Skateboard training devices are provided to assist all levels and ages of skateboard enthusiasts in learning tricks. The devices can comprise a deck including a core comprising a set of materials, wherein the core is partially or entirely surrounded by an outer protective material. In some aspects, the core can be made of one or more of a wood, a plastic, a metal, a composite, a fiberglass, and nylon. In some aspects, the outer protective material comprises a foam material. In some aspects, the core can comprise a foam material that is denser than an outer protective foam material.

The present disclosed subject matter relates to a method for producing a composite component, in particular for a gliding board, roller board or skateboard. The method comprises introducing a bottom mat made of reinforcing fibers, above this a flat core made of plastic, and above this a top mat made of reinforcing fibers into an opened mold, closing the mold, introducing an uncured plastics matrix into the closed mold, allowing the plastics matrix to cure in the closed mold, opening the mold, and demolding the composite component. The core is provided on its lower and upper sides with a plurality of spacer nubs, which keep the bottom and top mats in the closed mold at a distance from the lower and upper sides.

A skateboard comprising a board having an independent suspension and steering assembly connecting two wheels to the board. The suspension assembly comprises a support frame rotatably coupled to an underside of the board. The steering assembly comprises a steering crank fixed to and extending from an underside of the board. The suspension assembly further comprises for each wheel: a spindle for rotatably supporting the wheel; a knuckle for holding the spindle; an upper and a lower suspension arm pivotably coupled to the support frame at an upper and at a lower point of the support frame, respectively, and also pivotably coupled to the knuckle at an upper and at a lower point of the knuckle; and a spring for resiliently holding the knuckle against the board. The steering assembly further comprises for each wheel: a tie rod coupled by a ball joint to the steering crank and to the knuckle.

The detachable skateboard assembly includes a base part configured for detachable attachment to a board and an upper part configured for detachable attachment to the base part. The upper part is coupled to the base part in such a way that they can pivot relative to each other about a first pivoting axis. The detachable skateboard assembly further includes a wheel unit configured for attachment to the upper part and an elastomeric element arranged between the base part and the upper part such that the elastomeric element is compressed by the pivoting movement between the upper part and the base part. The elastomer element exerts a force tending to make the upper part and base part to recover a neutral position corresponding to the rectilinear displacement of the skateboard.

A steering axle unit (24) for chassis or skateboards, comprising a bearing block (1) and a steering axle body (98), wherein the bearing block (1) has a fastening plane (11) for fastening to a chassis or skateboard, particularly skateboard deck (52), wherein, in the assembled state, the fastening plane (11) is arranged on the chassis or skateboard particularly so as to be parallel to the designated direction of travel (25) of the chassis or skateboard, and wherein the bearing block (1) comprises a vertical axis CD (22) about which the steering axle unit (98) is arranged so as to rotate relative to the bearing block (1), an axle (8) that projects normally from the vertical median longitudinal plane of the bearing block (1) in the straight-ahead position being arranged on the steering axle body (98), wherein the vertical axis CD (22) is arranged on the median longitudinal plane of the bearing block (1) at an angle W1 (19) of less than 90° relative to the fastening plane (11) in the direction of the steering axle body (98), wherein the axle (8) is arranged at a normal distance (20) to the vertical axis CD (22), and wherein the axle (8) is arranged in front of the vertical axis CD (22) in the designated direction of travel (25) of the chassis or skateboard.

A carbon fiber reinforced skateboard is formed of laminated wood layers having identified grain directions. Upper and lower wood layers will have a grain direction parallel to a long axis of the skateboard. The skateboard will have interspersed wood layers with identified grain directions perpendicular to the long axis. Carbon fiber reinforcing material is adhered to interior plies of the skateboard along the long axis. A central portion of the reinforcing material is adhered below a central vertical point of the skateboard between the skateboard trucks. Anterior and posterior portions of the reinforcing material are adhered above the central vertical point and are located around the attachment locations for the skateboard trucks. The reinforcing material is located to provide a strengthened spine for the skateboard. A first concavity is located between the skateboard trucks parallel to the long axis. Second and third concavities are located perpendicular to the long axis.

A gripping surface includes a plurality of projections extending away from the gripping surface and a plurality of voids between and defined by the projections. The gripping surface may be disposed on a support surface, such as a deck of a skateboard or a deck of a balance board. The projections may be formed by cutting the support surface with a router, such as a computer numerical control router. The projections may each comprise three or more angles surfaces, whereby angled surfaces of proximal projections are positioned at mirror angles of one another.

A Single-foot Skateboard. The Skateboard has interchangeable components in order to reduce spare part inventory. The footboard of the Skateboard is reversible.

Methods and apparatus are discussed for an electric powered personal transportation vehicle with electric motors powered by one or more batteries. A set of universal battery mounting hole locations and a reserved space for one or more battery housings exist on a board for the personal transportation vehicle. The reserved space on the board for the one or more battery housings that house one or more battery packs is set to not interfere with an operation of the motors or the wheels. A first battery pack containing the one or more batteries differs in at least one of i) a different amp-hour capacity, ii) a different length, width, or height, and iii) a different shape than another battery pack designed to be physically contained in the one or more battery housings and electrically connect with corresponding electrical connections in the one or more battery housings.

A composite panel structure has opposing outer walls or surfaces and a core comprising a plurality of ribs extending between and connected to the outer walls and defining chambers which are filled with expanding foams, non-expanding foams, gases, or a combination thereof. The outer panel surfaces and internal chamber walls or ribs are made of woven or non-woven fibrous material impregnated with one or more resins. The panel structure may be used for making a variety of products including sports equipment such as sports paddles, surfboards, kite boards, skateboards, wakeboards, as well as construction panels for walls, ceilings or floors, display panels, panels for the vehicle industry, furniture, and other structures requiring high strength to weight properties.