A system, configuration, and method for converting a pair of skis to perform as an emulation snowboard is provided. The system includes a pair of skis, and a coupling device including a platform having an upper planar surface with a plurality of mounting locations with mounting system therein. The mounting system couples the skis together and provides a surface on which a pair of bindings may be affixed. The steps for conversion include providing a pair of skis, removing a ski binding from each ski in the pair of skis, if a binding is installed on either ski in the pair of skis, providing a platform with a mounting system, utilizing the mounting system to affix the platform to each ski in the pair of skis, and attaching a pair of snowboard bindings to the platform.

A system, method and apparatus for a digitally Controlled Variable Stiffness item of athletic equipment, such as a Ski, Snowboard, and Boots. A core of thermally responsive metal alloy, such as Nitinol is disposed within the athletic equipment. A thermal control module and controller permit the athlete to program the athletic equipment to a desired stiffness parameter. The controller may include an app operable via a mobile computing device in communication with the thermal control module.

A system, method and apparatus for a digitally Controlled Variable Stiffness item of athletic equipment, such as a Ski, Snowboard, and Boots. A core of thermally responsive metal alloy, such as Nitinol is disposed within the athletic equipment. A thermal control module and controller permit the athlete to program the athletic equipment to a desired stiffness parameter. The controller may include an app operable via a mobile computing device in communication with the thermal control module.

In described embodiments, a snowboard conversion kit includes a first strap assembly having a first hollow strap sleeve having a first end, a second end, distal from the first end, and a cutout between the first end and the second end. A first strap has a first strap end that extends into the first hollow strap sleeve from the first end and a second strap end that extends into the first hollow strap sleeve from the second end. The first strap and the first strap sleeve form a loop. A first strap securing assembly is adapted to extend through the first hollow strap sleeve and secure the first hollow strap sleeve to a snowboard. A second strap assembly, similar to the first strap assembly is also provided.

Provided is a snowboard binding in which a stopper function operates when a boot is removed and the stopper function is released when a boot is mounted, and a stopper device for a snowboard binding. The snowboard binding is provided with an urging body for rotatably urging a highback rearward, and configured so that when a lock lever of a lock mechanism is placed in an unlocked state by the rotational urging of the urging body, the highback automatically rotates rearward, and configured so that when the highback arrives at the rearward-rotation-limit position or near the rearward-rotation-limit position, a connecting cord of the lock mechanism is tensioned, the orientation in which the lock lever projects from the highback rear surface section is maintained, and the lock lever in this projecting orientation makes contact with the snow surface below a snowboard to bring about a slide-preventing effect.

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.

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.

A binding strap assist mechanism. The binding strap assist mechanism can be retrofitted onto standard snowboard binding straps to bias the binding straps into the open configuration, thus guiding the straps way from the foot area of the binding. Binding straps pass through the binding strap assist mechanism so that tensile forces along the length of each of these binding straps during use is not significantly conveyed to the binding straps assist mechanism. The tensile forces are thus isolated to the binding straps which are intended to carry such forces. The present invention provides a safe and convenient feature to snowboard bindings and other bindings. If the binding strap assist mechanism breaks or fails to function, the binding straps will continue to function as normal, resulting in no safety concerns to user.

Described herein include various embodiments of a binding assembly that assist with coupling a user's foot to a sport board. A foothold or binding upper that captures a user's foot can be coupled to a part of the binding assembly thereby enabling the binding assembly to secure the user's foot to the sport board. The binding assembly can include a chassis that has at least two connector receptacle that each allow an attachment feature (e.g., mounting screw) to extend therethrough and secure the binding assembly to the sport board. Each of the connector receptacles can be angled such that a longitudinal of the connector receptacle is positioned at an angle relative to a top surface of the sport board.

A method for providing at least one component of a snowboard binding, comprising the steps consisting in: using a material of the SMC (Sheet Molding Compound) type, constituted by discontinuous fibers of carbon or glass or hybrid, arranged randomly and interposed between two layers of polymeric resin; arranging the material in a mold for a step of pressure molding by means of metallic mold parts; performing the pressure molding step at a temperature and a pressure that are higher than the ambient values, with a low or high flow of material to fill the cavity of the mold; extracting the component from the mold.