BACKGROUND
This invention relates to the field of devices that traverse over snow, ice, and colder climates of the earth in a climbing or sliding fashion. Namely, boot retention devices otherwise known in the field as boot bindings, binding plates, mounting plates, mounting bases, snowboard boot bindings, touring ski bindings, soft shelled boot bindings, approach ski bindings, and the like and especially those meant for selective free heel touring and lock heel sliding positions for ski shaped touring devices. This invention also relates to binding assemblies oriented mainly for soft shelled boots that serve a touring mode with which the user may move in a walking motion while connected to the device and may also secondarily connect to a sliding device such as a ski or touring device like a split ski/board device using a snowboard boot binding though hard-shell boots could also be used in some embodiments. Touring boot binding systems are used for retaining a boot to a particular device for traversing over snow and ice covered terrain in a walking fashion. These boot binding systems need to be very versatile to be selectively placed on the ski touring device in a touring walking or telemark or cross-country mode or in an additional mode for lock heel sliding. Split-boards and/or touring snowboards require a touring binding assembly and separate mounting plate adaptors for attaching all manner of snowboard bindings to the adaptor plates. The adaptor plates selectively allow a touring position for a cross-country style ascension mode and a secondary mode to selectively lock the mounting plate adaptor position for sliding down hill. The user mounts a separate snowboard binding assembly and snowboard boot binding base to the mounting plate assembly which costs a lot and weighs a lot. When the touring binding base plate adaptor is mounted to the system it has the selective ability to pivot allowing a walking motion.
Said prior art also has the ability to accept standard issue snowboard binding systems using three hole and four hole mounting disks. Additionally, the mounting plate, in one prior art embodiment may optionally change from a walking pivot binding position by a quick-release axle located at a toe region on the base plate adaptor to a fixed non-walking “sliding” position by simply selectively reconnecting the base plate adaptor at a region between the heel and toe region of the base plate portion of the touring binding system in which the footwear touring pivot is stopped.
The present invention overcomes the prior art by offering a snowboard boot binding that has a quick-release axle from a ski touring dive interface without having to use a separate adaptor to form a touring mode for the binding. In other words the snowboard boot binding is the adaptor touring/locked heel interface and the boot rests directly upon its supporting structures with straps securing the boot to the said binding multiple mode interface. The snowboard boot binding interface in this disclosure is called a mounting plate, mounting base, binding, and the like.
FIELD
This invention relates to the field of selective pivot touring binding systems especially mounting plates, mounting bases, used on ski systems, split-ski device type systems, cross-country ski systems, snowshoe systems, and touring ski/board device systems able to transition the boot binding to a variety of ride modes without the need of an adaptor plate used in the prior art.
DESCRIPTION OF THE RELATED ART
Touring skis, split-boards, and touring snowboards in general have a specific binding plate/base or mounting plate/base adaptor which is a separate piece from the snowboard binding assembly and a secondary base plate. These snowboard binding assemblies may or may not include straps mounted to the base and the snowboard binding base mounted to the mounting plate adaptor. The straps typically have ratchets buckles for adjusting different boot sizes within the binding assembly. Skis also have a mounting plate for boots or hard shell boots. Some manufacturers have binding configurations to accept soft shelled boots. In some instances strapless systems are used for a hands free step-in type engagement to the device for riding on some ski touring devices.
In the current state of the art, boot mounting plates for touring skis, touring snowboards, and split-ski/boards are all limited by cumbersome binding systems which have complex hardware, a multitude of parts, adaptors, and adaptor interfaces that take up space, weight, money, and time. Furthermore, the current state of the art does not provide a snowboard boot binding that has material removed to reduce the weight of the mounting plate and make the boot sole visible through a window in the mounting plate.
All current touring ski systems and touring snowboard systems have a complex binding set-up that is heavy and most importantly takes up too much space and is too expensive. There also lacks a snowboard boot binding system that can allow selective touring ski pivots wherein the adaptor is part of the device binding as one unit and universally accepted on a ski, snowshoe, split-ski/board combination type devices and the like. Some prior art mounting plates/bases for a boot to rest on consists of a single pivot axis for walking in a touring mode and it is typically fixed so that the touring mode can never unlock releasing the binding from the touring position in a quick-release fashion. However, some touring snowboard bindings have a “short” quick-release touring axle which releases an adaptor plate. The prior art snowboard touring systems teach a standard utility which uses a standard 3 or 4 hole disk used in most snowboard binding boot mounting systems. Furthermore selectively connected to the adaptor plate with the use of tools and screws/bolts is the said snowboard binding assembly with straps and a separate binding base plate or hard shell ski binding which are to be connected to the mounting plate adaptor. Many boot attaching systems or boot mounting devices may be used in place of straps to couple the boot to the mounting plate. However, it must be noted that the prior art of soft shelled boot touring has not produced a mounting plate that includes front and rear strap portions connected directly to the mounting plate unit for retaining soft shelled boots when touring including a releasable touring axle pivot pin for multiple travel modes in and out of the binding directly. Additionally the prior art snowboard boot touring bindings have not produced a mounting plate interface that the snowboard boot can be mounted directly on. Furthermore, prior art snowboard boot bindings have not produced a boot bed with a boot sole window allowing the boot bottom to be visible through the boot bed when the boot is mounted to the boot bed.
There is also a need in the art of winter ski touring and snowboard touring to provide a touring snowboard boot binding mounting plate/base which has the ability to connect and disconnect at the toe region of the snowboard boot binding mounting plate so that the binding mounting plate can be separated from the device and can be reconnected to the device or separate device between the toe and the heel region of the snowboard boot binding base “directly” eliminating the need for a separate interfaces or plates to achieve, free heel walking position, a locked heel stance, or non-pivotal gliding stance or transition mode. The snowboard boot binding mounting base/plate could be used on quick connection interfaces of a snowshoe, ski, snowboard, or split-ski/board type devices and except soft shelled boots. In further embodiments, the boot bed or mounting plate may be mounted over two configurable ski sections. In further embodiments a hard shelled boot may also be used in a separate configuration or embodiment or even a strapless step-in system with the mounting plate design. There is also a need for a touring snowboard boot binding system and mounting base that is very compact and light weight and very easy to use and manufacture. Additionally, a need exists for a binding that is very sturdy and strong but remains light weight and can be utilized on split-ski/board, snowboard, touring ski, telemark ski, separate climbing cleat, or snowshoe or hybrid devices using a boot bed interface in the form of a snowboard boot mounting plate.
What is also needed is a snowboard boot binding base boot-bed structure that is selectively connected to the axle pin axis eliminating the need of snowboard boot binding adaptor plates. Additionally, torsion stiffness between the rider and the sliding device is much improved with the longer pin directly mounted to the snowboard boot binding mounting plate and ski device interface. In certain embodiments axle pin variations could be used.
SUMMARY
The present invention has been developed in response to the present state of the art, and in particular, in response to the problems and needs in the art that have not been fully solved by current available touring snowboard boot binding systems and mounting plates or mounting bases for snowboard boots or other boots used on touring skis, spit-ski/boards devices, snowshoes, and touring snowboards. The title “Multiple direct touring positions for snowboard boot binding mounting base” of this application basically is derived from a broader utility taught herein regarding touring, climbing, and sliding ski shaped devices with “one” boot binding apparatus herein disclosed. Said boot binding mounting plate having a universal usefulness in switching climbing and gliding modes in a plurality of winter devices such as ski shaped devices and hybrid devices split-ski/board devices that allow climbing modes and sliding modes selectively. In addition, mounting plate boot beds for snowboard boots may be mounted directly over two configurable ski sections in climb and glide modes. Accordingly, the present invention has been developed to provide an apparatus, system, and method and or devices for overcoming the short comings of the art including a selective touring mode boot binding mounting plate that attaches boots to climb and glide ski shaped devices like touring skis, snowboards, split-ski/boards, snowshoes, and crampons, with the use of a rigid removable axle axis interface located in the toe region of the mounting base providing a touring device interface making possible a walking motion when attached to the touring ski device interface. Additionally, the boot binding system or boot mounting base plate may also have mountable means for touring, sliding, traction, or snowshoe, ski, or split ski/board type systems to be applied in separate embodiments to increase options in uphill climbing traction or downhill sliding modes. In one embodiment the selective axle pivot pin axis position may be located on the front half of the binding base, middle region of the mounting base, or rear half of the boot binding base. In a further embodiment the boot is unable to slide off the mounting base area because of the use of a boot retaining system. In another embodiment the mounting base front toe portion is in a turned upward fashion or has a slight upward bend or upward structure to further prevent the boot from moving forward in the mounted position on the mounting base, or to aid in securing or accommodating the pivot pin for the touring walking mode. Furthermore, in another embodiment, the said selective touring boot mounting base may be configured to accept selective axle positions located on the mounting base allowing the footwear to pivot on or connect to a device such as a ski, snowboard, split ski/board, or snowshoe. The boot mounting base plate may be placed in a second position interface so the boot binding cannot walk pivot on items such as a touring snowboard, split ski/board device, approach ski, or other lock heel ski device interfaces on climb and slide devices. The boot mounting base or plate is able to perform all of the above utility without the use of complex systems, adaptors, binding plates/bases, parts, tools, screws, bolts, and the like, etc. These advantages overcome many or all of the above-discussed shortcomings in the prior art. Most importantly, these advantages create a boot retaining mounting base plate which directly locks and unlocks in quick-release fashion a down hill sliding locked heel mode position and a secondary quick-lock and release touring position on the boot mounting base plate creating an optional walking mode for touring with an axle pin anchored to the boot mounting base and a secondary boot mounting base lock or locks reward the axle dock. Additionally the boot mounts directly to the mounting base plate eliminating the need for a bulky snowboard or split ski/board binding adaptor plates/bases of the prior art. In another embodiment, these advantages create a locked heel sliding position over two ski sections. In a further embodiment, windows in the mounting plate may allow the bottom tread portion of the boot to be visible through the boot bed of the mounting plate.
