An improved highback adjustment system for a splitboard boot binding. A captive strut is mounted on the spine of the highback, the strut having a forward lean adjustor block such that rotation or sliding of the block lengthens or shortens the strut. The combination provides a broadly adjustable range of forward lean bias in small increments and the block is readily disengaged and stowed on the highback when not needed. Advantageously, the mechanism that can be operated and adjusted without tools, even with gloved hands, a significant benefit in winter conditions, and does not jam with snow. Methods of use of the improved forward lean adjustor and highback are also disclosed.

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.

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 a snow covered surface and an upturned peripheral region extending around a perimeter of the bottom wall to help facilitate sliding movement of the ski across a snow covered surface in any direction, without preference to a particular direction, and to help inhibit the ski from digging into the snow covered surface when sliding across the snow covered surface. The assembly also includes a mounting feature for coupling a binding to the bottom wall of the ski, such that an individual can position a foot in the binding and use the ski to slide across the snow covered surface.

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 a snow covered surface and an upturned peripheral region extending around a perimeter of the bottom wall to help facilitate sliding movement of the ski across a snow covered surface in any direction, without preference to a particular direction, and to help inhibit the ski from digging into the snow covered surface when sliding across the snow covered surface. The assembly also includes a mounting feature for coupling a binding to the bottom wall of the ski, such that an individual can position a foot in the binding and use the ski to slide across the snow covered surface.

An improved highback adjustment system for a splitboard boot binding. A captive strut is mounted on the spine of the highback, the strut having a forward lean adjustor block such that rotation or sliding of the block lengthens or shortens the strut. The combination provides a broadly adjustable range of forward lean bias in small increments and the block is readily disengaged and stowed on the highback when not needed. Advantageously, the mechanism that can be operated and adjusted without tools, even with gloved hands, a significant benefit in winter conditions, and does not jam with snow. Methods of use of the improved forward lean adjustor and highback are also disclosed.

A snowboard binding includes a baseplate configured to secure to an upper surface of a snowboard a high back and straps secure to the baseplate. A drive plate is secured to the upper surface of the baseplate and has a stiffness effective to change ride properties of the snowboard. The drive plate may include a laminate structure including one or more composite layers such as fiberglass, carbon fiber, aluminum, or titanium. A carriage may mount the drive plate to the snowboard and may define a recess for receiving the drive plate. Tabs may extend from the lower surface of the carriage and engage corresponding apertures in the baseplate. The tabs may have hooked end portions to secure the carriage to the baseplate.

Disclosed herein is a boot frame comprising: a) a base; b) two side supports; c) a toe binding; d) a heel binding; e) an ankle support; f) a calf support; and g) at least one strap configured to secure a boot to the boot frame, wherein the side supports are independently adjustable, and wherein adjusting the side supports allows for a boot to line up at an angle relative to the base.

Disclosed herein is a boot frame comprising: a) a base; b) two side supports; c) a toe binding; d) a heel binding; e) an ankle support; f) a calf support; and g) at least one strap configured to secure a boot to the boot frame, wherein the side supports are independently adjustable, and wherein adjusting the side supports allows for a boot to line up at an angle relative to the base.

The invention consist of a tool-less system applied for adjusting the wrist-strap and the toe-strap on snowboard bindings, where such tool-less system is made up with the combination of 3 elements, 1. It is tool-less so the attachment position of the binding strap can be unlocked from one position on the binding frame and locked into another position fairly easily with bare hands 2. It has a stable locking mechanism based on a profiled press-button/pin element fitting into at least one hole with profiled shape provided in the frame of the binding where also at least one hole provided in the strap(s) will fit in and be securely locked in when the button element is put in place 3. The press-button element is put in place from the inside and prevented from popping out during use also by the boot which blocks the only exit direction for the button element, which is inwards. The wrist-strap will further be prevented from popping out by the highback, which during riding covers the button element holding the wrist-strap in place. The toe-strap may further be prevented from popping out by the base-plate.

The invention consist of a tool-less system applied for adjusting the wrist-strap and the toe-strap on snowboard bindings, where such tool-less system is made up with the combination of 3 elements, 1. It is tool-less so the attachment position of the binding strap can be unlocked from one position on the binding frame and locked into another position fairly easily with bare hands 2. It has a stable locking mechanism based on a profiled press-button/pin element fitting into at least one hole with profiled shape provided in the frame of the binding where also at least one hole provided in the strap(s) will fit in and be securely locked in when the button element is put in place 3. The press-button element is put in place from the inside and prevented from popping out during use also by the boot which blocks the only exit direction for the button element, which is inwards. The wrist-strap will further be prevented from popping out by the highback, which during riding covers the button element holding the wrist-strap in place. The toe-strap may further be prevented from popping out by the base-plate.