A starting protector for an all-terrain vehicle is provided and includes a shaft, a driven wheel fitted over the shaft and comprising a tooth portion, a sleeving portion and a locking portion, and the tooth portion being configured to be connected with an engine; a driving wheel fitted over the sleeving portion, one side of the driving wheel being attached to the tooth portion, and the driving wheel being configured to be connected with a starting motor; a friction piece fitted over the sleeving portion and being in synchronous rotation with the sleeving portion, the friction piece being attached to the other side of the driving wheel, and when starting torque of the engine exceeds a preset value, the driving wheel and the friction piece slipping relatively; and a compressing assembly fitted over the sleeving portion and the locking portion to compress the friction piece and the driving wheel.

Gear unit with an integral differential arranged between an input shaft and two output shafts, having a first and a second planetary gearset with gearset elements. One gearset element is connected to an epicyclic gear train input, an output of the epicyclic gear train and a stationary component of the gear unit. A first gearset element is connected to the input shaft, a second gearset element is connected to the first output shaft, and a third gearset element is connected to a first gearset element of the second planetary gearset. A second gearset element is connectible to a second gearset element of the epicyclic gear train. A third gearset element is connected to the second output shaft. A first gearset element of the epicyclic gear train is connected to the input shaft. A third gearset element of the epicyclic gear train is connected to the stationary structural component.

An electric powertrain for a working machine, including: a first electric machine, a second electric machine, a propulsion axle for propulsion of the working machine, a transmission assembly comprising: a first input shaft drivingly connected to the first electric machine, a second input shaft drivingly connected to the second electric machine, a first output shaft drivingly connected to the propulsion axle, the first and the second input shafts being selectively drivingly connectable to the first output shaft, at least one second output shaft for power take-off, to which the second input shaft is drivingly connected, a set of gears including at least two selectable gear ratios for transfer of torque,

wherein at least the first input shaft is drivingly connectable to the first output shaft via the set of gears.

An electric motor-clutch assembly is described, wherein the electric motor comprises a rotor comprising a free surface which forms part of the external surface of the motor, the clutch comprises a friction disc and the friction disc is mounted axially movable to selectively contact said free surface.

A hybrid vehicle powertrain includes an internal combustion engine, an electric traction motor and a transmission. A first flexible coupling drivingly connects the internal combustion engine to the transmission, and a second flexible coupling drivingly connects the electric traction motor to the transmission.

The present invention relates to a method with which the driving dynamics of an electrically driven vehicle can be modified. Within the scope of the method according to the invention, a vehicle operating characteristic variable, as a function of which a torque transmission mechanism is engaged, is monitored, by means of which torque transmission mechanism two half-shaft assemblies of the vehicle which are each driven by an electric motor can be selectively connected to one another in terms of drive.

A powertrain for an electric vehicle, may include: an input shaft and an output shaft mounted in parallel to each other; first and second power transmission mechanisms provided to transmit power from the input shaft to the output shaft at two gear ratios different from each other; a one-way clutch included in the first power transmission mechanism; a friction clutch included in the second power transmission mechanism; and a bypass mechanism provided to form a power transmission path that bypasses the one-way clutch and a power transmission path that bypasses the friction clutch.

A starting protector for an all-terrain vehicle is provided and includes a shaft, a driven wheel fitted over the shaft and comprising a tooth portion, a sleeving portion and a locking portion, and the tooth portion being configured to be connected with an engine; a driving wheel fitted over the sleeving portion, one side of the driving wheel being attached to the tooth portion, and the driving wheel being configured to be connected with a starting motor; a friction piece fitted over the sleeving portion and being in synchronous rotation with the sleeving portion, the friction piece being attached to the other side of the driving wheel, and when starting torque of the engine exceeds a preset value, the driving wheel and the friction piece slipping relatively; and a compressing assembly fitted over the sleeving portion and the locking portion to compress the friction piece and the driving wheel.

Gear unit with an integral differential arranged between an input shaft and two output shafts, having a first and a second planetary gearset with gearset elements. One gearset element is connected to an epicyclic gear train input, an output of the epicyclic gear train and a stationary component of the gear unit. A first gearset element is connected to the input shaft, a second gearset element is connected to the first output shaft, and a third gearset element is connected to a first gearset element of the second planetary gearset. A second gearset element is connectible to a second gearset element of the epicyclic gear train. A third gearset element is connected to the second output shaft. A first gearset element of the epicyclic gear train is connected to the input shaft. A third gearset element of the epicyclic gear train is connected to the stationary structural component.

Apparatuses, methods, and systems comprising vehicle fleet management systems are disclosed. One embodiment is a method that provides a plurality of predetermined powertrain trim templates, where each of the plurality of predetermined powertrain trim templates specifies a plurality of powertrain trim parameters implementable by an electronic powertrain control system to control one or more operational response characteristics of the powertrain. The method includes selecting one of the plurality of predetermined powertrain trim templates and one of a plurality of vehicles of a vehicle fleet to receive the selected one of the plurality of predetermined powertrain trim templates. In response to the act of selecting one of the plurality of predetermined powertrain trim templates, the method transmits via a telematics network one or more modified powertrain trim parameters. Further, the method receives the modified powertrain trim parameters with a telematics system of the selected one of the plurality of vehicles of the vehicle fleet. Also, the method applies the modified trim parameters with the electronic powertrain control system to control the one or more operational response characteristics of the powertrain.