The current invention, in various embodiments, may provide a mounting plate (boot bed) which connects a snowboard boot bed (mounting plate) directly over two connected ski sections in a locked heel mode and a free heel mode where the boot bed pivots when ski sections have been separated. In one embodiment the device may include a mounting base for a boot to rest upon, namely a boot mounting base with direct strap connection means on either side of the boot mounting base for which a resilient strap can be mounted to the sides of the boot mounting base. In a separate embodiment the boot mounting base contains flanges extending from the foot bed of the boot mounting base for the straps to be mounted or to provide locking structures for riding mode transitioning. The said boot mounting base contains an axle pivot pin and axis portion at the front portion of the boot mounting base touring region or toe region of the boot mounting base for a walking motion, and a secondary selective locking position and locking means rearward the toe region locking area on the boot mounting base. The secondary lock position rearward the touring lock position prevents the boot mounting base from moving while coupled to the device. In further embodiments, rail structures, rib structures, flanges, walls, and the like can be used to provide structure for the ride interface transition.
This boot binding system mounting base may be configured to be used on any winter device that selectively glides over snow or climbs over snow from the group consisting of snowshoes, touring skis, telemark skis, touring snowboards, split-ski/boards, snowboards, snowboard boot bindings, and snowshoe ski hybrid devices. Please note that the boot mounting base can be referred as mounting plate, binding plate, binding base, mounting base, or other names that describe the binding boot mounting system named in this invention.
In one embodiment the touring boot binding system consisting of an axle pivot pin portion selectively connected to the snowboard boot mounting plate ski interface able to lock and unlock from position on at least one interface mounted on the touring ski or formed with the touring ski or mounted on a touring split ski/board, or ski other ski shaped devices. Additionally, in a further embodiment, traction can be removable coupled to the axle pivot pin in the area on the ski located adjacent the boot of the user when the boot binding plate is locked to a touring snowboard, snowshoe, split ski/board or other ski system.
In one embodiment traction when detached from a touring ski, touring snowboard, spilt ski/board or snowshoe device may be mounted separately to the boot mounting base. Thus, it becomes a crampon when coupled only with the footwear. However in further embodiments the traction could come from another source other than the riding device.
The prior art concepts for a soft shelled boot touring binding system particularly for snowboard boots all utilize designs that the user must use a separate snowboard binding base adaptor piece with holes oriented for attaching snowboard binding base and 3-4 hole disk to be mounted by bolt or screw to the separate mounting plate adaptor. The said adaptor includes a touring pivot in the toe region and secondary locking points in the adaptor to stop the walking tour pivot especially when in a snowboard mode thus created more weight and manufacturing than is necessary. Typical split-board bindings in the prior art utilize such bindings, adaptors, and interfaces. The present invention overcomes the prior art by providing a snowboard boot mounting plate or base with a quick release detachable walking mode which includes a detachable touring axle pivot pin axis directly to the mounting base binding and device ski interface and a secondary lock position also located on the boot mounting plate or boot base which is a locked heel position for a fixed slide mode on a ski touring device meaning the boot binding cannot pivot while coupled to the ski shaped device. In one embodiment of the present invention the heel is locked in a fixed or non-touring mode for sliding on a ski shaped device like a snowboard, split ski/board, or touring ski by a locking mechanism connected to the ski shaped device that engages the underside of the boot mounting plate by a locking movement or mechanism or pin that runs parallel with the a longitudinal direction on the boot mounting plate or the direction the footwear or snowboard boot points and on the same boot mounting plate the touring pivot axle can engaged in a transverse position in the boot mounting plate and touring ski. In a separate embodiment the heel lock may also run locking movements or fixed mechanisms parallel with the touring locking motion. Thus the prior art is overcome by combining the climb and glide adaptor with a boot binding plate or base into one manufactured piece eliminating the adaptors/screws and increasing usefulness and a plurality of locking points across the boot mounting plate.
In one embodiment the axle pivot pin used for the touring mode on the mounting plate as well as a locking tool reward the touring pivot dock on the mounting plate has quick-release and quick-attaching features allowing it to change position in a quick easy manner from the touring mode to other modes within the mounting plate. The axle pivot pin may have, in a separate embodiment, connective features on the axle to hold axle permanently or non permanently in the boot base plate to facilitate locking and unlocking the axle pivot pin axis or axes from any locked mode or travel mode position interface. Exampled features disclosed herein are a cotter pin and c-clamp though a multitude of systems could be used within the spirit of the invention. The cotter pin offering a quick-release option for the axle pivot pin. It must be noted that a multitude of options exist to secure both ends of the axle by features present on both ends of the axle which prevent the axle from sliding one way or another from its locked position due to features on at least one side of the axle pivot pin that secure it. In a separate embodiment at least one feature on one side of the axle or axle dock may be released or moved to allow the axle pivot pin releasing movement from its docked position on another interface. In another embodiment the axle pivot pin has been made longer then axles pivot pins and clevis pins in the prior art to create a longer span of strength for the rider of the climbing sliding device. In one embodiment the axle pivot pin ends extend beyond the periphery of the devices it selectively mounts to. In another embodiment the axle has been made shorter but is oriented in dimensions that have suitable strength to facilitate the utility of this named invention. It is obvious that a multitude of metals could be used or other materials, bends, axle structures, axle positions, to construct the axle pin to work in accordance with the present invention.
The boot mounting plate design in one embodiment consists of a boot bed for which the boot sits directly on, two flanges in the foot bed for resilient straps to be mounted to connect a boot to the top plane of the foot bed. In further flange embodiments the flange could be bolted, screwed, welded, or riveted and the like to the boot base plate. In one embodiment the axle pivot pin locking/docking areas are located adjacent the sole “plane” of the mounted boot with in at least two ribs, walls, spring loaded latch, latch, or rail structures and the like which support the axle pivot pin in a locked state in an interface and the boot mounting plate. In separate embodiments portions of at least one of a wall, rib, flange, or rail extend from the boot mounting plate foot bed. The boot mounting plate has pivot pin locking areas in the toe region of the boot mounting plate for the walking tour mode and secondary locking areas and structures rearward the toe pivot for a locked heel mode or a snowshoe pivotal mode, or even a secondary telemark binding plate touring position. The axle pivot pin generally is in a transverse position on the riding device interface and boot mounting plate when inserted in both and locked to interfaces of the split-ski/board, ski, board, snowshoe, hybrid, binding plate interface. In a further embodiment the boot mounting base has material removed creating a window or aperture. This material could be from the boot bed area or adjacent the boot bed area to form the window. In further embodiments there could be a series of windows, ribs, beams, window shapes, in the boot bed. This is advantageous to reduce weight, create boot bed structures, add locking points or structures, or add simple weight reducing aesthetics. In an embodiment only one lock feature is used to couple the boot mounting base in the locked heel mode for down hill sliding on the ski touring device. In a further embodiment the one lock feature is reward the touring lock feature wherein the touring lock feature is left unlocked while a different lock feature reward the touring lock feature is locked.
