A multipurpose vehicle includes a stepless speed changer which is provided at one of lateral sides of a vehicle body with respect to an engine and a traveling transmission, an engine output shaft projected from the engine toward the stepless speed changer along a lateral direction of the vehicle body, a speed changer input shaft projected from the stepless speed changer toward the engine along the lateral direction of the vehicle body, and a first gear transmission mechanism provided between and across the engine output shaft and the speed changer input shaft and transmitting power of the engine output shaft to the speed changer input shaft. The multipurpose vehicle further has a PTO section provided at the side of the stepless speed changer with respect to the engine and forwardly of the stepless speed changer, the PTO section being operably connected to the engine output shaft via a second gear transmission mechanism.

A powertrain for a vehicle includes a housing, a motor generator unit, a torque converter, a first and second shafts, a first and second gear sets, and a torque transmitting mechanism. The motor generator unit includes an output member. The torque converter includes a pump and a turbine. The pump is connected for common rotation with the output member of the motor generator unit. The first shaft rotatably is supported by the powertrain housing and is connected for common rotation with the turbine of the torque converter. The second shaft is rotatably supported by the powertrain housing and disposed parallel to the first shaft. An output gear is connected for common rotation to the second shaft.

A vehicle includes a heat exchanger, a transmission, and a controller. The transmission is configured to transfer power within a powertrain. The transmission has a primary fluid circuit, a secondary fluid circuit, and a valve. The secondary fluid circuit is configured to divert the fluid from the primary fluid circuit and deliver the fluid to the heat exchanger. The valve is configured to control diverting fluid from the primary fluid circuit to the secondary fluid circuit. The controller is programmed to, in response to a temperature of the fluid being outside of a desired range, open the valve to direct the fluid toward the heat exchanger via the secondary fluid circuit. The controller is further programmed to, in response to the temperature of the fluid being within the desired range, close the valve to isolate the fluid from the secondary fluid circuit and the heat exchanger.

An electric drivetrain including an electric machine and at least one output pinion intended to be connected to an axle differential, and at least one speed reduction device including a first gear train and a second gear train intended to drive the output pinion in rotation in a first rotational direction or a second rotational direction.

A drive unit for driving a drive wheel is disclosed. The drive unit includes a motor, a torque converter and a power output part. The torque converter is a component to which a power is inputted from the motor. The power output part outputs the power, inputted thereto from the torque converter, to the drive wheel. The power output part includes a first gear train and a second gear train. The first gear train outputs the power, inputted to the power output part from the torque converter, in a first rotational direction. The second gear train outputs the power, inputted to the power output part from the torque converter, in a second rotational direction reverse to the first rotational direction.

A drive unit for driving a drive wheel is disclosed. The drive unit includes a motor, a torque converter and a power output part. The torque converter is a component to which a power is inputted from the motor. The power output part outputs the power, inputted thereto from the torque converter, to the drive wheel. The power output part includes a first gear train and a second gear train. The first gear train outputs the power, inputted to the power output part from the torque converter, in a first rotational direction. The second gear train outputs the power, inputted to the power output part from the torque converter, in a second rotational direction reverse to the first rotational direction.

An automatic transmission assembly includes a torque converter drivably engaged with a transmission. The torque converter has an impeller with a hub. The hub has an exterior surface, a hub end face, and a first chamfered edge between the exterior surface and the hub end face. A gear has an axial opening, a gear end face, and a second chamfered edge between the axial opening and the gear end face. First and second extensions extend from the second chamfered edge. The first and second extensions extend in a direction normal to the second chamfered edge. During indexing of the torque converter, the first and second extensions contact the first chamfered edge.

An automatic transmission assembly includes a torque converter drivably engaged with a transmission. The torque converter has an impeller with a hub. The hub has an exterior surface, a hub end face, and a first chamfered edge between the exterior surface and the hub end face. A gear has an axial opening, a gear end face, and a second chamfered edge between the axial opening and the gear end face. First and second extensions extend from the second chamfered edge. The first and second extensions extend in a direction normal to the second chamfered edge. During indexing of the torque converter, the first and second extensions contact the first chamfered edge.

An object of the present invention is to provide a continuously variable transmission in which a magnitude relationship between a piston area of a primary pulley and a piston area of a secondary pulley is specified. As means for achieving the object, a continuously variable transmission includes: an electric oil pump disposed in an oil path between a piston oil chamber of a primary pulley and a piston oil chamber of a secondary pulley; and a controlling portion configured to control the entry and exit of oil in the piston oil chamber of the primary pulley by the electric oil pump. A piston area of the primary pulley in the continuously variable transmission is smaller than a piston area of the secondary pulley.

A hydrodynamic lock-based CVT gearbox is disclosed. The apparatus is configured to continuously convert input rpm into different rpm's without interrupting a gearbox connection with an engine using a suspended and single-speed gearbox, and clockwise and counterclockwise rotation control of hydrodynamic lock. The apparatus is configured to utilize parallel paths pattern for power transfer, which includes a first power path and a second power path parallel to the first power path. The first power path is configured to reduce rotation and increase torque. The second power path is configured to provide equal rotation of the input and output axes. The apparatus is further configured to transfer the power from the first power path to the second power path by disposing a limiter at the first power path. At the end, the rotational force of the paths is combined and transmitted to the output of the gearbox.