A bifurcated truck in a laterally-sliding board wheel assembly enables the freeboard to seamlessly transition from carvingas associated with a traditional skateboardto new omnidirectional motions, in which the board can easy travel forward, backwards, sideways or in any other directional combination. The wheel assembly of this invention employs a bifurcated truck system having two independent suspension arms, both operating independently from one another and from the board's castering wheels. The wheel assemblies are mirrored at each longitudinal end of the board, resulting in the board's ability to carve, slide or skidand easily transition back and forth among each of these modesproviding the rider a sense of stability and freedom commonly associated only with snowboarding.

A skateboard includes a board adapted for a user to stand with both feet thereon and having a major axis, and a front steering device and a rear steering device respectively disposed on front and rear sections of a bottom surface of the board along the major axis and each having two wheels. The front or rear steering device has a wheel seat disposed on the bottom surface of the board rotatably around a rotation axis which inclines downwards from front to rear, and a wheel rack disposed on the wheel seat rotatably or swingably around a main axis. An abutted surface is defined where the wheel seat and the wheel rack are abutted against each other. On an imaginary vertical plane including the major axis, where the rotation axis passes the abutted surface is in front of where the main axis passes the abutted surface.

Provided is a ball skate sole structure which can be customized for each individual or each sport. This ball skate sole structure includes: a base plate having a plurality of first holes and a plurality of second holes; at least one ball roller member, the at least one ball roller member being disposed in the first hole selected from among the plurality of first holes; and at least one brake member, the at least one brake member being disposed in the second hole selected from among the plurality of second holes.

A skateboard or longboard truck having configured to couple with a deck of the skateboard or longboard. The truck including a base and a hanger. The hanger disposed within a hanger aperture of the base. The hanger rotatably coupled with the base by a pivot assembly. The rotation of the hanger with respect to the base controlled by a compression assembly.

A suspension system for a small vehicle is described that includes a shock absorbing spring, a chassis integration assembly, and an adjustment mechanism, wherein the adjustment mechanism is adapted to be able to adjust a travel range of the shock absorbing spring to adjust a range of compression of the shock absorbing spring relative to a force-bearing capacity range of the small vehicle. The chassis integration assembly may include two attachment supports that are connected by a rod-and-piston in a cylinder that connects to each attachment support using a hinge. The rod traverses the spring, and the spring creates suspension between the two attachment supports. The suspension system may be configured to be controlled by gas or any other means of dampening by extension or compression.

A tracked skate runner provides a low-profile substitute for a wheel with exceptionally low rolling resistance on rough or soft terrain. The runner includes a skate frame and rollers that bear against an endless track of hinged links devoid of pinch points that can get jammed with ground debris. The skate frame provides a channel with sidewalls and a top dirt shield. The sidewalls fit closely with the links of the track to seal out dirt, and the top dirt shield protects the rollers from dirt that shakes off the top recirculating portion of the track.

A suspension for a skateboard, comprising a pair of steering knuckles on opposite sides of a chassis frame of the skateboard, a pair of upper control arms connected between the pair of steering knuckles and the chassis frame, a pair of lower control arms connected between the pair of steering knuckles and the chassis frame, and a first spring damper connected between the pair of upper control arms.

A one-wheeled vehicle may comprise a board including first and second deck portions each configured to receive a left or right foot of a rider oriented generally perpendicular to a direction of travel of a board, and a pair of side rails, each of which are coupled to the first and second deck portions at distal ends. A top surface of each side rail defines a generally concave shape, such that a plane connecting distal edges of the end portions of the side rail is spaced apart from the central portion of the side rail. In some examples, a bottom surface of each side rail also defines a generally concave-upward shape. In some examples, a bottom surface of each side rail includes a central cutout.

Exemplary embodiments are directed to a base plate for a skateboard that includes a body, and first and second pivot cups. The body includes a proximal end and a distal end. The first pivot cup extends from the body at or near the distal end. The second pivot cup is spaced from the first pivot cup and extends from the body at or near the proximal end. The second pivot cup defines an outer perimeter surface having an uninterrupted height. The second pivot cup includes an opening extending therethrough and surrounded by the outer perimeter surface of the second pivot cup. The second pivot cup includes one or more channels extending from the opening and through at least a portion of the second pivot cup. The one or more channels extend through at least the portion of the second pivot cup without extending through the outer perimeter surface.

An electric weight sensing skateboard using one or more strain gauge systems to detect rider-induced strain on one or both trucks, an inertial sensor to detect accelerations and balance position, and wheel speed sensors. Throttle is controlled by rider position, for example, lean forward to increase speed, lean back to slow down. Several drive methods include a driver position detection velocity setpoint control, torque setpoint control, and direct velocity/torque control. A throttle remote is note required. Rider weight activates the motors.