Splitboard binding systems including a binding that may be attached to either a left or right gliding board in a ski mode or to both gliding boards in a snowboard mode. The binding includes left and right bottom rails attached to the bottom surface of a base plate, which define channels for slidable attachment to “pucks” disposed on the gliding board in snowboard mode. Each rail has a circular bore at a forward end for attachment to a counterpart pivot pin on a ski mode toe bracket in a ski mode by a sideways movement. A securing lever is disposed on an upper surface of the toe bracket. When the securing lever is rotated into a securing position, an end of the securing lever prevents removal of the pivot pin from the rail bore. Rotating the securing lever to a removal position allows the binding to be removed.

The present disclosure relates to splitboard bindings. The splitboard bindings can be used to change a splitboard between a snowboard for riding downhill in a ride mode and touring skis for climbing up a hill in a tour mode. The bindings can have a first interface and a second interface configured to engage and disengage. The interfaces can be configured such that a binding has large clearances for easy transitions. The first interface can be configured with a locking mechanism. The second interface can be configured to remove large clearances between the first interface and second interface, when the locking mechanism of the first interface is engaged with the second interface, allowing the first interface to attach tightly to the second interface and splitboard to improve the ride of the splitboard.

The present disclosure relates to splitboard bindings. The splitboard bindings can be used to change a splitboard between a snowboard for riding downhill in a ride mode and touring skis for climbing up a hill in a tour mode. The bindings can have a first interface and a second interface configured to engage and disengage. The interfaces can be configured such that a binding has large clearances for easy transitions. The first interface can be configured with a locking mechanism. The second interface can be configured to remove large clearances between the first interface and second interface, when the locking mechanism of the first interface is engaged with the second interface, allowing the first interface to attach tightly to the second interface and splitboard to improve the ride of the splitboard.

A plate body is configured from a bottom part, a side surface part, and a flange part, and is formed in a concave shape, whereby the thickness of the bottom part of the plate body is reduced and the flexibility of a plate is increased. Reducing the thickness of the bottom part of the plate body reduces the length of screws for attaching a snowboard and prevents the screws from inhibiting the flexibility of the plate.

A plate body is configured from a bottom part, a side surface part, and a flange part, and is formed in a concave shape, whereby the thickness of the bottom part of the plate body is reduced and the flexibility of a plate is increased. Reducing the thickness of the bottom part of the plate body reduces the length of screws for attaching a snowboard and prevents the screws from inhibiting the flexibility of the plate.

The present invention relates to a set of coupling assemblies comprising a right coupling assembly and a left coupling assembly being configured to be mounted on aboard for board sports and to receive respectively a right boot and a left boot, wherein the right and left coupling assembly comprise an inner receiving unit and outer receiving unit, wherein each inner receiving unit comprises a locking arm which is pivotable about a main inner pivot axis from a locked position to a released position and vice versa, wherein each inner receiving unit comprises a pull mechanism comprising:—at least one elongate interlink member which extends between the two inner receiving units, and—a link pull member configured to engage the boot or the inner boot coupling part and to receive a pull force from the boot or boot coupling part when the boot or boot coupling part is no longer held by the coupling assembly and moves away from the coupling assembly, and to be pulled over a pull distance by said boot or by the boot coupling part, wherein the pull mechanism is configured to transfer the pull force and the pull distance to the at least one elongate interlink member, and to convert the pull distance in an interlink pull distance of the elongate interlink member, and wherein said interlink pull distance pivots the locking arm of the other coupling assembly from the locking position to the released position, thereby releasing the other boot.

The present invention relates to a set of coupling assemblies comprising a right coupling assembly and a left coupling assembly being configured to be mounted on aboard for board sports and to receive respectively a right boot and a left boot, wherein the right and left coupling assembly comprise an inner receiving unit and outer receiving unit, wherein each inner receiving unit comprises a locking arm which is pivotable about a main inner pivot axis from a locked position to a released position and vice versa, wherein each inner receiving unit comprises a pull mechanism comprising:—at least one elongate interlink member which extends between the two inner receiving units, and—a link pull member configured to engage the boot or the inner boot coupling part and to receive a pull force from the boot or boot coupling part when the boot or boot coupling part is no longer held by the coupling assembly and moves away from the coupling assembly, and to be pulled over a pull distance by said boot or by the boot coupling part, wherein the pull mechanism is configured to transfer the pull force and the pull distance to the at least one elongate interlink member, and to convert the pull distance in an interlink pull distance of the elongate interlink member, and wherein said interlink pull distance pivots the locking arm of the other coupling assembly from the locking position to the released position, thereby releasing the other boot.

A downhill snow ski sound system comprises a speaker coupled to a binding of a snowboard or ski. An orifice is located at a perimeter of the binding and a strap is coupled to and extends from the orifice. The speaker is releasably coupled to the binding by the strap. The speaker is positioned adjacent the binding with less than an inch between the speaker and the binding. The speaker is also positioned directly on and contacting the ski-board.

A downhill snow ski sound system comprises a speaker coupled to a binding of a snowboard or ski. An orifice is located at a perimeter of the binding and a strap is coupled to and extends from the orifice. The speaker is releasably coupled to the binding by the strap. The speaker is positioned adjacent the binding with less than an inch between the speaker and the binding. The speaker is also positioned directly on and contacting the ski-board.