A splitboard is a snowboard that splits into two halves. These halves can then be worn similar to cross-country skis (commonly referred to as “touring mode”) to thereby allow the snowboarder to ascend the mountain. After ascending to a desired location, the snowboarder can combine the halves to form a snowboard (commonly referred to as “riding mode”) for descending the mountain.
Interfaces have been developed to allow a “splitboard binding” to be mounted to the splitboard in both touring and riding modes. For touring mode, each half of the splitboard includes a touring bracket to which the front of the splitboard binding is coupled in a pivoting manner. Each splitboard half or the splitboard binding may also include a climbing bar (or heel riser, rest or lock) to provide support when climbing steeper terrain (i.e., when the heel is lifted substantially above the splitboard). For riding mode, two pairs of “pucks” or other structures are mounted on the splitboard so that the splitboard bindings can be coupled across the two halves. Typically, these pucks are configured to allow a slider plate or base plate of the splitboard binding to slide overtop and/or interlock with the pucks. In short, these interfaces allow the splitboard bindings to be quickly and easily moved between the touring and riding modes.
The present invention extends to an interface for enabling a splitboard binding to be mounted to any snowboard. The interface includes a baseplate that includes a disc for mounting the baseplate to a snowboard. The disc is configured to correspond with the common snowboard binding hole patterns to thereby allow the baseplate to be mounted on most snowboards. The interface further includes a puck that is configured to mount to the top surface of the baseplate. The puck is configured to interlock with many types of splitboard bindings. In this way, splitboard bindings can be mounted to a snowboard.
In some cases, the baseplate can include a hole pattern that matches a bolt pattern of a traditional splitboard to thereby allow other providers' pucks/adapters to be coupled to the baseplate. In this way, the present invention can enable many types of splitboard bindings to be mounted to a traditional snowboard.
In some embodiments, the present invention is implemented as an interface for enabling a splitboard binding to be mounted to a snowboard. The interface includes: a baseplate having an opening; a disc configured to insert into the opening in the baseplate, the disc including holes by which the disc can be mounted to a snowboard via a binding hole pattern of the snowboard, the disc being configured to secure the baseplate to the snowboard when the disc is mounted to the snowboard; and a puck that is configured to mount to the baseplate, the puck being configured to receive and secure a splitboard binding.
In other embodiments, the present invention is implemented as an interface for enabling a splitboard binding to be mounted to a snowboard. The interface includes: a baseplate having an opening, the opening including a notched inward facing surface; a disc having a notched outward facing surface that interfaces with the notched inward facing surface, the disc including holes by which the disc can be mounted to a snowboard via a binding hole pattern of the snowboard; and a puck that is configured to mount to the baseplate, the puck being configured to receive and secure a splitboard binding.
In other embodiments, the present invention is implemented as an interface for enabling a splitboard binding to be mounted to a snowboard. The interface includes: a baseplate having an opening, the opening including an inward facing surface; a disc having an outward facing surface that interfaces with the inward facing surface to secure the baseplate to a snowboard when the disc is secured to the snowboard; and a puck that is configured to mount to the baseplate, the puck being configured to receive and secure a splitboard binding.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter.
Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
As introduced in the background, unlike a traditional snowboard binding, a splitboard binding is configured to selectively mount to a splitboard in either the touring or riding mode. Accordingly, to use a splitboard, a snowboarder will not only need to invest in the splitboard itself, but will also need to invest in these specialized splitboard bindings. However, many snowboarders that use a splitboard, or at least those that use splitboard bindings, may still desire to ride their traditional snowboards. The present invention provides a way for snowboarders to use their splitboard bindings on their traditional snowboards.
As shown, baseplate 101 is rectangular in shape (although other shapes could be used) and includes a central opening 101a for receiving disc 103. The inward facing surface 101a1 of opening 101a is notched to correspond with notches in the outward facing surface 103a of disc 103. The circular shape of disc 103 and opening 101a allow disc 103 to be inserted at any rotational position while the corresponding notches prevent baseplate 101 from rotating relative to disc 103 once disc 103 is inserted into opening 101a and mounted to the snowboard.
Disc 103 includes a number of holes 103b that are arranged in patterns that correspond with the various binding hole patterns commonly used on snowboards (e.g., 4×4, 2×4, 3D, Burton Channel, etc). Accordingly, by selecting a disc 103 with the appropriate hole pattern, interface 100 can be mounted to virtually any modern snowboard. Additionally, to allow interface 100 to be used on a vintage snowboard that employs the “5-bolt” hole pattern, each end of baseplate 101 can include arched arrangements of mounting holes 101c (such as is shown in
In
Surface 101a1 of opening 101a is angled outwardly while surface 103a of disc 103 is angled inwardly such that baseplate 101 will be secured to the top surface of the snowboard once disc 103 is mounted. More specifically, as couplers (such as bolts) that extend through holes 103b are tightened into the holes of a snowboard, surface 103a will apply a downward force against surface 101a1 thereby sandwiching baseplate 101 between the snowboard and disc 103. Prior to tightening disc 103 within opening 101a, baseplate 101 can be rotated to a desired orientation relative to the snowboard so that the snowboarder's feet will be properly angled such as is shown in
Puck 102 includes a top surface 102a, a bottom surface 102b, and opposing ledges 102c that extend lengthwise along puck 102. In some embodiments, such as is shown in
Referring to
In some embodiments, holes 101b can be configured to align with a bolt pattern of a traditional splitboard (i.e., in a 3.5 inch by 1 inch pattern). In such embodiments, other providers' pucks/adapters (which have a 3.5 inch by 1 inch bolt hole pattern) can be coupled to baseplate 101/201 in place of puck 102. In this way, baseplate 101/201 can be used to mount the other providers' pucks/adapters to a traditional snowboard.
As shown in
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description.
This application claims priority to U.S. Provisional Patent Application No. 62/542,165 which was filed on Aug. 7, 2017.
Number | Date | Country | |
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62542165 | Aug 2017 | US |