A hybrid transmission of a countershaft design for a motor vehicle powertrain having an internal combustion engine, a first electric prime mover, and a second electric prime mover has a transmission drive shaft drivingly connected to the second electric prime mover, a first sub-transmission having a first transmission input shaft, and a second sub-transmission having a second transmission input shaft, the second transmission input shaft being drivingly connected to the first electric prime mover. The transmission further has a first coupling element, the transmission drive shaft being connectable to the internal combustion engine via the first coupling element. Moreover, the transmission has a second coupling element, the first transmission input shaft being connectable to the second transmission input shaft via the second coupling element. Additionally, the transmission has a third coupling element, the transmission drive shaft being connectable to the first transmission input shaft via the third coupling element.

A hybrid transmission device includes at least one drive device (EM2) and a gear change transmission (4) having multiple forward gear steps (G1, G2, G3, G4, GE2). The forward gear steps (G1, G2, G3, G4, GE2) are distributed onto at least one first sub-transmission (36) and one second sub-transmission (38). At least one even forward gear step (G2, G4) and at least one odd forward gear step (G3) are arranged in the first sub-transmission (36).

The present invention provides a power split hybrid power system and a hybrid vehicle. The hybrid power system comprises two planetary gear mechanisms sharing planetary carriers and ring gears, two motors and one engine. An output shaft of the engine is in transmission connection with a first sun gear shaft of a first sun gear, an input/output shaft of a first motor is in transmission connection with a second sun gear shaft of a second sun gear, and an input/output shaft of a second motor is in transmission connection with the ring gears. The output shaft of the engine, the input/output shaft of the first motor and the input/output shaft of the second motor can be relatively fixed to a housing of a transmission through a braking mechanism. Therefore, the power split hybrid power system can guarantee that a vehicle reaches a high speed in a pure motor driving mode so as to complete New European Driving Cycle and World Light Vehicle Test Cycle; and the engine can also be shut down at a high vehicle speed, and the dynamic property is improved in a low-speed state.

The present invention provides a power split hybrid power system and a hybrid vehicle. The hybrid power system comprises two planetary gear mechanisms sharing planetary carriers and ring gears, two motors and one engine. An output shaft of the engine is in transmission connection with a first sun gear shaft of a first sun gear, an input/output shaft of a first motor is in transmission connection with a second sun gear shaft of a second sun gear, and an input/output shaft of a second motor is in transmission connection with the ring gears. The output shaft of the engine, the input/output shaft of the first motor and the input/output shaft of the second motor can be relatively fixed to a housing of a transmission through a braking mechanism. Therefore, the power split hybrid power system can guarantee that a vehicle reaches a high speed in a pure motor driving mode so as to complete New European Driving Cycle and World Light Vehicle Test Cycle; and the engine can also be shut down at a high vehicle speed, and the dynamic property is improved in a low-speed state.

A clutch assembly for a motor vehicle drive train includes a first clutch having a first output element, where the first clutch is a friction-locking clutch. The clutch assembly further includes a second clutch having a second output element, where the second clutch is a form-locking clutch, and where the first clutch and the second clutch have a shared input element. Additionally, the clutch assembly includes a single sliding element associated with the first clutch and the second clutch, the sliding element being movable by a single actuating unit between a first engagement position and a second engagement position axially offset from the first engagement position. The first clutch is engaged when the sliding element is in the first engagement position and the second clutch is engaged when the sliding element is in the second engagement position.

A clutch assembly for a motor vehicle drive train includes a first clutch having a first output element, where the first clutch is a friction-locking clutch. The clutch assembly further includes a second clutch having a second output element, where the second clutch is a form-locking clutch, and where the first clutch and the second clutch have a shared input element. Additionally, the clutch assembly includes a single sliding element associated with the first clutch and the second clutch, the sliding element being movable by a single actuating unit between a first engagement position and a second engagement position axially offset from the first engagement position. The first clutch is engaged when the sliding element is in the first engagement position and the second clutch is engaged when the sliding element is in the second engagement position.

A hybrid transmission device (3) includes a first transmission input shaft (7), a second transmission input shaft (9) mounted on the first transmission input shaft, at least one electric motor (EM1, EM2), and a connecting clutch (K3) is configured for forming a rotationally fixed connection of the first transmission input shaft (7) and the second transmission input shaft (9). The connecting clutch (K3) is configured as part of a two-sided engagement device (S1).

A hybrid power system is provided having a motor, a double clutch, and a transmission with three synchronous meshing mechanisms, the hybrid power system can, through a reasonable structural design, implement the same as or more than the number of gears and operating modes of hybrid power systems employing a single motor and a dedicated hybrid transmission in the prior art, while being simpler in structure, more compact in size, and less costly.

A hybrid power system is provided having a motor, a double clutch, and a transmission with three synchronous meshing mechanisms, the hybrid power system can, through a reasonable structural design, implement the same as or more than the number of gears and operating modes of hybrid power systems employing a single motor and a dedicated hybrid transmission in the prior art, while being simpler in structure, more compact in size, and less costly.

A hybrid transmission arrangement (16) for a motor vehicle drive train (10) includes a first sub-transmission (32) with a first input shaft (24), a second sub-transmission (34) with a second input shaft (26), a first electric machine (56) connectable to the first input shaft (24) via a second clutch (K2), and a second electric machine (60) connected to the second input shaft (26). The first electric machine (56) is connected via a first gearwheel (70) to an intermediate element (74), which forms an input element of the second clutch (K2). The second electric machine (60) is connected to the second input shaft (26) via a second gearwheel (72). The first gearwheel (70) and the second gearwheel (72) are arranged coaxially and adjacent to each other.