A loading system for a vehicle includes a buggy for transporting cargo and a mounting assembly for loading the buggy onto the vehicle. A buggy frame has an elongated member. The mounting assembly is configured to be connected to the vehicle and has a sliding rail configured to slidingly receive the elongated member of the buggy frame to allow the buggy to slide along the sliding rail. The sliding rail has a first portion and a second portion extending at an angle relative to the first portion such that, when the mounting assembly is connected to the vehicle, the first portion extends generally horizontally and the second portion extends downwardly from the first portion. The second portion is configured to slide the buggy upwards onto the vehicle. The first portion being configured to slide the buggy generally horizontally into a loaded position on the vehicle.

An all-terrain vehicle has an air ventilation system positioned adjacent a rearmost point of the front ground engaging members and directing air rearwardly through an engine compartment, wherein the air ventilation system includes at least one air scoop adjacent a front of the vehicle for directing the air. In addition, an ATV is disclosed having a rear rack having an integral storage bin, where the storage bin is one piece with the rear rack. The storage bin is sealed.

An electric off-road vehicle includes a drive assembly including an electric motor; wheels including front wheels and rear wheels; a frame assembly on which the electric motor arranged; a battery pack providing electric energy for the electric motor; and a drive train including a drive axle assembly and a drive shaft. The drive shaft is connected between the electric motor and the drive axle assembly. The electric motor transmits a torque to at least part of the drive axle assembly through the drive shaft, and the drive shaft is positioned below the battery pack.

An electric off-road vehicle includes a drive assembly including an electric motor; wheels including front wheels and rear wheels; a frame assembly on which the electric motor arranged; a battery pack providing electric energy for the electric motor; and a drive train including a drive axle assembly and a drive shaft. The drive shaft is connected between the electric motor and the drive axle assembly. The electric motor transmits a torque to at least part of the drive axle assembly through the drive shaft, and the drive shaft is positioned below the battery pack.

A switch assembly for mounting to a handlebar of a vehicle is disclosed. The switch assembly has a main housing mounted to the handlebar. The main housing has a first lateral side, a second lateral side opposite the first lateral side, a rear side, and a front side. The main housing defines a recess. The recess opens in the first lateral side and the rear side. The switch assembly also has one of: a cap selectively received in the recess; and a switch housing selectively received in the recess. The switch housing has a switch mounted thereto. The switch is configured for communicating with a component of the vehicle. The recess is configured for receiving the cap and for receiving the switch housing. A vehicle having a handlebar with the switch assembly mounted thereto is also disclosed.

Provided are a self-balancing scooter and a control method thereof, and a kart powered by the same. The self-balancing scooter includes two scooter bodies on which foot boards and motorized wheels are disposed, and a rotating shaft device, where the rotating shaft device includes a rotating shaft, two axle seats, and a torsion limiting mechanism. The torsion limiting mechanism controls a rotation angle by the fit between a limiting portion on the rotating shaft and a fitting portion on one axle seat. The present disclosure realizes torsion limit by directly using the rotating shaft and the axle seats without the use of an additional element (for example, a limiting shaft), thus simplifying the structure of the rotating shaft device and facilitating assembly.

An air scoop device having a sidewall longitudinally defined by a leading edge and a trailing edge, the sidewall extending between a top portion and a bottom portion, wherein the top portion, the bottom portion and sidewall define an interior space; an inner portion extending approximately orthogonally from a distal end of the bottom portion, wherein the inner portion further defines the interior space; the top portion having a top leading edge and a top trailing edge; a top cutout extending from the top trailing edge to a top distal end of the top portion; the bottom portion having a bottom leading edge and a bottom training edge; and bottom cutout extending from the trailing edge to the inner portion. The present invention may be configured in a kit of two air scoop devices and a set of installation instructions.

An air scoop device having a sidewall longitudinally defined by a leading edge and a trailing edge, the sidewall extending between a top portion and a bottom portion, wherein the top portion, the bottom portion and sidewall define an interior space; an inner portion extending approximately orthogonally from a distal end of the bottom portion, wherein the inner portion further defines the interior space; the top portion having a top leading edge and a top trailing edge; a top cutout extending from the top trailing edge to a top distal end of the top portion; the bottom portion having a bottom leading edge and a bottom training edge; and bottom cutout extending from the trailing edge to the inner portion. The present invention may be configured in a kit of two air scoop devices and a set of installation instructions.

A portal gear box assembly for an all-terrain vehicle includes a portal gear box housing with a set of gears contained therein, and a plurality of heat-radiating fins extending from the housing wall and effective to radiate heat from the housing at a faster rate than would be radiated in the absence of the fins. The fins may extend outward or inward from the housing, and may be formed integrally with one or more of the walls of the housing, or may be removably attached to the housing. Preferred fins comprise a generally rectangular, planer surface extending radially from a wall of the housing.

A portal gear box assembly for an all-terrain vehicle includes a sealed portal gear box housing having an interior housing space that contains a set of gears for linking an axle to an output shaft. An expandable space is in fluid communication with the interior housing space, and is adapted to allow pressurized fluid contained in the interior housing space to flow into the expandable space, thus expanding the volume of the expandable space and reducing the pressure within the interior housing space. The expandable space may be provided in the form of a bellows whose volume can be changed by expansion or contraction of a fluid contained therein. A fluid is contained within the portal gear box housing and within the expandable space.

The expandable space may be mounted externally to the portal gear box housing, and may be connected to the portal gear box housing by a conduit effective for allowing fluid to pass between the portal gear box housing and the expandable space. The expandable space and its connecting conduit are effective for allowing air to flow from within the portal gear box housing to the expandable space when an increased air pressure within the portal gear box is encountered, thus mitigating against a build-up of air pressure within the portal gear box housing.