A vehicular control system for reducing shocks by inhibiting switching operation of a dog clutch when drive force cannot be assisted by an engine. A controller determines that an increase in the drive force by the engine is restricted. In a case that an increase in the drive force is not restricted when launching the vehicle, the controller establishes a first gear stage in the transmission to launch the vehicle, and shift to the second gear stage upon satisfaction of a predetermined condition during propulsion while increasing the drive force. In a case that an increase in the drive force is restricted when launching the vehicle, the controller establishes a second gear stage in the transmission to launch the vehicle.

There is provided a vehicle power transmission device which transmits power output from an electric motor (driving source) to left and right axles through planetary gear mechanisms and a differential device. In the device in which a parking gear is provided in a carrier of the planetary gear mechanism, the parking gear is supported on the carrier so that it is relatively rotatable, and a dog clutch (contact and release mechanism) for bringing the parking gear and the carrier into contact and disconnecting them is provided.

A hydraulic drive system is provided and generally includes a first rotor assembly arranged along a first side of the frame and having a first rotor and a first drive shaft extending through and connectable with the first rotor, a first motor assembly disposed along the first side of the frame and positioned linearly the first rotor assembly and a second rotor assembly arranged along a second side of the frame that is opposite the first side and having a second rotor and a second drive shaft extending through and connectable with the second rotor.

A gearbox having an input shaft (8) and an output shaft (20); a first epicyclic gear (10) connected to the input shaft (8); a second epicyclic gear (12) connected to the first epicyclic gear (10); a first electrical machine (14) connected to the first epicyclic gear (10); a second electrical machine (16) connected to the second epicyclic gear (12); a first main shaft (34) connected to the first epicyclic gear (10); a second main shaft (36) connected to the second epicyclic gear (12). A first coupling unit (56) disengagingly connects two rotatable components (22, 26, 50) at the first epicyclic gear (10), and a second coupling unit (58) disengagingly connects two rotatable components (28, 32, 51) at the second epicyclic gear (12), such that at least one of the rate of revolution and the torque at the first and the second main shafts (34, 36) can be influenced by controlling at least one of the first and the second coupling units (56, 58) to a condition of the rotatable components (22, 26, 50; 28, 32, 51) that is engaged or disengaged. Also a vehicle (1) having such a gearbox (2), a method to control such a gearbox (2), a computer program (P) to control a gearbox, and a computer program product comprising program code for an electronic control unit (48) or another computer (53) in order to implement the method.

A control system that controls a driveline of a motor vehicle to operate in a selected one of a plurality of configurations is configured to receive a brake signal responsive to the application of a braking system. The control system causes the driveline to operate in a second configuration and not a first configuration in dependence at least in part on the brake signal. In the first configuration a first group of one or more wheels and in addition a second group of one or more wheels are arranged to be driven by the driveline, and in the second configuration the first group of one or more wheels and not the second group are arranged to be driven by the driveline.

An axle assembly having a pair of axle half shafts and an axle housing defining a sump. The axle assembly further includes a first clutch assembly including a first half and a second half, wherein the first half is selectively engaged to the second half. The axle assembly also includes a second clutch assembly disposed adjacent to the first clutch assembly, wherein the second clutch includes a gear and the gear is selectively engaged with the second half of the first clutch assembly. Yet further, the axle assembly includes a lubrication pump mounted in the axle housing and drivingly coupled to the second clutch assembly; a spring mounted between the first half and the second half of the first clutch assembly; and a bearing disposed between the spring and the second half of the first clutch assembly.

Methods and systems are provided for a motorized disconnect operable to selectively engage and disengage two rotating components of a vehicle drivetrain. As one example, a motorized disconnect system is provided that operates via an electric motor and includes a shifter assembly with an oscillating gear track and cam profile for rotating the shifter assembly while moving it in an axial direction to selectively couple two rotating components.

An electric vehicle drive unit includes: first and second traveling motors that include first and second rotors, respectively; and a first planetary gear mechanism that includes first to third rotation element, The first rotation element is rotatably coupled to the first rotor. The second rotation element is rotatably coupled to the second rotor via a connection portion. The third rotation element is coupled to an output shaft coupled to a drive wheel side. Rotary axes in the first planetary gear mechanism, the first traveling motor and the second traveling motor are coaxially arranged. The electric vehicle drive unit further includes a clutch that disconnectably connects any two rotation elements among the first to third rotation elements to switch the two rotation elements to a directly coupled state at the time of connection.

Provided is a clutch that is able to not only transmit torque smoothly even when an input shaft and an output shaft significantly differ in relative speed and phase, but also reduce an energy loss during torque transmission. The clutch (10) includes a dog clutch (40) for transmitting forward or reverse torque from the input shaft (11) to the output shaft (12), and a friction clutch (20) for transmitting torque from the input shaft (11) to the output shaft (12) and disposed in parallel with the dog clutch (40), and selectively transmits or interrupts torque between the input shaft (11) and the output shaft (12).

A disconnecting axle assembly with a planetary differential assembly and a coupling that selectively couples a planet carrier of the planetary differential assembly to an axle shaft.