A rotating binding for a snowboard or other recreational equipment to which a user's foot is attached includes a lever having teeth at one end for engaging corresponding teeth in a disk attached to the snowboard or other equipment. Movement of the lever is resisted until an additional movement of the lever is performed in order to unsecure the lever from a secured position in which it engages the teeth within the disk. Some examples of the snowboard or other recreational equipment may include retractable fins that may be extended downward from the snowboard, or secured in a retracted position.

A rotating binding for a snowboard or other recreational equipment to which a user's foot is attached includes a lever having teeth at one end for engaging corresponding teeth in a disk attached to the snowboard or other equipment. Movement of the lever is resisted until an additional movement of the lever is performed in order to unsecure the lever from a secured position in which it engages the teeth within the disk. Some examples of the snowboard or other recreational equipment may include retractable fins that may be extended downward from the snowboard, or secured in a retracted position.

An interface for enabling a splitboard binding to be mounted to any snowboard is provided. The interface includes a baseplate that includes a disc for mounting the baseplate to a snowboard. The disc is configured to correspond with a common snowboard binding hole pattern to thereby allow the baseplate to be mounted on most snowboards. The interface further includes a puck that is configured to mount to the top surface of the baseplate. The puck is configured to interlock with many types of splitboard bindings. In this way, splitboard bindings can be mounted to a snowboard.

An interface for enabling a splitboard binding to be mounted to any snowboard is provided. The interface includes a baseplate that includes a disc for mounting the baseplate to a snowboard. The disc is configured to correspond with a common snowboard binding hole pattern to thereby allow the baseplate to be mounted on most snowboards. The interface further includes a puck that is configured to mount to the top surface of the baseplate. The puck is configured to interlock with many types of splitboard bindings. In this way, splitboard bindings can be mounted to a snowboard.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

A snowboard binding mounting system. The system includes a base plate and a main gear disposed on the base plate, the base plate engageable with a snowboard binding, the base plate having a plurality of screw openings each extending through the base plate and disposed around a circumference defined by the main gear; a plurality of pinion gears disposed on the base plate and meshed with the main gear, each pinion gear having a shaft opening aligned with a corresponding one of the screw openings; and a plurality of screws, each screw defining a shaft that extends through one of the pinion gear shaft openings and the corresponding screw opening.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

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.