The present invention relates to such a system, apparatus, and a method for allowing freedom and range of motion, movement, and spatial position on at least a snowboard or other board device. In one embodiment of the present invention, a mechanism of non-injury or MONI is used to allow a rider of a snowboard (or other device) the ability to move in multiple dimensions (in multiple angles and in multiple planes); the MONI embodiment allows a snowboard or other device to be inverted and offers an adjustable safety release mechanism as akin to skis. In another embodiment of the present invention, electro-magnetism is used to secure a rider to a snowboard (or other device) instead of a boot-binding, finally allowing a rider to maneuver like a skateboarder or surfer, with the ability to move anywhere on the board at will.

A snowboard binding with a base, a bearing shell movable about a first rotary pin supported by the base, and a pedal for controlling the bearing shell from an open position to a closed position, the bearing shell including a shell bottom and two shell sides supporting the pedal. The first rotary pin is supported by the bearing shell to form a boot stop in the shell bottom in any position of the bearing shell lying between an open position and the closed position. The shell bottom can support a bearing and the base, a pin housed in the bearing to form a hinge extending along the axis of rotation of the first rotary pin. The pedal can move relative to the shell sides about a second axis of rotation and be supported by two arms.

A snowboard binding including a baseplate, a bearing highback rotatable relative to the baseplate, a pedal to operate the bearing highback at clip-in between an opening position and a closing position and a locking element to lock the rotation of the bearing highback relative to the baseplate in closing position against the elastic return of a lever. The locking element includes two ratchet notches with the lever. The snowboard binding includes a lug that is received into a fork of the locking element with notches or of the lever to rotate the locking element with notches or the lever by unlocking the lever from one of the notches and by locking it with the other notch at clip-in.

A snow ski assembly is provided for use by an individual to slide across a snow covered surface, for example, under the force of gravity. The assembly includes a ski having a bottom wall for engaging the snow covered surface and an upturned peripheral region extending around a perimeter of the bottom wall. The bottom wall of the ski includes at least one control structure extending across at least a portion of the bottom wall, where the at least one control structure is configured to control a movement of the ski on the snow covered surface. The assembly also includes a mounting feature configured to couple a binding to the bottom wall of the ski, such that the individual can position a foot in the binding and use the ski to slide across the snow covered surface.

The present invention relates to a snowboard binding for coupling a snowboard shoe to a snowboard, comprising a baseplate, which is designed to be attached by means of a fastening device to a snowboard and to sit flat against same, a highback, which extends substantially perpendicularly to the baseplate, a toe strap, and an instep strap. The snowboard binding according to the invention is formed in two parts, wherein the baseplate and the toe strap are associated with a first module and the highback and the instep strap are associated with a second module. A coupling unit is provided, by means of which the first module and the second module can be releasably coupled to one another, the first module being designed to remain on the snowboard in a decoupled state and the second module being designed to remain on the snowboard shoe in the decoupled state.

A snowboard binding with a base, a bearing shell movable about a first rotary pin supported by the base, and a pedal for controlling the bearing shell from an open position to a closed position, the bearing shell including a shell bottom and two shell sides supporting the pedal. The first rotary pin is supported by the bearing shell to form a boot stop in the shell bottom in any position of the bearing shell lying between an open position and the closed position. The shell bottom can support a bearing and the base, a pin housed in the bearing to form a hinge extending along the axis of rotation of the first rotary pin. The pedal can move relative to the shell sides about a second axis of rotation and be supported by two arms.

The fastening device (3) for fastening a boot (4) to a sliding board (2) includes a base (10) intended to be fastened to a sliding board and to surround, at least partially, a sole and lateral sides of a boot, at least one lever (201, 301) that can move relative to the base and can interact with a retention element (44A, 44B) connected to a boot, the lever (201, 301) being able to move between a first retention position (P1) and a second clamping position (P2), the lever being able to retain the boot in the base when it is in its first position, the lever being able to transmit a downward force on the retention element when it is in its second position.

The fastening device (3) for fastening a boot (4) to a sliding board (2) includes a base (10) intended to be fastened to a sliding board and to surround, at least partially, a sole and lateral sides of a boot, at least one lever (201, 301) that can move relative to the base and can interact with a retention element (44A, 44B) connected to a boot, the lever (201, 301) being able to move between a first retention position (P1) and a second clamping position (P2), the lever being able to retain the boot in the base when it is in its first position, the lever being able to transmit a downward force on the retention element when it is in its second position.

A binding for snowboard includes a base structure and a heel support pivotally mounted to the base structure for movement between an open position for allowing a user to insert or remove their boot from the binding and a closed position for securing the users boot in the binding. An adjustable foot strap is attached to the base structure and a tensioning system is attached to the heel support and the adjustable foot strap for applying a tensioning force to the adjustable strap when the heel support is moved to the closed position and for releasing the tensioning force from the adjustable foot strap when the seal support is moved to the open position.