The fastening device (3) for fastening a boot (4) to a sliding board (2) includes a base (10) intended to be fastened to a sliding board and to surround, at least partially, a sole and lateral sides of a boot, at least one lever (201, 301) that can move relative to the base and can interact with a retention element (44A, 44B) connected to a boot, the lever (201, 301) being able to move between a first retention position (P1) and a second clamping position (P2), the lever being able to retain the boot in the base when it is in its first position, the lever being able to transmit a downward force on the retention element when it is in its second position.

The present invention relates to a snowboard binding for coupling a snowboard shoe to a snowboard, comprising a baseplate, which is designed to be attached by means of a fastening device to a snowboard and to sit flat against same, a highback, which extends substantially perpendicularly to the baseplate, a toe strap, and an instep strap. The snowboard binding according to the invention is formed in two parts, wherein the baseplate and the toe strap are associated with a first module and the highback and the instep strap are associated with a second module. A coupling unit is provided, by means of which the first module and the second module can be releasably coupled to one another, the first module being designed to remain on the snowboard in a decoupled state and the second module being designed to remain on the snowboard shoe in the decoupled state.

A binding apparatus for a snowboard is provided including a base plate having a pivot portion, an elongate arm member, and a cuff member for receiving a portion of a rider's boot or leg. The base plate may be affixed to the snowboard such that a boot may be coupled to a footbed thereof at an angle relative to the lateral axis of the snowboard. The elongate arm member is pivotably coupled to the pivot portion of the base plate at a first end portion thereof, and the cuff member is coupled to the elongate arm member. The elongate arm member is configured to pivotably rotate about an axis of rotation of the pivot portion such that the elongate arm member and cuff member coupled thereto are capable of moving fore and aft of a lateral axis of a snowboard.

The fastening device (3) for fastening a boot (4) to a sliding board (2) includes a base (10) intended to be fastened to a sliding board and to surround, at least partially, a sole and lateral sides of a boot, at least one lever (201, 301) that can move relative to the base and can interact with a retention element (44A, 44B) connected to a boot, the lever (201, 301) being able to move between a first retention position (P1) and a second clamping position (P2), the lever being able to retain the boot in the base when it is in its first position, the lever being able to transmit a downward force on the retention element when it is in its second position.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

An apparatus for gliding over snow is disclosed. The apparatus comprises at least two decks coupled via a swivel arm. Each deck comprises a strap to receive a foot of a user, and a board coupled to the deck via a connector. The user stands on the decks to create swivel-motion with the help of the swivel arm. The swivel-motion created at the deck is transferred to the connector and to the board to create forward momentum and glide the board over the snow.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

A snowboard boot and binding system is disclosed which facilitates the engagement and disengagement of a snowboard boot and binding. The snowboard boot may include a boot engagement member extending from a rear of the boot. The boot engagement member is moved downwardly into a corresponding binding engagement member to provide an arrangement which prevents forward movement of the boot. The boot engagement member also may include one or more serrations to engage with one or more pawls on the binding to prevent upward movement of the boot. A snap-in arrangement may be provided in a boot toe region. The boot has protrusions extending outwardly from each side of the boot to engage with catches on the binding sidewalls. As the boot is pressed downwardly into the binding, the protrusions splay the catches until reaching recesses, at which point the catches rebound to capture the protrusions against upward movement.

The present invention contemplates a binding system for a snowboards and the like. The system includes a soft-soled boot having a hardened exterior shell consisting of a toe portion and a heel portion, which are linked by at least one sidewall portion. The toe and heel portions include two toe and two heel pegs respectively. The boot includes an instep portion having instep cables for adjusting the boot to the wearer and the cables are adjusted by grommets and tightened in position by at least one resting bar. The binding has a base plate for connecting to the snowboard. The base plate further supports a pair of toe hooks adapted to engage the toe pegs and a pair of heel peg levers adapted to releasably engage the heel pegs of the boot. A grappling hook and ratchet mechanism grabs the resting bar on the boot.