The boot mounting base plate in one embodiment has at least three separate lock points regions provided across the boot mounting plate with at least two selectively providing a locked heel sliding mode. In further embodiments the touring mode position can remain in a the first touring position axle axis with the boot mounting plate able to selectively use a secondary lock interface to form lock heel mode without having to move the boot mounting plate out of touring mode. In a further embodiment at least one lock region comprises two lock features to facilitate locking the one region. The first interface region is a touring mode interface, the second interface region is a touring mode or lock heel mode interface region reward the touring mode region towards the mid plate, and the third interface region is reward the mid region of the boot mounting plate. The locking points could be moved to facilitate other designs without leaving the spirit of a three interface region boot mounting plate in one embodiment or more embodiments of the present invention.
In one embodiment or several embodiments and in accordance with the present invention the ski touring device is a climb and slide hybrid device or split ski/board that has at least two disconnecting ski sections that move in and out of a uniform sliding mode to a climbing mode. For the climbing mode the two ski sections have been placed in a new position where they have been moved apart to be used as climbing tools or walking tools in the snow while the boot binding plate can articulate in a walking motion. This is done by unlocking the two ski sections of the touring device using ski section locks so that the two ski sections can no longer be spanned by the snowboard boot binding in locked heel sliding “ride” mode and the snowboard boot binding is now in a free heel touring walking mode. When touring mode is complete and sliding mode is needed the two ski sections can be moved together again (and locked) forming a more uniform ski surface. In further embodiments traction can be placed on the said boot binding or the said ski device or ski sections. In another embodiment the boot binding plate can disconnect from the riding device to form an alternate climbing or sliding mode. The boot binding plate in one embodiment or more embodiments may have a window, an aperture, a flange, an axle/pin, an interface, a cleat, a bolt, a rivet, a weld, a wall, an edge, a hole, a square window, a girder, a box girder, a pin/axle interface in its mid region, in the toe region, at the side region, strap mounts, metal, plastic, carbon fiber, wood, resin, and any other structure to facilitate the invention on climb and glide devices and interfaces in accordance with the present invention. It would be obvious to one skilled in the art to add technology including prior art step-in technology, new step-in technology, strap technology, metal technology, plastic technology, streamlined manufacturing, milling technology, die casting technology, or the like to embodiments of the present invention without leaving its sprit of innovation.
The component references used to describe the utility like cotter pins, bolts, screws, and the like are used as a model to teach the utility of the invention. It is obvious that a multitude of components could be used outside of the defining props to teach and to facilitate multiple direct lock positions for touring ski mounting base of a snowboard boot binding.
Reference throughout this specification to features, advantages, or similar language does not imply that all of the features and advantages may be realized with the present invention should be or are in any single embodiment of the invention. Rather, language referring to the features and advantages is understood to mean that a specific feature, advantage, or characteristic described in connection with an embodiment is included in at least one embodiment of the present invention. Thus, discussion of the features and advantages, and similar language, throughout this specification may, but do not necessarily, refer to the same embodiment.
Furthermore, the described features, and advantages, and characteristics of the invention may be combined in any suitable manner in one or more embodiments. One skilled in the art will recognize that the invention may be practiced without one or more of the specific features or advantages of a particular embodiment. In other instances, additional features or advantages may be recognized in certain embodiments that may not be present in all embodiments of the invention.
These features and advantages of the present invention will become more fully apparent from the following description and appended claims, or may be learned by practice of the invention as set forth hereunder.
BRIEF DESCRIPTION OF THE DRAWINGS
In order that the advantages of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of accompanying drawings, in which:
FIG. 1 is a top perspective view illustrating the boot binding mounting plate with direct locking zones for, free heel skiing, locked heel skiing, snowshoeing, touring snowboarding, and split-ski/boarding with walls, flanges, girders, axle pin docks, and the like in accordance with the present invention
FIG. 2 is a top perspective view illustrating the boot binding mounting plate and an embodiment of a touring ski interface and connection means in the front half portion of the binding mounting plate. The mounting plate binding also has a second optional axis for the snowshoe position pivot, secondary telemark/cross-country pivot, and a non-pivot “locked heel” positions in the mid range of the plate or boot bed.
FIG. 3 is a side perspective view illustrating the boot binding mounting plate and direct locking zones for, free heel skiing, locked heel skiing, touring snowboarding, snowshoeing, and split-ski/boarding in accordance with the present invention.
FIG. 4A is a side perspective view of the binding boot mounting plate system and in accordance with the present invention.
FIG. 4B is a view of a prior art mounting plate adaptor with connective features for mounting a secondary mounting plate and snowboard boot binding assembly and necessary hardware.
FIG. 5 is a bottom view illustrating an embodiment of the boot binding mounting plate and multiple quick-locking quick-release components for locked heel and free hill climbing modes supported by structures in accordance with the present invention.
FIG. 6 is a perspective view illustrating a quick-attaching and quick-releasing mounting plate boot binding with a touring mode and a secondary locked heel mode for use on a snowshoe, touring ski, split ski/board, or a snowboard able to lock directly to the interface with the positional and quick-release pivot pin axle and or a secondary locking elements.
FIG. 7A depicts various views illustrating the mounting plate and quick-release coupling system and at least two mounting plate locking positions, removably coupled cleat/traction, on a ski shaped riding device in accordance with the present invention.
FIG. 7B is a top plan view illustrating the mounting plate with rail structures or flange structures which support the axle pivot pin especially in the toe region in accordance with the present invention.
FIG. 7C is a top perspective view of an illustrated mounting plate with rail structures or flange structures which support the axle pivot pin in accordance with the present invention.
FIG. 8 is a side perspective view illustrating a climbing ski/hybrid or split ski/board with two detachable ski sections, snowboard boot binding, and a touring axle pivot pin and boot mounting plate binding assembly and secondary locking heel lock for sliding mode when ski sections are joined and locked.
FIG. 9 is a top perspective view illustration of boot mounting devices on snowboard boot binding plate with an axle pivot mode on the plate mounted to a split ski/board with secondary locking heel modes and said snowboard boot binding mounted directly over the split ski sections in accordance with the present invention.
FIG. 10 is an illustration of a bottom view of the binding plate and quick-release axle pivot pin which extends beyond the periphery of the mounting plate surface with the two ends having locking features directly in the design of the axle pivot pin surface area as well as a box girder or frame in accordance with the present invention.
FIG. 11 is a side view illustration an embodiment of a binding mounting plate axle pivot pin direct locking points and structures below the plane of the boot sole and in accordance with the present invention.
FIG. 12A is a side view illustration an embodiment of a binding mounting plate axle pivot pin direct locking points and structures extending below the plane of the boot bed and locking points across the plate in accordance with the present invention.
FIG. 12B is a bottom perspective view illustration and embodiment of a snowboard binding plate with axle pivot pin direct docking points as part of the boot bed of the snowboard binding without the need of a snowboard binding adapter in accordance with the present invention
FIG. 13A is an illustration of a removable quick-release pivot axle pivot pin with axle pivot pin locking points on a touring ski binding interface assembly.
FIG. 13B is an illustration of a removable quick-release pivot axle pivot pin with axle pivot pin locking points (apertures, holes, or grooves) on either side of the axle pivot pin together with a touring ski binding interface assembly.
FIG. 14A is one embodiment illustrating boot bed positions, rail, positions, flange positions, and structures for a mounting plate binding with a snow repellant piece in accordance with the present invention.
FIG. 14B is a top perspective view of the selective touring mounting plate with windows or apertures in the boot bed in accordance with the present invention.
FIG. 14C is a side perspective view of the selective touring mounting plate with boot mounting devices or structures connected to the mounting plate and a separate embodiment of the boot bed position in the front half of the boot mounting plate.
FIG. 15 is one embodiment illustrating a selective touring boot mounting plate binding with a quick-release touring pivot and secondary locking means in accordance with the present invention.
FIG. 16 is one embodiment illustrating an axle pivot pin with two connected locking structures in accordance with the present invention.
FIG. 17 is illustrating an axle pivot pin (clevis pin) with one connected locking structure found in the prior art.
FIG. 18 is an embodiment illustrating the boot mounting plate binding connected to a snowshoe/ski hybrid touring mode in accordance with the present invention.
