A Method and apparatus for reducing stress on the body (e.g., foot, ankle, hip, spine) of a snowboarder while sitting on a chairlift. The apparatus includes a boot binding assembly adapted for mounting on the top surface of a snowboard including a boot retention member hinged for movement between a dosed position and an open position. For typical downhill snowboarding activity, a user will place the retention member in the closed position to orient the sole of the user's boot substantially parallel, i.e. against the snowboard top surface. For sitting on a chairlift, the user will place the retention member in the open position so as to allow the snowboard to pivot around the hinge and hang substantially vertically from the retention member thus avoiding stressful torques on the user's supporting limb.

A system for securing a snowboard binding to a snowboard may be an intermediary between the snowboard binding and the snowboard. In some embodiments, the system includes an expandable snowshoe attachment device. The system for securing a snowboard binding to a snowboard may include an upper piece and one or more lower pieces. The upper piece may be configured to attach to a lower surface of a baseplate of a snowboard binding. The one or more lower pieces may be rails. The rails may be fastened to a snowboard. The upper piece may include one or more extensions. The one or more extensions may deploy to increase a bottom surface area of the upper piece. Increasing the bottom surface area of the upper piece may increase the flotation of the upper piece on surfaces such as snow.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider’s steering foot causes counter-rotation of a steering fin under the rider’s steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider’s non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider’s steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.

A sport board binding system includes a receiver configured to be secured to a deck of a sport board, a boot, and an intermediate locking member. The receiver defines a channel extending inward from a periphery of the receiver. The boot is configured to be worn by a user and includes an engagement mechanism. The intermediate locking member includes a lower head connected to an upper head by way of a neck with the lower head selectively housed within the channel of the receiver and the upper head selectively housed within the engagement mechanism of the boot.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.

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 steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.

A system for securing a snowboard binding to a snowboard may be an intermediary between the snowboard binding and the snowboard. In some embodiments, the system includes an expandable snowshoe attachment device. The system for securing a snowboard binding to a snowboard may include an upper piece and one or more lower pieces. The upper piece may be configured to attach to a lower surface of a baseplate of a snowboard binding. The one or more lower pieces may be rails. The rails may be fastened to a snowboard. The upper piece may include one or more extensions. The one or more extensions may deploy to increase a bottom surface area of the upper piece. Increasing the bottom surface area of the upper piece may increase the flotation of the upper piece on surfaces such as snow.

A steering system for a snowboard includes two binding interface pods, one of which may be active and one of which may be passive. Rotation or tilting of a top plate of the active binding interface pod in response to rotation or tilting of the rider's steering foot causes counter-rotation of a steering fin under the rider's steering foot. The passive binding interface pod is responsive via a linkage between the active and passive binding interface pods to cause rotation of a steering fin under the rider's non-steering foot. Coordinated counter-rotation of the steering fins causes the board to turn in the direction of rotation of the rider's steering foot when the steering fins are unaligned. Optionally, both binding pods may be active in steering, i.e. enabling two footed steering.