An MG1 torque at a time of decreasing an engine speed of an engine is made larger when a turbocharging pressure by a turbocharger is higher than when the turbocharging pressure is lower. In this way, even if the losses of pumps of the engine differ due to the remaining turbocharging pressure during a transition of stopping the engine in turbocharging, it is possible to appropriately reduce the engine speed. Therefore, when the engine is being brought to a stop, it is possible to appropriately suppress vibration generated in the vehicle.

An MG1 torque at a time of decreasing an engine speed of an engine is made larger when a turbocharging pressure by a turbocharger is higher than when the turbocharging pressure is lower. In this way, even if the losses of pumps of the engine differ due to the remaining turbocharging pressure during a transition of stopping the engine in turbocharging, it is possible to appropriately reduce the engine speed. Therefore, when the engine is being brought to a stop, it is possible to appropriately suppress vibration generated in the vehicle.

A drive unit (100) is provided with a first electric machine (110), a second electric machine (120), a first shaft (130) and an output shaft (140). A rotor (111) of the first electric machine (110) is rotationally fixed to the first shaft (130), and a rotor (121) of the second electric machine (120) is rotationally fixed to the output shaft (140). The drive unit (100) also includes a separating clutch (150) and a connection element (230) for the rotationally fixed connecting of an internal combustion engine, and a first gear ratio step (142) is arranged between the connection element (230) and the shafts (130, 140) with a gear ration i<1. The drive unit (100) has an electro-mechanical parking lock unit (1) with which a rotational movement of the output of the first gear ratio step (142) can be blocked.

A drive unit (100) is provided with a first electric machine (110), a second electric machine (120), a first shaft (130) and an output shaft (140). A rotor (111) of the first electric machine (110) is rotationally fixed to the first shaft (130), and a rotor (121) of the second electric machine (120) is rotationally fixed to the output shaft (140). The drive unit (100) also includes a separating clutch (150) and a connection element (230) for the rotationally fixed connecting of an internal combustion engine, and a first gear ratio step (142) is arranged between the connection element (230) and the shafts (130, 140) with a gear ration i<1. The drive unit (100) has an electro-mechanical parking lock unit (1) with which a rotational movement of the output of the first gear ratio step (142) can be blocked.

A propulsion assembly includes an assembly output shaft adapted to drive one or more power receiving devices, a first output driving shaft which is adapted to drive the assembly output shaft, and a second output driving shaft which is adapted to drive the assembly output shaft. The first output driving shaft extends in an angle to the assembly output shaft which is larger than zero degrees and smaller than 180 degrees. The propulsion assembly further includes a first input shaft adapted to drive the first output driving shaft and adapted to be driven by a first power supply unit, wherein the first input shaft extends in an angle to the first output driving shaft which is larger than zero degrees and smaller than 180 degrees, and a second input shaft adapted to drive the first output driving shaft and adapted to be driven by a second power supply unit. The second input shaft extends in an angle to the first output driving shaft which is larger than zero degrees and smaller than 180 degrees. The second output driving shaft is adapted to be driven by a third power supply unit, wherein the second output driving shaft extends in an angle to the assembly output shaft which is larger than zero degrees and smaller than 180 degrees.

A propulsion assembly includes an assembly output shaft adapted to drive one or more power receiving devices, a first output driving shaft which is adapted to drive the assembly output shaft, and a second output driving shaft which is adapted to drive the assembly output shaft. The first output driving shaft extends in an angle to the assembly output shaft which is larger than zero degrees and smaller than 180 degrees. The propulsion assembly further includes a first input shaft adapted to drive the first output driving shaft and adapted to be driven by a first power supply unit, wherein the first input shaft extends in an angle to the first output driving shaft which is larger than zero degrees and smaller than 180 degrees, and a second input shaft adapted to drive the first output driving shaft and adapted to be driven by a second power supply unit. The second input shaft extends in an angle to the first output driving shaft which is larger than zero degrees and smaller than 180 degrees. The second output driving shaft is adapted to be driven by a third power supply unit, wherein the second output driving shaft extends in an angle to the assembly output shaft which is larger than zero degrees and smaller than 180 degrees.

A transmission for a hybrid drive assembly includes an input shaft, an output shaft, a first transmission shaft, a second transmission shaft, a third transmission shaft, first, second, and third shift elements, a first spur gear set, a second spur gear set, and a third spur gear set. The input shaft can be coupled to the first transmission shaft by the first shift element, the first transmission shaft is coupled to the first spur gear set, the first spur gear set can be coupled to the second transmission shaft by the second shift element, the second transmission shaft is coupled to the second spur gear set, and the second spur gear set is coupled to the third transmission shaft. The third transmission shaft is coupled to the third spur gear set and the third spur gear set can be coupled to the output shaft by the third shift element.

A transmission for a hybrid drive assembly includes an input shaft, an output shaft, a first transmission shaft, a second transmission shaft, a third transmission shaft, first, second, and third shift elements, a first spur gear set, a second spur gear set, and a third spur gear set. The input shaft can be coupled to the first transmission shaft by the first shift element, the first transmission shaft is coupled to the first spur gear set, the first spur gear set can be coupled to the second transmission shaft by the second shift element, the second transmission shaft is coupled to the second spur gear set, and the second spur gear set is coupled to the third transmission shaft. The third transmission shaft is coupled to the third spur gear set and the third spur gear set can be coupled to the output shaft by the third shift element.

A hybrid transmission arrangement for a motor vehicle (30) includes a first transmission group (12), a second transmission group (18), a third planetary gear set (PS3), and a first electric machine (EM1). The first transmission group (12) includes a first input (14), a first output (16), and a first planetary gear set (PS1). The first input (14) is connectable to an internal combustion engine (VM). The second transmission group (18) includes a second input (20), a second output (22), and a second planetary gear set (PS2). The second input (20) is connected to the first output (16) of the first transmission group (12). The third planetary gear set (PS3) includes a first element (S3;H3.sup.I), a second element (H3;S3.sup.I), and a third element (P3;P3.sup.I). The third planetary gear set (PS3) is interlockable using a first shift element (E) and arranged coaxially to a first axis (A1). The first element (S3;H3.sup.I) is connected to the first electric machine. The second element (H3;S3.sup.I) is connected to the second output (22). The third element (P3;P3.sup.I) is connected to a drive output (Ab) of the hybrid transmission arrangement (10).

A hybrid drive system has an internal combustion engine having a crankshaft, an electric motor having a rotor and a stator, a dual clutch transmission having an input shaft, a dual claw clutch having a first claw clutch and a second claw clutch, a first sub-transmission, and a second sub-transmission. The first claw clutch is non-rotatably connects a first sub-transmission input shaft of the first sub-transmission to the input shaft. The second claw clutch non-rotatably connects a second sub-transmission input shaft of the second sub-transmission to the input shaft. The rotor is arranged in such a way that torques starting from the rotor on an output side of the second claw clutch can be introduced into the dual clutch transmission via the second sub-transmission input shaft.