A portable snowboard with detachable parts comprises a first planar section and a second planar section. The first planar section comprises a first member of an interconnecting joint. A second end of the first planar section comprises the first member of the interconnecting joint. The second planar section comprises a second member of the interconnecting joint. The second end of the second planar section comprises a second member of the interconnecting joint. The first member of the interconnecting joint is detachably fastened to the second member of the interconnecting joint to engage the first planar section with the second planar section to form the portable snowboard.

A portable snowboard with detachable parts comprises a first planar section and a second planar section. The first planar section comprises a first member of an interconnecting joint. A second end of the first planar section comprises the first member of the interconnecting joint. The second planar section comprises a second member of the interconnecting joint. The second end of the second planar section comprises a second member of the interconnecting joint. The first member of the interconnecting joint is detachably fastened to the second member of the interconnecting joint to engage the first planar section with the second planar section to form the portable snowboard.

A snowboard having a multicore construction comprising a plurality of layers, including at least two wood cores separated by an inner composite layer, and outer composite layers arranged between a wood core and the base or top sheet of the snowboard, respectively. Also, a production method for a multicore snowboard design.

A snowboard having a multicore construction comprising a plurality of layers, including at least two wood cores separated by an inner composite layer, and outer composite layers arranged between a wood core and the base or top sheet of the snowboard, respectively. Also, a production method for a multicore snowboard design.

The invention concerns a snowboard binding (1) comprising a snowboard anchor element (2) and a boot anchor element (3); at least one pivot mechanism (4) pivotally coupling the snowboard anchor element (2) and the boot anchor element (3) to allow pivoting of the boot anchor element (3) with respect to the snowboard anchor element (2). It also concerns a snowboard adapted for this binding.

The invention concerns a snowboard binding (1) comprising a snowboard anchor element (2) and a boot anchor element (3); at least one pivot mechanism (4) pivotally coupling the snowboard anchor element (2) and the boot anchor element (3) to allow pivoting of the boot anchor element (3) with respect to the snowboard anchor element (2). It also concerns a snowboard adapted for this binding.

The subject invention provides a snowboard that is propelled over the snow by a battery powered hub motor. The preferred embodiments include a pair of elastic arms mounted in the tails section of the snowboard, on which specialized snow paddles are fitted to a hub motor designed for various snow conditions. The paddle wheel attaches to the elastic arms through axle locking plates transferring the trust provided by the hub motor to the snowboard.

Embodiments of the present disclosure provide a sled having a sled attachment and a runner. The sled attachment may include a control deck and a connector assembly coupled to and positioned below the control deck. The runner may be coupled to the connector assembly and spaced apart from the deck. The runner may extend along a longitudinal axis of the control deck. The runner may comprise a snowboard.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.