4 via the second input shaft 8 the second S3 gear stage 17 and then to the output shaft. 9

In the operating states described so far, the vehicle 1 can be operated as a hybrid vehicle or exclusively with the internal combustion engine.

Operating status 1 / EM

FIG. 9 shows the operating state 1 / EM. In this operating state, the vehicle 1 is operated exclusively by an electric motor. In this operating state, the S1-switching device is in neutral position, the S2- Switching device also in neutral position and the S3-switching device in the switching position E. The internal combustion engine 3 is decoupled, so that no first torque path M1 results. The second torque path M2 extends from the electric motor 4 via the first input shaft 7 to the first S3 transmission stage 16 and then to the output shaft 9. This operating state is used in particular for starting the vehicle 1, since the hybrid transmission 1 has no frictional elements that drive an internal combustion engine would allow.

Operating condition 2 / EM

FIG. 10 shows the operating state gear 2 / EM, which is a pure electromotive state. In this operating state, the S1-switching device and the S2-switching device are both in neutral position. By contrast, the SS switching device is in the switching position F. As before, there is again no first torque path M1. The second torque path M2 extends from the electric motor 4 to the second input shaft 8, via the second S3 gear stage 17 to the output shaft. 9

Operating status R

FIG. 11 shows the operating state R (reverse gear), but this is identical to the operating state 1, with the difference that the electric motor 4 is operated in the opposite direction. Thus, reference is made to the preceding description.

Operating state generator

In the figure 12, finally, the operating state generator is shown. In this operating state, the S1 switching device and the S3 switching device are each in the neutral position. The S2-switching device is located in the switching division C, so that the first and the second input shaft 7, 8 are rotatably coupled together. In this state, the internal combustion engine 3 can directly drive the electric motor 4, so that it can act as a generator and, for example, can charge a storage device. As shown, a six-speed drive with coupled internal combustion engine is possible by the transmission structure, so that a comfortable Gangwahi can be taken at any time. The electric motor 4 supports in changing the operating state or states. There are also several purely electromotive operating states possible, the internal combustion engine then also intervene supportingly when changing the operating state.

LIST OF REFERENCES

1 vehicle

2 hybrid transmissions

3 internal combustion engine

4 electric motor

5 wheels

6 differential device

7 first input shaft

8 second entrance

9 output shaft

10 double gear stage

11 first S1 gear stage

11.1 fixed wheel

11.2 idler gear

12 second S1 gear stage

12.1 fixed wheel

12.2 gear section

13 double gear

14 S2 gear stage

14.1 idler gear

14.2 gear section

15 double gearbox

16 first S3 gear stage

16.1 fixed wheel

16.2 idler gear

17 second S3 gear stage

17.1 fixed wheel

17.2 idler gear

A switching state

B switching state

Claims

Patent claims

1. Hybrid transmission (2) for a vehicle (1) with a first input shaft (7) for coupling to an internal combustion engine (39, with a second input shaft (8) for coupling to an electric motor (4), the first and second input shafts (7,8) are aligned coaxially with one another, with an output shaft (9), the output shaft (9) being arranged parallel to the first and/or second input shaft (7,8), with an S1 double gear stage (10) and with an S1 switching device, wherein the S1 double gear stage (10) has a first and a second S1 gear stage (1 1, 12) and wherein the S1 switching device selectively switches the first input mode (7) via the first S1 gear stage (11) or the first input shaft (7) can be connected via the second S1 gear stage (12) to the output shaft (9) in terms of transmission technology, with an S2 gear stage (14) and with an S2 switching device, the S2 switching device optionally controlling the second input shaft (8) can be connected to the S2 gear stage (14) or the second input shaft (8) to the first input shaft (7) in terms of transmission technology, with an S3 dual gear stage (15) and with an S3 switching device, the S3 dual gear stage ( 15) has a first and a second S3 gear stage (16, 17) and wherein the S3 switching device optionally the second input time (8) via the first S3 gear stage (16) or the second input time (8) via the second S3 Gear stage (17) can be connected to the output shaft (9) in terms of transmission technology, with a double gear (13) with an S1 gear section (12.2) and an S2 gear section (14.2), the S1 gear section (12.2) being part of the S1 - Double gear stage (10) and the S2 gear section (14.2) forms part of the S2 gear stage (14).

2. Hybrid transmission (2) according to claim 1, characterized in that the double gear (13) is designed as an idler gear on the output shaft (9).

3. Hybrid transmission (2) according to one of the preceding claims, characterized in that the S1 switching device is arranged on the output shaft (9) and can set the double gear (13) with the output shaft (9) in a rotationally fixed manner to the first input shaft (7 ) to be connected via the second S1 gear stage (12) to the output shaft (9) in terms of transmission technology, or an idler gear (11.2) of the first S1 gear stage can be set in a rotationally fixed manner with the output shaft (9) in order to connect the first input shaft (7) via the to connect the first S1 gear stage (1 1) to the output shaft (9) in terms of transmission technology.

4. Hybrid transmission (2) according to one of the preceding claims, characterized in that the S2 switching device is arranged on the second input shaft (8) and can set an idler gear (14.1) of the S2 transmission stage in a rotationally fixed manner with the second input shaft (8), whereby the idler gear (14.1) meshes with the S2 gear section (14.2).

5. Hybrid transmission (2) according to one of the preceding claims, characterized in that the S3 switching device is arranged on the output shaft (9) and can optionally set an idler gear (16.2) of the first S3 transmission stage (16) in a rotationally fixed manner to the second The input shaft (8) can be connected to the output shaft (9) via the first S3 gear stage (16) in terms of transmission technology, or an idler gear (17.2) of the second S3 gear stage (17) can be set in a rotationally fixed manner with the output shaft (9) in order to ensure the second Input shaft (8) to be connected to the output shaft (9) via the second S3 transmission stage (17) in terms of transmission technology.

6. Hybrid transmission (2) according to one of the preceding claims, characterized in that the S1 switching device, the S2 switching device and / or the S3 switching devices are designed as unsynchronizing switching devices, in particular screw sleeve devices.

7. Hybrid transmission (2) according to one of the previous claims, characterized in that the hybrid transmission can have one, some or all of the following operating states:

8. A method for operating the hybrid transmission (2) according to one of the preceding claims, characterized in that the operating state is changed by changing the switching position of the S1 switching device, the S2 switching device and / or the S3 switching device.

9. The method according to claim 8, characterized in that when the operating state changes, the electric motor (4) and the internal combustion engine (3) are controlled so that the change is implemented without interruption in traction.

10. Vehicle (1), characterized by a hybrid transmission (2) according to one of the preceding claims.