An all-terrain vehicle includes a frame, a cockpit, wheels, suspension assemblies, an engine, a seat support, a cushion, and a storage box. The frame includes a longitudinal beam extending along a front-rear direction and a vertical beam extending upwards from the longitudinal beam. The cockpit is arranged in a middle portion of the frame. The wheels are connected to left and right sides of the frame. The suspension assemblies are connected between the wheels and the frame. The engine is disposed on the frame. The seat support is disposed on the frame, and includes a cushion support and a backrest support both arranged in the cockpit, and the backrest support is located above the cushion support. The cushion is mounted on the cushion support. The storage box is detachably mounted on the backrest support, and the storage box and the cushion form a seat that can be leaned on.

An all-terrain vehicle includes a frame, a cockpit, wheels, suspension assemblies, an engine, a seat support, a cushion, and a storage box. The frame includes a longitudinal beam extending along a front-rear direction and a vertical beam extending upwards from the longitudinal beam. The cockpit is arranged in a middle portion of the frame. The wheels are connected to left and right sides of the frame. The suspension assemblies are connected between the wheels and the frame. The engine is disposed on the frame. The seat support is disposed on the frame, and includes a cushion support and a backrest support both arranged in the cockpit, and the backrest support is located above the cushion support. The cushion is mounted on the cushion support. The storage box is detachably mounted on the backrest support, and the storage box and the cushion form a seat that can be leaned on.

An electrified vehicle include a chassis, a front axle coupled to the chassis, a rear axle coupled to the chassis, an electric motor supported by the chassis, and a trailer coupled to a rear end of the chassis and configured to be towed by the electrified vehicle. The electric motor is configured to drive at least one of the front axle, the rear axle, or a component of the electrified vehicle. The trailer includes a trailer frame, a trailer axle coupled to the trailer frame, and an energy storage device supported by the trailer frame. The energy storage device includes a plurality of batteries. The energy storage device configured to power the electric motor.

An electrified vehicle include a chassis, a front axle coupled to the chassis, a rear axle coupled to the chassis, an electric motor supported by the chassis, and a trailer coupled to a rear end of the chassis and configured to be towed by the electrified vehicle. The electric motor is configured to drive at least one of the front axle, the rear axle, or a component of the electrified vehicle. The trailer includes a trailer frame, a trailer axle coupled to the trailer frame, and an energy storage device supported by the trailer frame. The energy storage device includes a plurality of batteries. The energy storage device configured to power the electric motor.

A vehicle, a running board assembly, and a drive assembly for a running board are disclosed. The drive assembly includes: a mounting base, a first connecting portion, a second connecting portion, and a running board holder. The first connecting portion is rotatably connected with the mounting base and the running board holder. The second connecting portion is rotatably connected with the mounting base and the running board holder. The running board holder includes a third main body and a third hinged portion. The first connecting portion includes a first main body and a plurality of first hinged portions, and the third hinged portion is rotatably connected among the plurality of first hinged portions; and/or the second connecting portion includes a second main body and a plurality of second hinged portions, the third hinged portion being rotatably connected among the plurality of second hinged portions.

A vehicle frame includes a frame rail, a shock tower bracket, and a cable. The frame rail is elongated along a vehicle-longitudinal axis. The shock tower bracket is connected to the frame rail. The cable is connected to the frame rail and the shock tower bracket. The cable extends transverse to the vehicle-longitudinal axis from the frame rail to the shock tower bracket.

A vehicle frame includes a frame rail, a shock tower bracket, and a cable. The frame rail is elongated along a vehicle-longitudinal axis. The shock tower bracket is connected to the frame rail. The cable is connected to the frame rail and the shock tower bracket. The cable extends transverse to the vehicle-longitudinal axis from the frame rail to the shock tower bracket.

A vehicle underbody structure includes a pair of rockers that are provided on both vehicle width direction sides of a vehicle underbody and extend in a vehicle front-rear direction, a battery that is disposed centrally in a vehicle width direction center between the pair of rockers and is disposed above a vehicle floor and on the lower side of a seat, a fuel tank that is disposed in the vehicle width direction center between the pair of rockers and is disposed under the vehicle floor and further toward a rear side of the vehicle than the battery, and a waste pipe that is coupled to a drive unit provided at a vehicle front side of the battery and extends in the vehicle front-rear direction between the battery and one of the rockers.

A vehicle underbody structure includes a pair of rockers that are provided on both vehicle width direction sides of a vehicle underbody and extend in a vehicle front-rear direction, a battery that is disposed centrally in a vehicle width direction center between the pair of rockers and is disposed above a vehicle floor and on the lower side of a seat, a fuel tank that is disposed in the vehicle width direction center between the pair of rockers and is disposed under the vehicle floor and further toward a rear side of the vehicle than the battery, and a waste pipe that is coupled to a drive unit provided at a vehicle front side of the battery and extends in the vehicle front-rear direction between the battery and one of the rockers.

A system and method for compensating reduced track speed because of engine droop for a work machine is disclosed. The system may comprise a frame, an attachment coupled to the frame, a ground-engaging mechanism adapted to support the frame, an engine, a motor, a track speed sensor, an engine speed sensor, and a controller. The engine may drive the ground-engaging mechanism and attachment. The engine may be coupled through a variable speed transmission to the ground-engaging mechanism and the attachment. They variable speed transmission may include a hydrostatic circuit. The controller may be adapted to send an increased transmission command signal based on a drop in the engine speed signal when the work machine engages an increased load. The increased transmission command signal may increase a motor speed to cause an increase in track speed to compensate at least a portion of the reduced track speed from the engine speed droop.