Disclosed is a novel ankle strap and a toe strap that secures snowboard or splitboard rider's boots to corresponding boot bindings. The straps are generally made from a one-piece molding that includes indented portions on the outside surface of the molding that creates corresponding outdented portions on the boot-facing surface for cushioning. The indented portions are bound by ribs, the ribs forming a continuous interconnected rib structure. As the outdented portions flex, the continuous interconnected rib structure helps the strap maintain its shape and structure.

Fixation of a binding board to skis demountable connected into a form of a splitboard uses a sliding demountable setting of bearing pins in eyes formed on adjacent areas of the board and a clamp fixed to the skis. The essence of the invention is a fixation of the lateral parts of the eyes by stoppers which partially overreach into the cross sections of the eyes. The diameter of the bearing pins basically corresponds with the diameters of the eyes. The bearing pins are equipped with circular recesses for engaging of the stoppers and also with end parts formed as from above one-sidedly reduced conical tips.

Fixation of a binding board to skis demountable connected into a form of a splitboard uses a sliding demountable setting of bearing pins in eyes formed on adjacent areas of the board and a clamp fixed to the skis. The essence of the invention is a fixation of the lateral parts of the eyes by stoppers which partially overreach into the cross sections of the eyes. The diameter of the bearing pins basically corresponds with the diameters of the eyes. The bearing pins are equipped with circular recesses for engaging of the stoppers and also with end parts formed as from above one-sidedly reduced conical tips.

A toe strap of a snowboard binding is constituted of one belt to fasten an upper portion of a tiptoe of a boot and another belt to fasten a tip of the tiptoe of the boot, and it is a problem to have a configuration to guide the toe strap so as to be fastened to an appropriate position with respect to a shape of the tiptoe portion of the boot when the boot is mounted. At least any one belt of the one belt and the other belt of the toe strap includes an extending portion that extends at least any direction of front and rear on a center position in a lateral direction, and the extending portion of the belt is configured to abut on the boot prior to a non-extending portion of the belt on an adjacent position when the boot is mounted.

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.

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 binding system includes a base portion shaped to receive a boot. The base portion has first and second opposite facing surfaces. The binding system also includes a first interface having first and second surfaces. The first interface includes two separable interface portions, with each of the two interface portions having first and second opposite facing surfaces and including at least one coupling element disposed over at least the second surface of the interface portion. The at least one coupling element includes a body segment proximate to the second surface of the interface portion and a blocking head segment distal to the second surface of the interface portion. The body segment has a first width with respect to a longitudinal axis of the body segment and the blocking head section having a second, greater width than the first width.

A binding system includes a base portion shaped to receive a boot. The base portion has first and second opposite facing surfaces. The binding system also includes a first interface having first and second surfaces. The first interface includes two separable interface portions, with each of the two interface portions having first and second opposite facing surfaces and including at least one coupling element disposed over at least the second surface of the interface portion. The at least one coupling element includes a body segment proximate to the second surface of the interface portion and a blocking head segment distal to the second surface of the interface portion. The body segment has a first width with respect to a longitudinal axis of the body segment and the blocking head section having a second, greater width than the first width.

A mechanism for attaching, for example, a boot to a ski, that uses a sphere in cylinder geometry to enable release in a wide array of incremental directions and rotations.

Splitboard binding systems including a binding that may be attached to either a left or right gliding board in a ski mode or to both gliding boards in a snowboard mode. The binding includes left and right bottom rails attached to the bottom surface of a base plate, which define channels for slidable attachment to “pucks” disposed on the gliding board in snowboard mode. Each rail has a circular bore at a forward end for attachment to a counterpart pivot pin on a ski mode toe bracket in a ski mode by a sideways movement. A securing lever is disposed on an upper surface of the toe bracket. When the securing lever is rotated into a securing position, an end of the securing lever prevents removal of the pivot pin from the rail bore. Rotating the securing lever to a removal position allows the binding to be removed.