A snowboard binding (6) has an adjustably positioned toe ramp (44) mounted to the front end (32) of the base (18) with an upwardly curving front portion (62) shaped to conform to the toe (14) of the boot sole (12) to increase the toe-side edge responsiveness. A dampened, energy absorbing heel pad (66) is mounted to the rear end (28) of the base to help absorb impact. Arm channels (84,86) are formed in each of the left and right side flanges (22,24), extend upwardly from the baseplate (20), and are sized to contain the left and right mounting arms (94,96) of a heel support (26). A pair of threaded fasteners (104,108) clamp the mounting arms within the side flanges over a range of upwardly and rearwardly extending portions. Front-and-rear forces on the heel support are resisted by the two fasteners and by engagement of the upper and lower edges (122,124) of the arms with upper and lower channel walls (88,89). Lateral forces exerted by the heel support on the base are effectively resisted by this channeled side flange construction.

A binding for snowboards has a back plate 2 at the rear of a base plate 1, and the back plate 2 is moved back and forth to vertically move side plates 3 which are provided with an ankle strap 32 and a toe strap 33.

An improved snowboard binding (6) has an adjustably positioned toe ramp (44) mounted to the front end (32) of the base (18) with an upwardly curving front portion (62) shaped to conform to the toe (14) of the boot sole (12) to increase the toe-side edge responsiveness. A dampened, energy absorbing heel pad (66) is mounted to the rear end (28) of the base to help absorb impact. Arm channels (84,86) are formed in each of the left and right side flanges (22,24), extend upwardly from the baseplate (20), and are sized to contain the left and right mounting arms (94,96) of a heel support (26). A pair of threaded fasteners (104,108) clamp the mounting arms within the side flanges over a range of upwardly and rearwardly extending portions. Front-and-rear forces on the heel support are resisted by the two fasteners and by engagement of the upper and lower edges (122,124) of the arms with upper and lower channel walls (88,89). Lateral forces exerted by the heel support on the base are effectively resisted by this channeled side flange construction.

A device for retaining a boot on a gliding board having a base with an upper surface and a lower surface, at least one cavity being provided in the thickness of the base between the upper surface and the lower surface to house a pad. The pad projects at least partially with respect to the upper surface when it is housed in the cavity. The device has an arrangement allowing a removable fastening of the pad in the cavity.

A harness system for a snowshoe employs a single strap and a single buckle to secure the boot to the snowshoe at two locations, one approximately at the arch and one at the toe. The single strap is secured to four points on the harness assembly, left and right sides of each of two flexible harness shells which engage both sides of the boot approximately in the arch and toe areas. Extending generally in a Z-shaped pattern in one embodiment, the strap is fixed at its one end and secured firmly but adjustably at its opposite end. At the two intermediate attachment points are sliding connections to anchoring devices at the ends of the harness legs. One of these sliding attachments may be on a buckle which is releasable, to release the strap from the boot. The harness assembly has the advantages of single-hand engagement and release, one-step engagement and release involving a single buckle, simpler assembly, and mechanical advantage in tightening the strap for adjustment or in engaging the over-center buckle.