A plate body is configured from a bottom part, a side surface part, and a flange part, and is formed in a concave shape, whereby the thickness of the bottom part of the plate body is reduced and the flexibility of a plate is increased. Reducing the thickness of the bottom part of the plate body reduces the length of screws for attaching a snowboard and prevents the screws from inhibiting the flexibility of the plate.

A pivoting snowboard boot binding including a snowboard assembly, a binding assembly, and a locking mechanism assembly. The snowboard assembly includes a snowboard. The binding assembly includes bindings. The locking mechanism assembly connects said bindings with said snowboard. The locking mechanism assembly has a locked configuration and an unlocked configuration. The bindings can rotate with respect to the snowboard to look forward in the unlocked configuration. The bindings are locked in a predetermined position with the snowboard in the locked configuration.

A pivoting snowboard boot binding including a snowboard assembly, a binding assembly, and a locking mechanism assembly. The snowboard assembly includes a snowboard. The binding assembly includes bindings. The locking mechanism assembly connects said bindings with said snowboard. The locking mechanism assembly has a locked configuration and an unlocked configuration. The bindings can rotate with respect to the snowboard to look forward in the unlocked configuration. The bindings are locked in a predetermined position with the snowboard in the locked configuration.

In one example, a snowboard binding includes a retention and release assembly configured to be mounted to a snowboard, and further includes a retention mechanism operable by a wireless remote control. A boot interface portion of the snowboard binding is configured to releasably engage the retention and release assembly, and the boot interface portion is also configured to releasably retain a boot. In operation, the user can enable release of the boot interface portion from the retention mechanism by activating the wireless remoted control so as to cause the boot interface portion to be unlocked from the retention mechanism.

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.

There is provided herein and improved step in binding having a body and a footplate pivotally coupled therein at the front. A levered high back exposes load arms which are interfaced to the pivotable footplate by way of linkages. When the footplate is depressed, the linkages transition horizontally, thereby increasing rearward force and therefore leverage on the backplate, until substantially horizontally engaged. At this orientation, the linkages experiences little or no vertical vector component thereby preventing inadvertent unbinding.

There is provided herein and improved step in binding having a body and a footplate pivotally coupled therein at the front. A levered high back exposes load arms which are interfaced to the pivotable footplate by way of linkages. When the footplate is depressed, the linkages transition horizontally, thereby increasing rearward force and therefore leverage on the backplate, until substantially horizontally engaged. At this orientation, the linkages experiences little or no vertical vector component thereby preventing inadvertent unbinding.

A mounting device for snowboards and other snow glide boards that includes a puck assembly. The adjustment system can be adjusted with three degrees of freedom with respect to the snowboard: foot placement, foot angle, and heel and toe centering. The puck assembly can attach directly to the snowboard or can be built into the snowboard boot binding. The mounting device can include a slider block/snowboard binding base plate and a disk. The disk includes a series of projections. The slider block/snowboard binding base plate receives the disk in a recess indented in the slider block/snowboard binding base plate top surface. The recess is patterned with a series of detents sized and shaped to receive the projections from the disk. The detents arranged as a series of arcs, of equal radius, translated linearly on even increments. This combination allows for the foot angle and heel and toe centering adjustments to be made concurrently.

A mounting device for snowboards and other snow glide boards that includes a puck assembly. The adjustment system can be adjusted with three degrees of freedom with respect to the snowboard: foot placement, foot angle, and heel and toe centering. The puck assembly can attach directly to the snowboard or can be built into the snowboard boot binding. The mounting device can include a slider block/snowboard binding base plate and a disk. The disk includes a series of projections. The slider block/snowboard binding base plate receives the disk in a recess indented in the slider block/snowboard binding base plate top surface. The recess is patterned with a series of detents sized and shaped to receive the projections from the disk. The detents arranged as a series of arcs, of equal radius, translated linearly on even increments. This combination allows for the foot angle and heel and toe centering adjustments to be made concurrently.

Some aspects include a ski binding system using controllable electromagnets, alone or in combination with permanent magnets, as means of attaching or releasing a ski boot to a ski during use. Some aspects include a ski binding system using a controllable solenoid. In some aspects, microprocessor-based control releases binding electronically based on input from sensors located in binding, ski and/or boot, as well as in other equipment or clothing connected to them or to skier, or binding releases when a mechanical threshold is overcome. In some aspects, sensor data are recorded for analysis of system performance and for adjustment and improvement of system parameters based on data analytics.