FIG. 19 illustrates the mounting plate binding in free heel mode in accordance with the present invention
FIG. 20 illustrates side view of an embodiment of the boot mounting plate with recessing traction in accordance with the present invention.
FIG. 21 illustrates side view of an embodiment of the boot mounting plate with recessed traction in accordance with the present invention.
FIG. 22 is a bottom perspective view illustrating the multiple locking points for free heel and locked heel travel modes including a box girder structure for supporting the locking structures on the bottom side of the boot mounting plate in accordance with the present invention.
FIG. 23 is a top perspective view illustrating a selective touring ski device with the boot mounting plate binding attached in locked heel position in accordance with the present invention. The touring mode on the boot mounting plate binding is also shown “unlocked” in the illustration.
FIG. 24 is a top plan view illustrating a snowboard with an interface equipped to except the boot mounting plate binding in a locked heel configuration in accordance with the present invention.
FIG. 25 is an exploded view of the boot mounting plate, axle pivot pin, and boot mounting assembly in accordance with the present invention.
FIG. 26 is a bottom plan view of the boot mounting plate/base, releasable axle axis, detachable traction, and two touring modes and a locked heel mode in accordance with the present invention.
FIG. 27 is a top plan view of the boot mounting plate/base, releasable axle axis, detachable traction, and two touring modes and a locked heel mode in accordance with the present invention
FIG. 28 is a top plan view of a split ski/board device with two ski sections separated in touring mode and boot mounting plate in touring mode in accordance with the present invention.
FIG. 29 is a bottom plan view of a split ski/board device with two ski sections in ski mode in and boot mounting plate mounted above the ski sections in accordance with the present invention.
FIG. 30A is a top plan view of a split ski/board device with two ski sections out in touring mode and boot mounting plate in touring mode in accordance with the present invention.
FIG. 30B is another top plan view of a split ski/board device with two ski sections out in touring mode and boot mounting plate in touring mode in accordance with the present invention.
FIG. 31 is a bottom plan view of a split ski/board device with two ski sections out in touring mode and mounting plate in touring mode in accordance with the present invention.
FIG. 32 is a top plan view of ski sections selectively locked in ski mode in accordance with the present invention.
FIG. 33A is a ski shaped device.
FIG. 33B is a ski shaped device able to move itself into multiple split ski device sections in accordance with the present invention.
FIG. 34 is a flow chart illustrating a climb and slide device with two ski sections moving in and out of tour mode and ski mode in accordance with the present invention,
DETAILED DESCRIPTION
Reference throughout this specification to “one embodiment,” “an embodiment,” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of phrases “in one embodiment,” “in an embodiment,” and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.
Furthermore, the described features, structures, or characteristics, of the invention may be combined in any suitable manner in one or more embodiments. One skilled in the art will recognize, however, that the invention can be practiced without one or more of the specific details, or with other methods components, materials, and so forth. In other instances, well known structures, materials, or operations are not shown or describe in detail to avoid obscuring aspects of the invention.
FIG. 1 is a top perspective view of a mounting plate 90A with a touring mode section 60 at the toe region of the boot mounting plate 90A which accepts the detachable quick attaching axle pivot pin axis 61 at hole 63 and allows the boot mounting plate 90A to attach to the top surface of a skiing device interface (not shown) and detach from that location from the skiing device. The boot mounting plate 90A also has at least one secondary locking feature 59, 40, and 70 behind the touring 63 axle pivot pin axis 61 location. This second locking feature 59, 40, and 70, may be in the form of an axle pivot pin 61 which engages the periphery of a ski touring device interface (not shown) and the periphery of the boot mounting plate 90A in a transverse position 115 through the boot mounting plate 90. In another embodiment a secondary locking feature moves in a back and forth motion through heel lock feature 70 in wherein the motion is parallel or longitudinal to the side of the boot mounting plate 90A. Whereas the axle pivot pin 61 maintains the touring mode 63 forming a transverse anchoring point for the boot mounting plate 90. In other words the touring mode axis 63 allows the axle pivot pin 61 to reside in the boot mounting plate 90A so its two portions are visible while residing in the mounting plate.
The boot mounting plate 90A contains a boot bed surface 101 and 130 for the boot to rest upon when coupled to the boot mounting plate 90A. Surface 126 and 125 are positioned below the surface 101 of the boot mounting plate 90A allowing the locking components movement below surface 101 and 130. Wall or rail structures 110 are also positioned below the boot bed surface 101 and or boot sole bottom plane (not shown) allowing the locking mechanism support means in one or more of the preferred embodiments 63, 59, 40, and 70 for a quick-release and quick-attaching locked heel mode with portions to be situated underneath the boot bed 101. It must be noted that the touring mode 60 may have axle pivot pin 61 in holes 63 to lock the front half boot mounting plate 90 portion to a riding device locking interface (not shown) and at the same time have at least one secondary locking feature in an area of the boot mounting plate portion 140 and the secondary locking structures on the boot mounting plate 90A are supported rails 110 preventing a walking motion. This locked heel mode is contained in an area 140 and is advantageous when descending on a ski device such as a ski or joined sections of a split ski/board especially in a steep alpine setting. In one embodiment wall or rail structures 110 comprise of a pair of side walls running parallel under the foot bed top surface 101 “plane” of the boot mounting plate 90A. Features contained within the walls 110 constitute locking features to hold the boot mounting plate 90 to a separate locking interface for a free heel or locked heel mode. It would be obvious for one skilled in the art in light of the present disclosure to attempt a separate embodiment of locking structures on the underside of the boot mounting plate 90A under the foot bed 101 plane or boot sole plane or adjacent the plane in combination with a touring pivot mode 63 that is detachable and carry out an important aspect of the invention.
Boot mounting plate 90A side portion 115 includes boot attachment means with holes 24 whereby hardware such as bolts and screws or rivets (not shown) can couple at least “one” of the straps 12 and 31 or strap connections/walls to the boot mounting plate 90A, though other boot mounting devices or systems could be used such as step-in systems or other yet to be invented systems. Secondary lock features 59, 40, and 70 are preferred embodiments though other embodiments may be used to lock a rear portion of the touring mounting plate below the boot bed creating a locked heel mode when the free heel touring mode is not desired simply by quick release and quick attaching means. In a separate embodiment locking features 59, 40, and 70 could be supported above the foot bed plane. The boot mounting plate 90A is preferably constructed in metals including aluminum but may be made in materials suitable for colder climates including thermo set plastics, resins, wood, poly carbonate, carbon fiber, steel, and the like, etc.
FIG. 2 is a side view illustrating the boot mounting plate binding 90B and a separate touring free heel ski locking interface 32 in accordance with the present invention. The axle pivot pin 61 resides in interface hole 64 and touring pivot hole axis 63 of the touring mode 60 of the boot mounting plate 90B. The touring lock interface 32 may be separately coupled to the top side of a ski or snowboard with bolts or screws entering holes 46 for attachment to the said ski or snowboard sliding devices or could be a molded part of the ski. An additional boot mounting plate 90B heel lock embodiment is shown in heel lock 80. In this embodiment features 67 go through square cut out open windows 66 a second axle pivot pin 61 is utilized by entering heel lock hole 70 on the mounting plate 90B and heel lock hole 71 on the ski device locking interface. The heel lock 61 is locked into place with a forward longitudinal motion 10 moving from the heel region and moving towards the front of the boot mounting plate 90B. The touring pivot pin 61 is shown in a motion 15 moving from one side of the boot mounting plate 90 to the other and one side or flange 86 of the touring interface 64 to the other side or flange 86 creating a transverse position.
The axle pivot pin hole 59 is used for a secondary lock position rearward the touring position 63 to directly lock the interface 59 to a riding device interface 64 in a quick-release quick-attach manner. This position prevents the boot mounting plate 90B from pivoting in a walking motion around axle pivot pin's 61 axis when the axle pivot pin 61 docked in 59. In a separate embodiment the axis 59 could be attached to a snowshoe allowing the toe region of the boot mounting plate 90B to dig into the snow while in the walking motion. In a further embodiment a cleat traction device could be attached to the boot mounting plate 90B axis point 59 or other axes or other locking features found on the boot mounting plate 90B.
