A Method and apparatus for reducing stress on the body (e.g., foot, ankle, hip, spine) of a snowboarder while sitting on a chairlift. The apparatus includes a boot binding assembly adapted for mounting on the top surface of a snowboard including a boot retention member hinged for movement between a dosed position and an open position. For typical downhill snowboarding activity, a user will place the retention member in the closed position to orient the sole of the user's boot substantially parallel, i.e. against the snowboard top surface. For sitting on a chairlift, the user will place the retention member in the open position so as to allow the snowboard to pivot around the hinge and hang substantially vertically from the retention member thus avoiding stressful torques on the user's supporting limb.

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.

A sport board binding system includes a receiver configured to be secured to a deck of a sport board, a boot, and an intermediate locking member. The receiver defines a channel extending inward from a periphery of the receiver. The boot is configured to be worn by a user and includes an engagement mechanism. The intermediate locking member includes a lower head connected to an upper head by way of a neck with the lower head selectively housed within the channel of the receiver and the upper head selectively housed within the engagement mechanism of the boot.

A flat board as a base plate of a binding for splitboards with holders for the bindings' fixation on skis that are joined together to form a snowboard that has a circular slit (or opening) formed in a central part of the board. The circular slit is equipped with a perimeter recess for removable fixation of a contact ring which is, on its inner perimeter, equipped with two pairs of opposed dents (or indentations) that are designed for connection with a holder. The contact ring is also modified between the dents (or indentations) for insertion of end pins of a locking eccentric. The locking eccentric is formed by an axial shaft with end pins protruding from end hubs formed at both ends of the axial shaft.

A flat board as a base plate of a binding for splitboards with holders for the bindings' fixation on skis that are joined together to form a snowboard that has a circular slit (or opening) formed in a central part of the board. The circular slit is equipped with a perimeter recess for removable fixation of a contact ring which is, on its inner perimeter, equipped with two pairs of opposed dents (or indentations) that are designed for connection with a holder. The contact ring is also modified between the dents (or indentations) for insertion of end pins of a locking eccentric. The locking eccentric is formed by an axial shaft with end pins protruding from end hubs formed at both ends of the axial shaft.

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.

The present invention relates to, a sliding board, the structure of which comprises at least one lower layer, at least one upper layer, a core, at least one rail delimiting a groove with a top opening for receiving and guiding an anchoring component for a shoe fastening baseplate, wherein it comprises at least one serrated bar separate and spaced apart from the groove of the rail and designed to interact with at least one peripheral toothed sector mounted on the lower surface of the baseplate with a view to preventing its longitudinal translational movement, and to, a fastening device designed to equip said sliding board and a snowboard equipment comprising said sliding board and said device.

The present invention relates to, a sliding board, the structure of which comprises at least one lower layer, at least one upper layer, a core, at least one rail delimiting a groove with a top opening for receiving and guiding an anchoring component for a shoe fastening baseplate, wherein it comprises at least one serrated bar separate and spaced apart from the groove of the rail and designed to interact with at least one peripheral toothed sector mounted on the lower surface of the baseplate with a view to preventing its longitudinal translational movement, and to, a fastening device designed to equip said sliding board and a snowboard equipment comprising said sliding board and said device.