A ski binding with a binding element mounted displaceably on a slide rail arranged on a ski and which can be fixed in different positions by a latching device, wherein the latching device has latch elements which engage in each other in a blocking position on the binding and ski sides, and the binding-side latch element has a pivotable lever element, that in a displacement position the latch elements are not in engagement with each other, wherein the binding element has an operating element with an oblique run-on surface which is can be transferred between open and closed positions, wherein the operating element, upon transfer of the operating element to the open position, cooperates with an oblique contact surface of the lever element such that the lever element is moved out of the blocking position.

A snow ski has a longitudinal body defining a sole for gliding on the snow. The ski includes: (a) a platform slidably coupled to the body for sliding longitudinally relative to the body; and (b) a gripping element slidably and rotatably coupled to the body and rotatably coupled to the platform. The gripping element extends downward to penetrate the snow in response to the platform being slid rearward relative to the body. The gripping element retracts upward above the sole when the platform is slid forward relative to the body. First and second gripping elements may be disposed on opposing sides of the body. A locking mechanism selectively locks the platform at a forward position, in which the gripping element is retracted, one or more intermediate positions, or a rearward position in which the gripping element extends to penetrate the snow. A ski-traction kit for retrofitting a ski is provided.

A snow ski has a longitudinal body defining a sole for gliding on the snow. The ski includes: (a) a platform slidably coupled to the body for sliding longitudinally relative to the body; and (b) a gripping element slidably and rotatably coupled to the body and rotatably coupled to the platform. The gripping element extends downward to penetrate the snow in response to the platform being slid rearward relative to the body. The gripping element retracts upward above the sole when the platform is slid forward relative to the body. First and second gripping elements may be disposed on opposing sides of the body. A locking mechanism selectively locks the platform at a forward position, in which the gripping element is retracted, one or more intermediate positions, or a rearward position in which the gripping element extends to penetrate the snow. A ski-traction kit for retrofitting a ski is provided.

The present invention concerns a system for optional dynamic positioning of a ski binding (2) or parts of this, on or in a ski during use. The invention is characterized in that the system comprises an electrical actuator (6), an energy source (7) in order to run the electrical actuator, in addition to a control system (8) adapted to control the electrical actuator.

The present invention concerns a system for optional dynamic positioning of a ski binding (2) or parts of this, on or in a ski during use. The invention is characterized in that the system comprises an electrical actuator (6), an energy source (7) in order to run the electrical actuator, in addition to a control system (8) adapted to control the electrical actuator.

A heel unit apparatus for a ski touring binding is disclosed which comprises a body mounted on a support, the body being rotatable relative to the support on a vertical axis. The body comprises a resilient element movable within the body which when pre-loaded under compression or tension, exerts forces in opposing directions. The body also comprises at least one forward connector moveable between resting and release positions for releasably connecting the body to the heel of a footwear and a My linkage between the resilient element and the at least one forward connector configured such that force exerted in one of the opposing directions resists movement of the at least one forward connector from the resting position to the release position. The resilient element, the at least one forward connector and the My linkage cooperate to resist forward release. The body further comprises a Mz linkage between the resilient element and a resting surface on the support configured such that the force in the other of the opposing directions presses against the resting surface to resist rotation of the body about the support. The resilient element, the Mz linkage and the body cooperate to resist lateral release. Shocks independently affecting the My and the Mz linkages do not significantly lessen resistance to Mz and My release, respectively.

This disclosure pertains to a toe unit for engaging a footwear toe of a footwear to releasably fasten the footwear toe to a snow travel aid. The toe unit comprises: a base for mounting on the snow travel aid; a slider slidably mounted on the base, the slider operably configured to resiliently slide laterally upon the base and away from a central position in response to a lateral force; opposable jaws mounted on the slider, wherein the jaws are moveable between an open and a closed position to releasably engage respective sides of the footwear toe in the closed position in order to fasten the footwear toe to the snow travel aid and to permit pivotal movement of the footwear about an axis intersecting the jaws. The opposable jaws are operable to move from the closed position to the open position independent of displacement of the slider from the central position in response to torque generated by rotation of the footwear about the footwear toe.

A brake arrangement for a touring binding, adjustable between a braking position and a sliding position. The brake arrangement includes a base having a fastening arrangement for fastening to one or more of a ski or the touring binding, a pedal having a step surface for a shoe on a side of the pedal facing away from the ski, at least one brake arm mounted on the base and on the pedal, at least one first resilient element configured to preload the brake arrangement into the braking position, and a locking element that is movable between an engaged position and a disengaged position. The locking element, in the engaged position, is designed to lock the brake arrangement in the sliding position. The locking element may be preloaded into the engaged position. The brake arrangement may include a blocking element that is adjustable between a blocking position and a release position.

A toe piece for a device for fastening a boot on a sliding board, having a base (130; 3) intended to be fixed to the sliding board, two lateral jaws (101; 8, 9), each mounted to be rotationally mobile on the base (130; 3) about a substantially vertical rotation axis (103; 10, 11), so as to occupy a closed position to hold a boot and a separated position to release or receive a boot, and a pusher (110; 35) having two lateral trig surfaces (114; 24, 25) each cooperating with a respective ramp (104; 22, 23) of each jaw (101; 8, 9), this pusher being linked to the base by a trig spring (112; 36), and two links (120; 28, 29) each linked to a jaw by a first lateral axis (123; 14, 15) and linked together by at least one central axis (125; 32).

A toe piece for a device for fastening a boot on a sliding board, having a base (130; 3) intended to be fixed to the sliding board, two lateral jaws (101; 8, 9), each mounted to be rotationally mobile on the base (130; 3) about a substantially vertical rotation axis (103; 10, 11), so as to occupy a closed position to hold a boot and a separated position to release or receive a boot, and a pusher (110; 35) having two lateral trig surfaces (114; 24, 25) each cooperating with a respective ramp (104; 22, 23) of each jaw (101; 8, 9), this pusher being linked to the base by a trig spring (112; 36), and two links (120; 28, 29) each linked to a jaw by a first lateral axis (123; 14, 15) and linked together by at least one central axis (125; 32).