FIG. 3 is the boot mounting plate binding assembly 20 which comprises multiple binding travel modes including a free heel ski touring mode 60 similar to cross-country skiing mode with the binding mounting plate 90C able to pivot about an axis made possible by axle pivot pin 61 in a walking motion. Pivot axle 61 is detachable in a quick release manner from its position in the touring mode 60 when connected to a separate touring ski interface and able to selectively reattach in a quick manner to hole 59 forming a locked heel binding configuration when reattached to a locked heel interface connected to a sliding device such as a split-able ski device. In a separate embodiment the device may be a snowshoe ski hybrid 72 (FIG. 6) and allow pivot axis 59 to rotate the mounting plate 90C through the plane of the ski (not shown). If there is no opening through the device for the mounting plate to rotate through when pivot axis 59 is used then the binding plate 90C will remain locked in a fixed lock heel mode because the mounting plate cannot rotate. When touring is again desired the axle pivot pin 61 is reentered through holes 63 and flanges on the riding device binding interface (example. FIG. 32). The axle pivot pin 61 is selectively locked in place with locking features 27 on both sides of the axle pivot pin 61 which could include a cotter pin 23 and the c-clamp 69. In other embodiments the locking features of the axle pivot pin 60 could be changed but the spirit of the utility would remain the same. Axle pivot pins in the prior art are shorter and do not include two features on both sides of the pivot pin for locking the pin in place. Pivot axle pin 61 is longer allowing the ends of the pivot axle to extend beyond the outer periphery of the mounting plate 90C with the locking features also outside the periphery of the boot mounting plate 90 and riding device connecting components. In other embodiments the axle axis 61 or locking pin 56 may be fully surrounded so that its end is hidden when in a locked or unlocked mode or manufactured state. For example, locking pin 56 has metal locking axles or pins that are inside the manufactured piece of 56. It would be obvious for one skilled in the art to also place axle pin 61 in a similar fixed state within the binding mounting plate or skiing device interface to facilitate the invention without leaving its scope.
The locking mechanisms on the mounting plate 90C are unique from the prior art in that they lock the boot mounting plate 90C in two selective places in quick release quick attach fashion to winter climbing and sliding devices. The first is the touring pivot mode 60 in which the axle pivot pin 61 enters the boot binding plate 90C and device interface (not shown) 90C perpendicular motion 15 to the direction footwear/boot will point on the boot mounting plate 90C forming a transverse situation. In other words the pivot axle pin 61 inters the side of the binding and reappears on the other side allowing the cotter pin 23 to be inserted into cotter hole 22 in the releasable axle 61 outside the periphery of the boot mounting plate 90C holding the mounting plate 90C firmly in position with the ski touring flanged interface. On other portions of the boot mounting plate 90C secondary lock positions 59, 70, and 40 are located to facilitate a locked heel travel mode and work together with namely ski shaped devices in combination with the accessibility to the optional touring climbing mode. In a separate embodiment heel lock 56 is mounted to a ski device and enters the boot binding plate 90C in a longitudinal motion parallel to the direction the footwear will be pointed when mounted to the boot mounting plate 90C.
Thus the boot mounting plate 90C has the ability to directly attach to a touring interface for a walking motion. When another travel mode is desired the mounting plate 90C and axle pivot pin 61 can be repositioned directly to a separate locking interface. This second position of the boot mounting plate 90C prevents the binding from pivoting especially when skiing or snowboarding downhill.
The boot mounting plate 90C includes holes 24 on the sides of the boot mounting plate 90 for securing namely soft shelled boots including snowboard boots. The mounting plate 90C in a separate embodiment may include a strap section 12 which holds the front half of the boot and a second strap section 31 that holds the rear half of boot. A heel piece 11 connected to the back half of the boot mounting plate 90C with highback 16 may also be included to offer more support to the rider. In a separate embodiment the boot mounting plate 90C may be configured as a strap-less step-in system with the same innovative features contained in the boot mounting plate 90 in accordance with the present invention.
FIG. 4A is a side perspective view of the mounting plate 90D illustrating a touring pivot 63 in the touring region 60 wherein the axle pivot rod 61 (not shown) can removably couple the touring mode 60 axle pivot pin 61 and releasing the boot mounting plate 90 D from a riding device interface. Pivot 59 may also offer a secondary locking region for the axle pivot pin 61 to be placed preventing the boot mounting plate 90D from pivoting in a walking motion in one embodiment. In a separate embodiment the pivot 59 can pivot the boot mounting plate 90D in a snowshoe style pivot or in a limited pivot before the touring region 60 makes contact with a second surface similar to telemark style pivoting. Further locking means in the heel region 70 can also be utilized for a secondary or third locking area in the boot mounting plate 90D. Thus from regions heel to toe the mounting plate can be selectively locked and unlocked in a quick-release quick-attaching manner whether for touring or for lock heel travel modes. Boot bed 101 allows a boot to rest upon its top surface. Walls 110 extend from the foot bed for supporting secondary locking means 70 and 59.
FIG. 4B is a perspective view of a prior art binding assembly. This assembly includes a separate mounting plate interface pieces 40, 39 system with a touring mode axle hole 41 for a clevis pin pivot rod. Separate mounting bolts and screws 44s 44w and 44n which need a separate screw drew driver or wrench to attach snow board mounting plate 32 to the top 39 and 39 attaches to 40. Disk 31 is sandwiched onto the top side of the snowboard binding base 33. It is obvious that the prior art requires many components, pieces, plates, hardware, to carry out a touring mode and a locked hill mode. Mounting plate 90A, B, C, D in FIGS. 1-3 and 4A reduce the amount of parts needed to carry out a snowboard touring binding system. Additionally, mounting plate 90D in FIG. 4A when connected to its quick-attaching interface is actually more sturdy and closer to the device than the prior art suggested in 4B. 4A offers better performance when attached to the riding device including a snowboard because of its lower connected profile. 4A is also much lighter because of few parts which is a necessary advantage when touring the back country. Boot mounting plate 90 overcomes all disadvantages of the prior art.
FIG. 5 is a bottom perspective view of one embodiment of the boot mounting plate 90E in accordance with the present invention. The boot mounting plate 90E is shown with a box support girder or frame type structure 195 with at least two side walls 110 and perpendicular structure 112 connected to the bottom of the mounting plate 90E at surface 101. This structure makes up a box or frame type girder for supporting locking structures to prevent the boot mounting plate 90E from making a free heel touring movement. This is called a locked heel position especially for descending snow covered slopes on a skiing device. Locking structures in one or more of the disclosed embodiments may be carried out in regards to locking features 40, 70, and 77. One or more of these locking regions could be utilized. It must be noted that other locking means and interfaces could be utilized in carrying out the invention without leaving its scope.
The axle pivot pin 61 is shown in several possible docking locked locations including 63, and 59. It may also, in a separate embodiment selectively dock and lock into 40 to lock to the rear half of the boot mounting plate 90E. In one embodiment quick-release and quick attaching components on the sides of the axle pin like a cotter pin 23 on one end of the axle pivot pin 61 and a c-clamp 69 at the opposite end of the axle pivot pin 61. The axle pivot pin 61 moves from one side of the boot mounting plate 90E to the other forming a transverse span in a perpendicular motion in comparison to lock 72 motion 10 though other movement directions of the locking components could be carried out. Furthermore the structures or shapes at either end of the axle pivot pin 61 including the axle pivot pin 61 itself could prevent the axle from falling out of its locked positions. The axle pivot pin 61 is unique in comparison to the prior art wherein it transversely spans the full length of the boot mounting plate 90E snowboard binding base so much so that it's two outer edges extend the periphery of the boot mounting plate 90E in two areas when the axle pivot pin 61 is docked and locked. The longer axle pivot pin 61 construction offers a more robust touring pivot providing more turn response when a rider is connected to the mounting plate 90E riding a ski device. It must be noted that the axle could be made shorter without leaving the spirit of the invention. The axle pivot pin 61 in a preferred embodiment is made of metal though any rigid material could carry out the invention in regards to an improved touring pivot axle pin as disclosed herein. In further embodiments windows/apertures are present within the boot mounting plate 195 to reduce weight.
FIG. 6 is an illustration of perspective views of the boot mounting plate 90 and its ability to optionally and selectively connect in a quick-release and quick attaching manner to a “hike or glide” group consisting of a ski 100, a snowboard 200, a snowshoe 300, a touring ski hybrid 400 or split ski/board 400 by using the axle pivot pin 61. In one embodiment the axle pivot pin 61 with detachable features including at least one cotter pin 23 and a c-clip 69 or retaining ring 69 connected to the pivot axle pin 61 in one example embodiment. Flanges 86 with docking axle pivot pin 61 holes 96, 64, and 106 may be used on the riding devices. In one embodiment a riding device may consists of climbing and sliding boot mounting plate positions on one device. In other words the pivot axle pin 61 can be removed from one location climbing mode or travel mode on the device releasing the boot mounting plate 90 and then the boot mounting plate 90 is placed in a second position and connected to the same device or separate device for a secondary different travel mode such as sliding.
