The vehicle includes a powertrain having an axle having a first drive wheel and a second drive wheel. A first gearbox may couple a first power source to the first drive wheel, and a second gearbox may independently couple a second power source to the second drive wheel. And, a controller may be configured to initiate a gear shift in the first gearbox and the second gearbox at different times.

A method of operating an electric vehicle having multiple electric traction motors include receiving a signal indicative of a driver requested torque, and determining portions of the torque request to produce from each traction motor based on efficiency maps of the motors. The method may also include producing the determined portions of torque from each motor.

Aspects of the disclosure provide an adjustable storage panel apparatus for a vehicle (e.g., bus) that includes an upper panel assembly; a lower panel assembly, wherein an upper edge of the lower panel assembly pivotably engages a bottom edge of the upper panel assembly; opposing horizontal tracks comprising a front end and a back end, the horizontal tracks configured to be disposed on each of opposing side walls of the vehicle, wherein the lower panel assembly slideably engages each of the opposing horizontal tracks; and opposing vertical tracks comprising an upper end and a lower end, the vertical tracks configured to be disposed on each of opposing side walls of the vehicle along a vertical plane. The upper panel assembly slideably engages each of the opposing vertical tracks such that the upper and lower panel assemblies are positioned along the vertical plane in an extended position and the lower panel assembly is capable of being slid along a length of the horizontal track such that the lower panel assembly remains substantially parallel to the vertical plane and the upper panel assembly becomes oriented at an angle relative to both the vertical plane along the opposing vertical tracks and the lower panel assembly.

A shut down system of a fuel cell vehicle includes: a fuel cell configured to output a high voltage; a rechargeable high voltage battery; a bidirectional converter arranged between an output terminal of the fuel cell and the high voltage battery; a first relay arranged between the fuel cell and the bidirectional converter; and a controller configured to control a voltage of the bidirectional converter when the fuel cell vehicle stalls to reduce a voltage of the output terminal of the fuel cell and turn off the first relay when a voltage value of the output terminal of the fuel cell is below a preset voltage reference value.

The present disclosure discloses an electric drive axle assembly and a vehicle having the electric drive axle assembly. The electric drive axle assembly includes: an electric power assembly and an axle case assembly. The electric power assembly includes a power motor, a transmission, and a differential; the transmission has a transmission housing, the power motor being fixed to the transmission housing; the differential is supported on the transmission housing. The axle case assembly includes an axle case component and two half axles, the two half axles and the differential are both located inside the axle case component, and the transmission housing is fixed to the axle case component. For the electric drive axle assembly according to the embodiment of the present disclosure, the electric power assembly and the axle case assembly are integrated, which shortens a transmission chain, improves transmission efficiency, creates a compact structure and saves space.

A method of controlling an electric vehicle operating on a route includes receiving at a first time, at a control unit of the electric vehicle, data indicative of a condition of a stretch of the route that the electric vehicle will traverse at a second time later than the first time. The method further includes varying a cooling of a battery system of the electric vehicle, using the control unit, based on the received data.

An articulated vehicle having at least two vehicle parts which are connected to and articulated relative to each other is provided. The vehicle includes a front vehicle part and at least one rear vehicle part arranged behind the front vehicle part with respect to a longitudinal direction of the vehicle. The front vehicle part has a first drive unit including at least an electric motor and a first energy storage system; and at least one rear vehicle part has a drive unit including at least an electric motor and an energy storage system. Each rear vehicle part includes an individual electrical system that is galvanically isolated from the front vehicle part and from each other at least under normal driving conditions.

The disclosure relates to a powertrain for a vehicle, comprising: a transmission and a differential gear which are drivingly connected to each other, wherein the differential gear is configured to be drivingly connected to driving wheels of the vehicle; wherein the transmission comprises a first set of gearwheels and a second set of gearwheels, at least one gearwheel of the first set of gearwheels being drivingly connected to at least one gearwheel of the second set of gearwheels via at least a first shaft which is configured to rotate about a first rotational axis, wherein the first set of gearwheels is arranged on a first side of the differential gear and the second set of gearwheels is arranged on a second opposite side of the differential gear. The disclosure also relates to a vehicle.

Aspects of the disclosure provide an adjustable storage panel apparatus for a vehicle (e.g., bus) that includes an upper panel assembly; a lower panel assembly, wherein an upper edge of the lower panel assembly pivotably engages a bottom edge of the upper panel assembly; opposing horizontal tracks comprising a front end and a back end, the horizontal tracks configured to be disposed on each of opposing side walls of the vehicle, wherein the lower panel assembly slideably engages each of the opposing horizontal tracks; and opposing vertical tracks comprising an upper end and a lower end, the vertical tracks configured to be disposed on each of opposing side walls of the vehicle along a vertical plane. The upper panel assembly slideably engages each of the opposing vertical tracks such that the upper and lower panel assemblies are positioned along the vertical plane in an extended position and the lower panel assembly is capable of being slid along a length of the horizontal track such that the lower panel assembly remains substantially parallel to the vertical plane and the upper panel assembly becomes oriented at an angle relative to both the vertical plane along the opposing vertical tracks and the lower panel assembly.

A power steering electrohydraulic system is provided for an electric vehicle, including: at least one reservoir of hydraulic fluid; and at least one hydraulic actuator for actuating a steering rack shaft of the vehicle; at least two electric motor pump units in parallel for supplying the actuator with hydraulic fluid from the reservoir and adjusting the flow rate of the hydraulic fluid supplied to the actuator, and each electric motor pump unit is a motor pump unit operating at a voltage of 24V. A vehicle equipped with such a system is also provided.