A brake arrangement for a touring binding adjustable between a braking position and a sliding position, including: a base having a fastening arrangement; a pedal; at least one brake arm mounted on the base and on the pedal; at least one first resilient element to preload the brake arrangement into the braking position; a locking element that is linearly displaceable along a longitudinal direction of the ski to adjust between an active position, which locks the brake arrangement in the sliding position, and a passive position; and an actuating element mounted on the brake arrangement pivotable about a pivot access, the actuating element adjustable between a locking position, where the locking element is set into the locking position, and a release position, where the locking element is set into the passive position, and wherein a pivoting movement of the actuating element causes a linear movement of the locking element.

A front unit for a touring binding, comprising: two lateral bearing portions arranged on a ski transverse axis, wherein, when the front unit is in a closed position, the two lateral bearing portions are configured to engage lateral counter bearing portions of a ski boot to hold the ski boot on the front unit so that the ski boot can pivot about the ski transverse axis; and a longitudinal positioning portion on which the ski boot can be supported, wherein the counter bearing portions are positioned for engagement relative to the bearing portions, the front unit being shiftable between an open position and the closed position, wherein the bearing portions and the counter bearing portions are disengaged in the open position and engaged in the closed position, wherein the longitudinal positioning portion, relative to the bearing portions, is secured in the open position and movable in the closed position.

Some aspects include a ski binding system using controllable electromagnets, alone or in combination with permanent magnets, as means of attaching or releasing a ski boot to a ski during use. Some aspects include a ski binding system using a controllable solenoid. In some aspects, microprocessor-based control releases binding electronically based on input from sensors located in binding, ski and/or boot, as well as in other equipment or clothing connected to them or to skier, or binding releases when a mechanical threshold is overcome. In some aspects, sensor data are recorded for analysis of system performance and for adjustment and improvement of system parameters based on data analytics.

Some aspects include a ski binding system using controllable electromagnets, alone or in combination with permanent magnets, as means of attaching or releasing a ski boot to a ski during use. Some aspects include a ski binding system using a controllable solenoid. In some aspects, microprocessor-based control releases binding electronically based on input from sensors located in binding, ski and/or boot, as well as in other equipment or clothing connected to them or to skier, or binding releases when a mechanical threshold is overcome. In some aspects, sensor data are recorded for analysis of system performance and for adjustment and improvement of system parameters based on data analytics.

Some aspects include a ski binding system using controllable electromagnets, alone or in combination with permanent magnets, as means of attaching or releasing a ski boot to a ski during use. Some aspects include a ski binding system using a controllable solenoid. In some aspects, microprocessor-based control releases binding electronically based on input from sensors located in binding, ski and/or boot, as well as in other equipment or clothing connected to them or to skier, or binding releases when a mechanical threshold is overcome. In some aspects, sensor data are recorded for analysis of system performance and for adjustment and improvement of system parameters based on data analytics.

Some aspects include a ski binding system using controllable electromagnets, alone or in combination with permanent magnets, as means of attaching or releasing a ski boot to a ski during use. Some aspects include a ski binding system using a controllable solenoid. In some aspects, microprocessor-based control releases binding electronically based on input from sensors located in binding, ski and/or boot, as well as in other equipment or clothing connected to them or to skier, or binding releases when a mechanical threshold is overcome. In some aspects, sensor data are recorded for analysis of system performance and for adjustment and improvement of system parameters based on data analytics.

A binding having a front plate (2), a front assembly (3) for immobilising the boot and capable of cooperating with the sole (81) of the boot (8), a rear assembly (6) for retaining the boot and capable of cooperating with a retaining lug (85) of the rear portion of the front sole and/or with the rear sole, the rear assembly being movable relative to the front plate in the vertical plane, and tensioning means (66) which act between the rear retaining assembly (6) and the ski and/or the front plate (2) and which are capable of tensioning the boot (8) on the binding (1) and enabling the heel to be raised freely. The front immobilisation assembly is mounted in a floating manner on the front plate about a transverse pivot axis (A3), the supporting point enabling the front end (81′) of the sole (81) of the boot.

A binding having a front plate (2), a front assembly (3) for immobilising the boot and capable of cooperating with the sole (81) of the boot (8), a rear assembly (6) for retaining the boot and capable of cooperating with a retaining lug (85) of the rear portion of the front sole and/or with the rear sole, the rear assembly being movable relative to the front plate in the vertical plane, and tensioning means (66) which act between the rear retaining assembly (6) and the ski and/or the front plate (2) and which are capable of tensioning the boot (8) on the binding (1) and enabling the heel to be raised freely. The front immobilisation assembly is mounted in a floating manner on the front plate about a transverse pivot axis (A3), the supporting point enabling the front end (81′) of the sole (81) of the boot.

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); and—a 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, . . . ), wherein—the 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 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); and—a 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, . . . ), wherein—the 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.