The snowboard mounting plate 61 interface 33 is mounted to the snowboard 200 with screws, bolts or rivets or other means. The axle pivot pin 61 docking areas 96 lock the mounting plate 61 to the interface 33 in a snowboarding locked heel mode. Axle pivot pin 61 uses position 59 on the mounting plate 90 and can be lined up to docking areas 96 on the snowboard 200 mounting plate 90 interface 33 and the axle pivot pin 61 is pushed into place through both the mounting plate 90 lock position 59 and docking areas 96 in the interface 86. The ski 100 has mounting areas for the mounting plate 90 in flanges 86 and axle pin 61 docking areas 64 on the flanges 86. The mounting plate 90 can be attached with its touring axle pivot pin 61 at position 63 with the pivot pin 61 forming a free heel mode for a walking motion or the mounting plate 90 can be attached at a secondary lock system rear of the touring axle position 63 such as axle lock position 59. The axle pivot pin position 59 is a locked pivot mode preventing the mounting plate 90 from articulating in a walking motion. Basically the heel cannot move up and down in a walking motion when axle pivot position 59 is coupled to holes 64 on the ski flange 86.
A snowshoe 300 is pictured with an interface suited to accept the boot mounting plate 90 by way of axle pivot pin 61 through docking holes 106 on flanges 86. A snowshoe ski hybrid device or split ski/board 400 with the ability to form a touring ski mode or a snowshoe mode and a locked heel mode by use of boot mounting plate 90, is pictured in 400. It also may contain one or more embodiments of the present invention including the use of the mounting plate 90 in a snowshoe mode, locked heel ski mode, and cross-country ski mode, or touring mode. Additionally, the mounting plate when removed from a device may be used with a cleat forming a crampon system (not shown).
The boot mounting plate 90 shown in FIG. 6 illustrates the ability for the mounting plate 90 to be universal in that in can attach and reattach to so many devices in so many positions. The straps 12 and 31 may be used in one embodiment for binding soft shelled boots to the mounting plate. In another embodiment a step-in system could be utilized in the universal mounting plate 90. Finally, in another embodiment at least one strap could be used mounted to the boot mounting plate 90.
FIG. 7A is a top plan view of the boot mounting plate 90F, a touring ski 100, the boot mounting plate 90F, and the axle pivot pin 61. The axle pivot pin 61 uses movement 15 to engage the ski interface flanges 86 transversely with axle pivot pin 61 docking holes 63 or 59. In a separate embodiment two axle pivot pins 61 could be docked simultaneously in 63 and 59 locking to areas of the boot mounting plate 90F at the same time. The boot mounting plate 90F has apertures 113 or windows directly located on surface 101 of the boot mounting plate 90F where footwear/boot will rest when coupled to the binding system 20. The aperture windows 101 reduce the weight of the boot mounting plate 90F especially when constructed of a metal such as aluminum. Adjacent each aperture 113 are rib or flange like structures to maintain a structure. The apertures 113 also allow the bottom surface of the boot (not shown) when mounted to the boot mounting plate 90F have nothing in there between accept for the boot and the top of a riding device allowing snow to travel through or a separate flat material snow repelling device connected to either side of the aperture for keeping snow off of the binding (not shown). In the prior art there is a separate base plate connected to the snowboard binding assembly and binding base which is very heavy and cumbersome.
In one embodiment the boot mounting plate 90F may have an aperture or window in the heel region 248 with flange or wall structures around the aperture periphery for structure. This is for reducing weight or helping with lock placement with-in the boot bed of the boot mounting plate which is surface 101 as well as any surface the sole of the footwear or boot makes contact when mounted to the binding plate top surface. In another embodiment there is a second aperture or window in the front third portion of the boot binding plate 90F in FIG. 7 for securing a locking mechanism. So the boot mounting plate 90F in FIG. 7 contains open window structures through the boot mounting plate 90F itself which serve various purposes including weight reduction, locking features, and aesthetics. The boot mounting plate 90F in one embodiment could contain apertures or windows 113 on the foot bed 101 with flanges 115 extending upward or downward from the foot bed 101. Connected to at least one of the flanges 115 are at least one resilient strap or straps 12 and 31 for securing a boot to the mounting plate 90F. In a further embodiment the sole of the boot can be seen when attached to the boot mounting plate 90F through apertures or windows 113. In a separate embodiment the aperture or windows 113 in the boot mounting plate 90F could be made in various shapes and sizes to carry out its nature of utility existence offering a purpose not yet found on current snowboard touring boot binding plates in the prior art that utilize a detachable touring pivot axle in the front half of the boot binding plate 90F and a secondary locking structure for a locked heel mode rear of the touring pivot.
100
a touring ski snowshoe hybrid is illustrated with detachable front traction 117 which can attach and quick-release with the axle pivot pin 61 inserted into a plurality of positions including a front touring position 63 and a rear locked heel or pivotal snowshoe pivot 59. The front traction 222 is mounted to pivot dock 59a on the traction 117 and 59 on the ski 100 to selectively lock the traction 222 to the underside of the ski 100 with the axle pivot pin 61. Also shown is a rear lock 119 which can also lock to the ski positioned to the underside of the touring ski 100. Front 222 and rear locks 119 also contain spike structures for gaining traction on winter precipitation such as snow and ice. An additional traction component which can be used is a climbing skin 224 can be removably coupled to the ski system shown in FIG. 7 or attached permanently. Finally, in one embodiment a selective heel lift 139 has at least one climbing bar coupled to the top surface of the heel lift to selectively rotate up or down dependent on the users desire of climbing a slope and reduce lower leg fatigue.
FIG. 7B and FIG. 7C are top perspective plan views of the boot mounting plate 90G in accordance with the present invention. The touring style snowboard/ski binding has a base plate 90G that can directly mount a boot on a portion surface 101 and rails 110 located and connected to the surface 101 with rails 110 supporting a quick-release quick attaching locking component or interface located and connect the locking component such as a axle pivot pin 61 to a separate sliding device such as a ski or snowboard. Rail 110c structure portion is in the front half of the boot mounting plate 90G with touring axle pivot pin 61 docking position 63 which offers a position under the boot bed 101 or footwear boot sole plane (not shown).
In one embodiment the rail 110e faces or touches only the sole surface of the boot with no other structures touching a portion of the top surface of the rail 110e. At one end of the rail 110c in the touring area 60 mounting holes 63 are located for docking and securing axle pivot pin 61. FIG. 17 is another illustration of this embodiment. The boot bed 101 is made higher than at least a portion of the axle pivot pin 61 docking location in the rail 110 allowing footwear boot to correctly pivot in a walking motion above and over the axis. This system is directly integrated with the boot mounting plate 90G. Furthermore, in combination with the touring pivot mode 63 is a selective optional locking heel mode 70 integrated into the boot mounting plate 90G to directly lock to a separate quick release locking component or interface on a sliding device to prevent the boot mounting plate 90G from pivoting in a walking motion. In one embodiment the top portion of the rail structures 110e are not connected or touching any surface but face the bottom of a boot without any other structure there between. The rails 110c may be configured to parallel the side wall 115 or the rails 110 may be perpendicular with the walls 115 with a portion of their structure below the plane or surface of the footwear boot bed 101. The rail 110, 110c, 110e, can be oriented in any form to carry out the and hold and support the mechanisms of locking and unlocking of the touring pivot pin 61 or portions of the boot mounting plate 90 in quick release and quick attaching fashion and the heel lock system in accordance with the present invention. It must be noted that the rail structures 110, 110c, 110e could be added separately or bolted to the boot mounting plate 90G in several different embodiments without leaving the scope of the present invention including separate pieces. Included with the rail design in a separate embodiment are walls or flanges 115 which rise above the boot bed 101 plane to secure straps at strap holes 24 as well as positioning the boot properly on the binding mounting plate 90. In one embodiment the sides 115 do not need flanges or walls but a side surface to place holes 24 (not shown). The boot mounting plate 90G in FIG. 7A has the ability to selectively tour as well as quick release the touring position at holes 59, 63 in the rails 110 and optional and quickly locking the heel 70 for a locked heel mode 70 if desired. This boot binding mounting plate 90G is very useful in the back country because it offers a lightweight multiple travel mode device with very little weight. It also offers locking mechanism areas below the boot bed 101 to carry out climb and sliding travel modes for a sliding device.
