A rotating machine and a pinion shaft are separately arranged on opposite sides to each other in the vehicle front-rear direction across a third axis that is an axis of a differential device in plan view as seen from above the vehicle. This configuration enables the rotating machine, a parallel shaft transmission, the pinion shaft, the differential device, and others to be integrally assembled to a case, to thereby configure an electric drive unit to be compact, which is advantageous in space.

A final drive assembly for a vehicle drive axle having first and second axle-shafts that are configured to rotate about a common first axis. The final drive assembly includes a first gear-set configured to be operatively connected to the first axle-shaft. The final drive assembly also includes a second gear-set configured to be operatively connected to the second axle-shaft. The final drive assembly additionally includes an electric motor configured to provide an electric motor torque input to each of the first and second gear-sets and arranged on a second axis that is parallel to the first axis.

A vehicle behavior control device is provided in a vehicle that includes a suspension device supporting a wheel so as to allow a stroke with respect to a vehicle body, and having a geometry in which a center of the wheel is displaced in a direction in which a wheelbase stretches and contracts due to the stroke, and a front and rear wheel differential rotation constraining member that constrain differential rotation between a front wheel driving force transmission mechanism that transmit a driving force to front wheels and a rear wheel driving force transmission mechanism that transmit a driving force to rear wheels. The vehicle behavior control device includes a front and rear wheel differential rotation constraining control unit that increase a constraining force of the front and rear wheel differential rotation constraining member in response to occurrence of a pitching behavior of the vehicle body.

A gear box having a gear set therein for mounting to the outside of a housing of an axle assembly and connected to the input shaft of the differential of the axle assembly can allow high speed electric motor(s) to connect to the differential via the gear box for driving the axle assembly. The gear box can be mounted using existing bolt hole pattern on the axle assembly housing such as the input cover of the axle head assembly housing the differential. The gear set can be a planetary gear set where the rotor of the electric motor can be rotationally connected to the sun gear and the carrier gear can be connected to the input pinion shaft. In another embodiment an axle assembly having a differential can also have a gear box mounted to the outside of the axle housing and connected to the input pinion shaft to allow use of a high speed electric motor by providing an appropriate gear ratio conversion.

A control system for a hybrid vehicle configured to start an engine promptly during propulsion in an electric vehicle mode. Electric power generation resulting from cranking the engine by a first motor is greater in the first electric vehicle mode compared to a second electric vehicle mode. A controller that is configured to determines whether an acceptable input power to an electric storage unit is smaller than a threshold value. If the acceptable input power to the electric storage unit is smaller than the threshold value, selection of the first electric vehicle mode is inhibited.

A final drive assembly for a vehicle drive axle having first and second axle-shafts that are configured to rotate about a common first axis. The final drive assembly includes a first gear-set configured to be operatively connected to the first axle-shaft. The final drive assembly also includes a second gear-set configured to be operatively connected to the second axle-shaft. The final drive assembly additionally includes an electric motor configured to provide an electric motor torque input to each of the first and second gear-sets and arranged on a second axis that is parallel to the first axis.

The present disclosure discloses a power-drive system for a vehicle and a vehicle. The power-drive system comprises: an engine; a plurality of input shafts; a plurality of output shafts; a first clutch device, arranged between the engine and the plurality of input shafts, so that the engine selectively engages with at least one of the plurality of input shafts; a motor power shaft, a motor power shaft first gear linking with a gear-position driving gear in the same direction being freely sleeved on the motor power shaft, and the plurality of output shafts and the motor power shaft linking with a differential of the vehicle; a first motor generator, configured to link with the motor power shaft; and a second motor generator, wherein the second motor generator and the engine are located on an input side of the first clutch device, the plurality of input shafts is located on an output side of the first clutch device, and the second motor generator is configured to carry out stationary power generation using at least part of power of the engine when the vehicle is parked.

A motor module for modularly making a front and/or rear electric axle, comprising an electric motor generator and a gear train enclosed in a gearbox case permanently fixed to a stator of said electric motor-generator, the module having an L-shape. Electric axle comprising a pair of L-shaped modules for making a T-shaped front electric axle and a U-shaped rear electric axle.

A vehicle drive assembly with transverse dual-power-source, comprising two power sources and an automatic transmission. The automatic transmission has a first input shaft and a second input shaft, and the two power sources are respectively connected to the two input shafts; a first intermediate shaft is provided parallel to the first input shaft, a second intermediate shaft is provided coaxial with the first input shaft, a third intermediate shaft is provided coaxial with the first intermediate shaft, and a first gear and a second gear on the first intermediate shaft are in engaged transmission; a third gear shaft and a fourth gear on the second intermediate shaft are in engaged transmission; and a fifth gear and a sixth gear on the third intermediate shaft are in engaged transmission, and the sixth gear is simultaneously in engaged transmission with a seventh gear on a differential.

A driving system includes a drive source for driving a left drive portion and a right drive portion, a power transmission mechanism having first and second differential mechanisms each including a first rotating element, a second rotating element and a third rotating element and a switching unit. The first rotating elements of the first and second differential mechanisms are connected to each other so as to rotate in the same direction, the second rotating elements of the first and second differential elements are connected to the left drive portion and the right drive portion, respectively, and the third rotating elements of the first and second differential mechanisms are connected to each other so as to rotate in opposite directions.