A heel unit for an alpine touring binding, comprising a binding body which is suitable for holding a heel portion of an alpine touring shoe in a downhill position of the heel unit and for releasing the heel portion of the alpine touring shoe in an alpine touring position of the heel unit, such that the alpine touring shoe can lift off the heel unit, and a climbing aid which is adjustable between an active position and a passive position, wherein, while in the active position, the climbing aid supports the heel portion of the alpine touring shoe at a predetermined height above a sliding board plane in the alpine touring position of the heel unit, wherein the climbing aid is biased over the entire path of movement thereof into the active position by means of a flexible element and can be locked in the passive position.

A support plate for a binding for a gliding board that includes the following: a chassis to be fixed on an upper surface of the gliding board; a damping plate intended to be at least partially interposed between a lower surface of the chassis and the upper surface of the gliding board. The support plate includes a wedge that is less compressible than the damping plate, movable between a hardness configuration, suitable for transmitting a vertical force from the chassis to the upper surface of a gliding board, and inhibiting, at least partially, the compression of the damping plate and between a flexibility configuration, suitable for the force to be retransmitted from the chassis to the upper surface of a gliding board, mainly via the damping plate.

A fastening assembly for a ski crampon includes a hinge pin having a mounting portion and a securing portion. The mounting portion has a smaller dimension in a first direction and a larger dimension in a second direction, the first and second directions orthogonal to the longitudinal direction of the hinge pin. The securing portion has substantially the same dimension in the first and second directions. A mounting fastening portion defines a gap and an opening. The gap and the opening each extends substantially transversely to a ski longitudinal direction and substantially parallel to the ski surface. The gap receives the mounting portion of the hinge pin, which is inserted through the opening. The dimension of the opening in the ski longitudinal direction is larger than the dimension of the mounting portion in the first direction and smaller than the dimension of the mounting portion in the second direction.

A fastening assembly for a ski crampon includes a hinge pin having a mounting portion and a securing portion. The mounting portion has a smaller dimension in a first direction and a larger dimension in a second direction, the first and second directions orthogonal to the longitudinal direction of the hinge pin. The securing portion has substantially the same dimension in the first and second directions. A mounting fastening portion defines a gap and an opening. The gap and the opening each extends substantially transversely to a ski longitudinal direction and substantially parallel to the ski surface. The gap receives the mounting portion of the hinge pin, which is inserted through the opening. The dimension of the opening in the ski longitudinal direction is larger than the dimension of the mounting portion in the first direction and smaller than the dimension of the mounting portion in the second direction.

Device and methods for a ski assembly system and snowboard assembly system having a ski or snowboard with a centerline axis, a perpendicular axis, and a ski suspension system. The ski or snowboard suspension system has a suspension platform with two or more struts rotatably coupled with the suspension platform and at least one of a front mount assembly and a rear mount assembly.

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.

A ski binding moving mechanism (1) comprising:a ski binding (2a) configured to be fastened in the vertical and lateral direction on a ski, and further configured to be movable in the longitudinal direction relative to the ski;a rod (5) with two or more pushing elements (51a, 51b, . . . ), the rod (5) being fastened to the ski binding (2a); anda rotatable element (32), configured to be fastened fixedly relative to the ski in the longitudinal direction of the ski, the rotatable element (32) being rotatable relative to the ski (6), wherein the rotatable element (32) comprises:a first and a second rotating pin (321, 322) configured to rotate with the rotatable element (32), and cooperate with the pushing elements (51a, 51b, . . . ), whereinthe rotatable element (32) is configured to be rotated at least one revolution and move the rod (5) and the binding (2a) in the same longitudinal direction throughout the revolution.

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.