FIG. 7C shows a boot mounting plate 90H with pivot axle pin 61 uses a perpendicular motion 15 to side walls 115 to form a transverse axle pivot pin location and lock and unlock the axle pivot pin 61 to the tour hole dock 63 and rails 110. The heel lock is engaged with a parallel motion 10 to side walls 115 or longitudinal motion. Note that all locking mechanisms reside in the rails 110 below the foot bed 101 making sure the boot is above the quick release locks. In a separate embodiment the locks could be positioned above the boot bed 101. Apertures 192 allow mounting plate weight reduction, aesthetics, and allowing some snow to travel through the boot bed 101 instead of sticking to it. The material of the boot mounting plate 90H in most forms utilizing the technology of the present invention should be made in metal such as aluminum, or carbon fiber, plastics, or any material suitable to carry out the present invention. In one embodiment the boot mounting plate 90H could contain apertures or windows in the foot bed 101 and other parts of the boot mounting plate 90H and at the same time have upward or downward turned side walls 115 or flanges 115 at the sides of the boot mounting plate 90H to help contain the boot on the boot bed or support the boot bed 101. (see also FIG. 7B and FIG. 14B).
FIG. 8 is a split ski/board 400 which has three modes of transportation in snow. The first is a sliding device or ski 100 for sliding down inclines when in locked heel mode as well as cross-country free-heel touring mode when heel is unlocked. There is also a snowshoe mode allowing the binding 20 to pivot through the plane or optional opening of the ski for climbing propulsion. The uniqueness of the touring ski hybrid split ski/board 400 is the ability its boot mounting plate 90 possesses in regards to allow selective lock and free heel modes in quick release and attach manner. Additionally, the boot binding 20 in FIG. 8 is a conventional snowboard binding high back 11, conventional snowboarding binding strap 12 in front and conventional snowboard binding strap in back 31 connected to 115. The boot mounting plate 90 which 11 and 12 are connected to has features which allow the boot mounting plate 90 to selectively tour in a walking free heel mode and also ski in locked heel mode. The pivot pin axle 61 has multiple locations in which to dock the axle pivot pin including 59 and 63 in rails 110. (see also FIG. 9)
FIG. 9 illustrates a snowshoe ski hybrid device or split ski/board. Important features in connection with one embodiment of the present invention is the top surface of the rails 110 face the boot sole when the boot is present on the mounting plate 90 with no other surface there between. The rails 110 are also attached to foot bed 110 in this embodiment. Pivot pin axle axes 63 and 59 can also be seen for multiple touring modes and supported by the rails 110. Lock 56 is pushed in a longitudinal motion parallel with flange 115 through rails or flanges 110 to engage and lock the heel of the mounting plate 61. The locking is all accomplished directly to the mounting plate 91 below the sole of the footwear or boot bed 101 in accordance with the present invention including in the box girder 195 below a portion of the boot bed 101. The touring ski hybrid split ski/board 400 has the ability without the need of separate special separate mounting plates or adaptors for the boot mounting plate 90 to connect to and carry out the present invention.
FIG. 10 is a bottom perspective view of an embodiment of boot mounting plate 90I in accordance with the present invention of a climb and glide equipped boot mounting plate 90. In one embodiment the axle pivot pin 61 is shown extended beyond the periphery of both sides of the mounting plate 90I. Features 22 in the form of a groove or hole on both sides of the axle pivot pin 61 allow attachment of locking features to the ends of the pivot axle for quick-release means so the axle pivot pin 61 can be moved from its position from a touring mode 63 or a secondary mode 59 or 70. In one embodiment C-clips 69 or cotter pins 23 are placed to in position 61 in FIG. 10 to selectively lock the axle pivot pin 61 in its docked position 63 in the boot mounting plate 90I. Rails 110 can be seen as well as walls 115 for stabilizing footwear on the boot mounting plate 90I. Rails 110 are connected to the boot bed 101 allowing locks to pass under the foot bed through the rails 110 to connect and disconnect climbing and sliding travel modes.
FIG. 11 is a side perspective view of the boot mounting plate 90I illustrating the lock hole 70 for an axle pivot pin 61 to be inserted or even a detent clevis pin. Axle dock 63 is shown with the axle pivot pin 61 inserted and docked. Rail or walls 110 are shown below the plane or boot bed 101 of the boot mounting plate 90I and connected to or extend off portions of the boot bed 101 portion facing the terrain or ground. Flanges 115 are connected to or extend off the top side of the boot bed 101 or same structure which the boot sole makes contact with the boot mounting plate 90I also shown with strap mounting holes 24 on flanges 115. 303 is optional traction for a snowshoe mode.
FIG. 12A is a detailed side view of a boot mounting plate 90J in accordance with the present invention which over comes the draw backs of the prior art. Boot bed 101 supports a boot 99 on at least portions of its surface area directly or its apertures windows (not shown). Portions of the rails 110 extend off of the terrain facing bottom surface 101 and are connected to the bottom surface of the boot bed 101 of the boot mounting plate 90J and are below the surface area of the boot bed 101. The rail portion 110e or top side of the rail is exposed for the boot 99 to face it directly or touch it in one embodiment. The rail 110 contains locking quick release locking features supported in it's design including pivot hole 63 and locking flange or hole 70 to interact with another quick release locking feature or interface on a sliding or climbing device for winter landscapes such as skis or snowboards. Axle pivot pin 61 can be inserted or docked in lock hole 70 for a locked heel mode and axle pivot pin 61 touring holes 59 and 63 for a touring free heel mode. At the same time the boot bed 101 has up turned flanges 115 which straps can be connected to for restraining a boot 99 on top of the mounting plate 90J. Line 299 represents the boot 99 sole 101B contacting points on the top side of the boot mounting plate 90J and the locking points all shown below that line connected to the rails or walls 110. Line 299 also represents, in one embodiment, a upward turned front portion of the boot mounting plate 90J. It must be noted that in a separate embodiment the two rails on either side of the boot binding plate 90J could be touching each other in other words the void between the two rails could be filled in with material constituting a solid block (not shown). The boot 99 In a separate embodiment the straps 12 and 31 could easily be connect to a side portion of the boot mounting plate 90J to connect the straps 12 and 31 at holes 24 with screws or bolts or rivets and or applicable connecting structures.
In a separate embodiment the boot mounting plate 90J shown in FIG. 12A could be one piece of material with a foot bed 101 portion with at least two side rails 110 or flanges 110 bent downward from the boot bed 101 surface. Flanges 110 include locking areas in the surface area. Flanges or walls 115 are bent upward from the boot bed 101 and have holes 24 for mounting at least one strap or straps 12 and 31. In a further embodiment line 299 is the line the boot bed 101 follows in the front of the mounting plate 90J to further secure the boot 99 from forward motion on the boot mounting plate 90J. Axle pivot pin 61 docking hole 59 is shown as a locked heel pivot mode if the boot mounting plate 90J is resting on a ski base. It cannot pivot in this ski mode. In another embodiment in accordance with the present invention it would be obvious to make the touring mode 63 equipped rails 110 as separate pieces and connected them to at least a portion the boot bed 101 underside and extending off of the boot bed 101 underside portion on the boot mounting plate 90 opposite the side the boot 99 rests upon with portions the boot bed 101 underside still directly facing the terrain between the rails. Also included in this embodiment are features which lock the heel portion of the boot mounting plate 90J binding into place in its mounted position. (see also FIG. 12B)
FIG. 12B embodiment is bottom perspective view of a boot mounting plate 90K in accordance with the present invention which over comes the draw backs of the prior art. Boot bed 101 supports a boot 99 on at least portions of its surface area directly. Portions of the rails 110 are ground or terrain facing from bottom surface 101 and are connected to or extend from the bottom surface of the boot bed 101 of the mounting plate 90K and are below the surface area of the boot bed 101. The rail portion 110e or top side of the rail is partially exposed with top portions not touching or connected to any object. The rail 110 contains locking release locking features in its design at pivot hole 63 and locking flange or hole 70 to interact with another quick release locking feature on a sliding or climbing device interface for winter landscapes such as skis or snowboards. Axle pivot pin 61 can be inserted in lock dock 70 for a locked heel mode and axle pivot pin 61 touring holes 59 and 63 for a touring free heel ski mode. At the same time the boot bed 101 has up turned flanges 115 extending its sides which straps can be connected to for securing a boot 99 on top of the boot mounting plate 90K. It must be noted that in a separate embodiment the two rails on either side of the binding plate 90K could be touching each other in or in other words the void between the two rails could be filled in with material constituting a solid block. (not shown). The boot 99 In a separate embodiment the straps 12 and 31 could easily be connect to a side portion of the boot mounting plate 90K to connect the straps 12 and 31 at holes 24 with screws or bolts or rivets and applicable connected structures.
