Drive system for an electric vehicle including a first sub-assembly of electric machines kinematically connected to a first common gear, and a second sub-assembly of electric machines kinematically connected to a second common gear. A first set of gear trains is kinematically connecting the first sub-assembly to a secondary shaft capable of driving the driving wheels of the vehicle, wherein a first selective coupling system is arranged to select a first gear train or a second gear train from a neutral position during a gear change phase. A second sub-assembly kinematically connects the second common gear to the secondary shaft. The second sub-assembly of electric machines is controlled so as to supply additional torque making it possible to compensate for the loss of torque resulting from the uncoupling of the first sub-assembly inherent in the gear change.

A portal axle drive for a vehicle axle of an electric vehicle with driving wheels includes a drive shaft (AN) with an input axis (a) and an output shaft (AB) with an output and wheel axis (b). The input axis (a) and the output axis (b) have an axial or portal offset (c). A first gear stage (Ü1) is arranged between the drive shaft (AN) and the output shaft (AB). In an axial direction, a second gear stage (Ü2) is arranged next to the first gear stage (Ü1) and an engagement device (SE) is arranged next to the second gear stage (Ü2). The first gear stage (Ü1) and the second gear stage (Ü2) are engageable via the engagement device (SE).

A wheel end disconnect assembly includes a housing, a shift ring, a shift fork and an actuator. The shift ring is supported for axial translation relative to the housing between a connected position in which the shift ring couples an input member to a wheel hub for rotation therewith and a disconnected position in which the input member and the wheel hub are rotatable relative to each other. The shift fork includes a first arm portion, a second arm portion, and an input portion extending from a junction of the first and second arm portions. The shift fork is pivotably coupled to the housing at the junction of the first and second arm portions. The actuator is configured to move the input portion to pivot the first and second arm portions such that the first and second arm portions translate the shift ring between the connected and disconnected positions.

During movement of a mass of a centrifugal clutch a radially inner position to a radially outer position and a resulting increase in torque transmitted from an input gear to an output shaft, a power transmission apparatus includes a first torque region where the apparatus restricts operation of a pressing assist cam and a second torque region where the apparatus allows operation of the pressing assist cam.

An apparatus structured to control an electric vehicle accessory of an electric vehicle during a charge event includes a controller communicatively coupled to a battery and an electric vehicle accessory. The controller is structured to determine that the battery of an electric vehicle is undergoing a charge event, and based on determining that the battery of the electric vehicle is undergoing the charge event, place the electric vehicle accessory in an on-state during the charge event, and cause the electric vehicle accessory to recharge by absorbing energy from the charging station during the charge event.

An apparatus structured to control an electric vehicle accessory of an electric vehicle during a charge event includes a controller communicatively coupled to a battery and an electric vehicle accessory. The controller is structured to determine that the battery of an electric vehicle is undergoing a charge event, and based on determining that the battery of the electric vehicle is undergoing the charge event, place the electric vehicle accessory in an on-state during the charge event, and cause the electric vehicle accessory to recharge by absorbing energy from the charging station during the charge event.

A vehicle includes an engine, a front frame, a rear frame, an intermediate frame, a front propeller shaft, a rear propeller shaft, and a wet oiling brake. A pair of right and left front lower arms are swingably mounted to the front frame. A pair of right and left rear lower arms are swingably mounted to the rear frame. The intermediate frame is located between the front frame and the rear frame. The front propeller shaft extends forward from the engine and the rear propeller shaft extends rearward from the engine. The wet oiling brake is located within a region defined by the intermediate frame in the front-rear direction and brakes a rotation of the front propeller shaft.

A vehicle includes an engine, a front frame, a rear frame, an intermediate frame, a front propeller shaft, a rear propeller shaft, and a wet oiling brake. A pair of right and left front lower arms are swingably mounted to the front frame. A pair of right and left rear lower arms are swingably mounted to the rear frame. The intermediate frame is located between the front frame and the rear frame. The front propeller shaft extends forward from the engine and the rear propeller shaft extends rearward from the engine. The wet oiling brake is located within a region defined by the intermediate frame in the front-rear direction and brakes a rotation of the front propeller shaft.

A vehicle that utilizes a counter-rotating electric motor to generate at least a portion of its propulsive force that includes the vehicle with front and rear wheels, the counter-rotating motor with two oppositely rotating components linked to two drive shafts that are coupled to the wheels in a common rotational direction, a component for reversible stopping the rotation of at least one rotating component while permitting the drive shafts to rotate, a power source linked to the motor, and a controller that controls both the speed of the vehicle and the reversible stopping component to switch between a first operational mode for slower vehicle speeds and a second operational mode for higher vehicle speeds, thereby increasing the overall electrical efficiency for operating the vehicle.

A vehicle that utilizes a counter-rotating electric motor to generate at least a portion of its propulsive force that includes the vehicle with front and rear wheels, the counter-rotating motor with two oppositely rotating components linked to two drive shafts that are coupled to the wheels in a common rotational direction, a component for reversible stopping the rotation of at least one rotating component while permitting the drive shafts to rotate, a power source linked to the motor, and a controller that controls both the speed of the vehicle and the reversible stopping component to switch between a first operational mode for slower vehicle speeds and a second operational mode for higher vehicle speeds, thereby increasing the overall electrical efficiency for operating the vehicle.