A vehicle front portion structure include: side rails that extend in a vehicle longitudinal direction, that have rear end portions connected to a battery; a front side cross member, that is connected to a vehicle front side of both of the side rails and extends in a vehicle transverse direction; and a rear side cross member, extends in the vehicle transverse direction, wherein a front portion of each side rail is positioned further toward a vehicle upper side than a rear portion of the side rail, and an inclined portion, which is inclined toward a vehicle lower side while heading from a vehicle front side toward a vehicle rear side, is provided between the front portion and the rear portion, and wherein a gear box is disposed at a vehicle lower side of the inclined portions, as seen in a vehicle side view.

An electric vehicle includes a fuel cell unit and a power controller unit that are disposed next to each other in a front compartment. Each of the fuel cell unit and the power controller unit includes an upper casing having a lower strength and a lower casing having a strength greater than that of the upper casing. The fuel cell unit and the power controller unit are arranged so that a distance La between the lower casings along an alignment axis is shorter than a distance Lb between the upper casings along the alignment axis.

An electric power take-off system includes a motor configured to convert electrical power received from a battery into hydraulic power, an inverter configured to provide electrical power to the motor from the battery, a heat dissipation device in thermal communication with the inverter, wherein the heat dissipation device includes a thermal fluid pump configured to pump cooling fluid through a plurality of conduits, a flow meter configured determine a flow rate through the plurality of conduits, and a controller configured to receive data from the flow meter and provide operating parameters to the heat dissipation device, wherein the controller is further configured to determine if the data from the flow meter is less than a critical operating condition and decrease the hydraulic power provided by the electric power take-off system in response to determining that the data from the flow meter is less than the critical operating condition.

A mechanical stabilization system for a battery assembly is disclosed. The system includes an actuator and a stabilizer that are configured to work in concert. The actuator and stabilizer are disposed in a housing of the battery assembly. The system may be implemented by depression of the actuator disposed in the housing, which causes the stabilizer to retract a support post into the housing. The depression can occur during a docking operation of the battery assembly with a lift mechanism for an electric vehicle. When the actuator is released, the support post automatically reverts to its previous, deployed state. The support post is configured to maintain the battery assembly in a stable configuration when the battery assembly is separated from the electric vehicle.

A refuse vehicle includes a chassis, an energy storage device, a vehicle body, an electric power take-off system, and a hydraulic component. The energy storage device is supported by the chassis and is configured to provide electrical power to a prime mover. Activation of the prime mover selectively drives the refuse vehicle. The vehicle body is supported by the chassis, and includes an on-board receptacle for storing refuse therein. The electric power take-off system is positioned on the vehicle body, and includes an electric motor configured to drive a hydraulic pump to convert electrical power received from the energy storage device into hydraulic power. An amount of electrical power at least one of received by and provided to the electric motor is limited by a controller to control an output characteristic of the hydraulic pump. The hydraulic component is in fluid communication with the hydraulic pump and configured to operate using hydraulic power from the electric power take-off system.

A towing module of a personal mobility includes: a main body provided to extend in a vertical direction and in which a battery is mounted: a driving wheel installed on a lower portion of the main body and having a driving motor: a steering handle installed on an upper portion of the main body; and a connector provided in the main body to selectively connect one of various types of modules to be towed. The main body is maintained in a standing state while driving by the connection to the module to be towed. A personal mobility and a control method thereof utilize the towing module.

[Problem] To improve the weight balance in the front-rear direction of an electric work vehicle having a configuration in which a battery is mounted on the front side, to lower the center of gravity of the electric work vehicle, to shorten the wiring distance when a main switch is switched using an operation switch, and to prevent the length of a space inside a bonnet in a front-rear direction from becoming excessively large. [Solution] An electric work vehicle includes: front wheels and rear wheels supported by a vehicle body frame; a driver's seat provided above a rear end portion of the vehicle body frame; a traveling motor for driving the rear wheels; a power transmission unit that is integrated with the traveling motor, and reduces the power of the traveling motor and transmits the power to an axle that is joined to the rear wheels; and a battery that supplies power to the traveling motor via a first inverter. The battery is disposed inside the bonnet mounted on the front side of the vehicle body frame, and the traveling motor, the power transmission unit, and the first inverter are disposed under the driver's seat.

The disclosure relates to the technical field of vehicle body structures, and in particular provides a vehicle and a front longitudinal beam rear section member of the vehicle. The front longitudinal beam rear section member comprises a base part, and a first part and a second part which are located on two sides of the base part in a width direction of the vehicle, the vehicle is provided with a traction battery, and the traction battery is at least connected to the base part; the vehicle comprises a cross beam located behind the front longitudinal beam rear section member in a length direction of the vehicle, and the base part is connected to the cross beam; and the vehicle comprises two rocker panels separately arranged in the width direction of the vehicle, and each of the first part and the second part is connected to the rocker panel on a corresponding side, wherein at least some of the base part, the first part and the second part are of an integrally-formed structure. With such a configuration, difficulties in the manufacture of different parts themselves and in matching between parts are reduced, and the product consistency of front longitudinal beam rear section members is improved.

The disclosure relates to an electric vehicle for the transportation of persons and/or loads, having a frame structure and axle modules which are coupled to the frame structure, a front axle module and a rear axle module, to which in each case the wheels are coupled kinematically, at least one of the axle modules having a drive and an energy source. One of the axle modules has four suspension points for the attachment by means of elastic bearings to the frame structure, in each case, two suspension points forming a pair, and the pairs lying at different heights in the motor vehicle vertical direction.

A battery is mounted in front of the vehicle along a longitudinal direction of the vehicle and mounted on the vehicle body, and the fuel tank is mounted in the vehicle body by disposing the fuel tank at the rear side in the longitudinal direction of the vehicle such that expansion of passenger compartment and vehicle body stability may be achieved.