In a separate embodiment the boot mounting plate 90K shown in FIG. 12A-B could be one piece of material with a boot bed 101 portion with at least two side rails 110 or flanges 110 bent downward from the boot bed 101 surface. Flanges 110 include locking areas in the surface area. Flanges or walls 115 are bent upward or downward from the boot bed 101 and have holes 24 for mounting at least one strap or straps 12 and 31. In a further embodiment line 299 is the line the boot bed 101 follows in the front of the boot mounting plate 90K to further secure the boot 99 from forward motion on the boot mounting plate 90K.
In another embodiment in accordance with the present invention it would be obvious to make the touring mode 63 equipped rails 110 as at least two separate rail pieces and connected them to at least a portion the foot bed 101 underside on the mounting plate 90K opposite the side the boot 99 rests upon with all center portions the foot bed 101 underside still directly facing the terrain between the rails. Also included in this embodiment are features which lock the heel portion of the mounting plate 90 into place in its mounted position. (see also FIG. 12A)
Block 412 has rail grooves 56 which interact with rails 110 to form a locked heel locking mechanism 70 in accordance with the present invention. The rails 110 use slide into feature 56 locking the mounting plate 90K directly to the interface. The axle pivot pin 61 is also repositioned from the touring free heel interface to the slider block 412 interface.
The front portion of the mounting plate 90K is shown with an upward turned feature 512 with a bend 656 off of the foot bed 101 also shown. The upward turned feature 512 at the front of the mounting plate 90K helps keep the boot from moving off the mounting plate 90K and offers further stability.
FIG. 13A embodiment is a top perspective view of the axle pivot pin 61 and mounting components for a touring ski 100 interface 32. The axle pivot pin 61 is shown including grooves or holes or anything suitable to carry out the invention with selective coupling objects such as cotter pins 23 and c-clips though it would be obvious in light of the present disclosure to utilize any quick release coupling object together with a second coupling or docking object on the opposite end of the axle 61. According to one embodiment the coupling mechanisms are connected at “both” sides of the releasable axle pivot pin 61 in features such as grooves, threads, holes, axle itself etc with pivot pins surface area with at least one of the coupling mechanism being quick-release and quick attaching such as the cotter pin 23 or any other coupling part. In another embodiment one coupling feature at the end of the axle pivot pin 61 is in the form of a c-clip (see FIGS. 6, 7, and 10). Touring ski interface 32 is mounted to the top surface of the ski 100 with bolts or screws 85 placed through holes 46 and into holes 48 on the ski 100.
FIG. 13B is a top perspective view of a ski touring interface 32 with mounting holes 46 for bolts or screws or rivets to be inserted through and holes 63 on the boot mounting plate 90, said interface 32 connected to a sliding device such as a ski. The axle pivot pin 61 has locking features 27 on both sides of the axle pivot pin 61 to hold the axle pivot 61 pin when it is locked into position in holes 64 on the interface 32. In a separate embodiment the locking features 27 may use a cotter pin 23 or a c-clamp 69 in accordance with the present invention. When the axle pivot pin 61 is inserted into position 64 on the interface 32 its two ends 21 including the locking features 27 extend beyond the periphery of flanges 86.
FIG. 14A is a side view perspective of the mounting plate 90G in accordance with the present invention illustrating the upward bend angle 295 of the front portion of the mounting plate 90G shown with a bend angle of 25 degrees of the main foot bed 101. This feature helps retain a mounted boot and its forward movement on the mounting plate 90G. Locking areas for touring modes are shown in axle pivot pin 61 docking area 63 allowing the mounting plate to articulate at a specific toe region in a free heel touring mode. Axle pivot pin 61 docking hole 59 is shown as a locked heel pivot mode if the mounting plate 90G is resting on a ski base. If the mounting plate 90G is connected to a snowshoe then the docking hole 59 axle 61 position allows an additional articulating free heel touring mode. In a further embodiment locking areas may include a heel portion lock 70 connected to a box girder structure 195 at the rear of the mounting plate 90G. The box structure 195 is a series of flanges 110 connected to one another and part of the foot bed 101. Snow shield 30 is a separate piece which can be permanently affixed to the mounting plate 90G to prevent snow from sticking to the underside of the mounting plate 90G. The snow shield 30 can also be placed on other portions of the mounting plate 90G to serve the same purpose. It must be noted that the mounting plate 90G can have permanently connected structures affixed to its surface area to supply strength or separate binding and mounting plate 90G functions. In another embodiment an upward turned feature at the front half of the binding helps keep the mounted boot secure.
FIG. 14B is a top plan view of the boot mounting plate 90F in accordance with the present invention. Locking areas for touring modes are shown in axle pivot pin 61 docking area 63 allowing the boot mounting plate 90F to articulate at a specific toe region in a free heel mode. Axle pivot pin 61 docking hole 54 is shown as a locked heel pivot mode 70 if the boot mounting plate 90F is resting on a ski base. If the boot mounting plate 90F is connected to a snowshoe then the docking hole 59 axle position allows an additional free heel articulating touring mode. In a further embodiment locking areas may include a heel portion lock 70 connected to a box structure 195 at the rear of the boot mounting plate 90F. The box structure 195 is a series of flanges or at least one flange 110 connected to one another and part of the foot bed 101. It must be noted that the boot mounting plate 90F may have permanently connected structures affixed to its surface area to supply strength or separate binding and boot mounting plate 90F functions. In one embodiment apertures 192 can be added on the boot bed 101 to reduce weight, locking structure can move through, add aesthetics, and create an open window through which snow can move to touch the boot sole or other piece. In a further embodiment apertures 192 also provide grip for a mounted boot to keep it more stable on the boot mounting plate 90F. (also see FIG. 7C)
FIG. 14 C is a side perspective view of one embodiment of the mounting plate 90K in accordance with the present invention or the full snowboard touring binding assembly 500 intergraded and connected to one boot mounting plate 90K without the need of a snowboard binding base plate or separate mounting plate. The design includes an upward turned foot bed 101 portion 512 at the front touring area 60 of the mounting plate 90K which may be up turned from 1 degree to as much as 90 degrees off set the foot bed 101 to facilitate it's use which is making boot more stable on the mounting plate 90K and limits forward movement of the boot when mounted to the mounting plate 90K. Also including in one embodiment at least one strap or strap portion 12 and strap portion 31. In a further embodiment the upward turned boot stabilizer is a flange or wall offset the boot bend at the toe region of the boot binding plate. The design also includes a touring pivot 63 for a free heel mode in which the axle pivot pin 61 can dock in a selective quick release and quick attach manner in wall or rail 110. Flange or rail 110 is connected to and extending from the foot bed 101 of the snowboard binding 500 with top rail portion 110E not connected or touching another surface. Also included in the mounting plate 90K is the heel lock 70 located in wall or rail 110. (see FIG. 14A)
FIG. 15 is a top perspective view of a boot mounting plate 90L in accordance with the present invention comprising a foot bed 101 with upward turned flanges 115 on the sides of the foot bed 101. Flanges 115 suspend the mounting holes 24 for the mounting of at least one strap 112 to the flange 115. Touring pivot 63 contained and supported within the rail, rib, or wall 110 holds and supports the axle pivot pin 61. Locking feature 70 holds the mounting plate 90L to locking feature 56 on the slider block 412. The innovative step in the mounting plate 90L or soft boot binding assembly 90L with straps attached thereto is its ability to attach to the slider block 412 without the use of separate mounting plates over coming too much weight and expense. In accordance with the present invention the mounting plate 90L has a quick-release tour pivot axle 61 and multiple “direct” quick release locking docks or points under the foot bed 101 not found in the prior art and eliminates the use of bolts to anchor a snowboard binding assembly and binding base to a separate mounting plate saving money weight and time and at the same time increasing performance of the binding system for touring, climbing, and sliding. The slider block 412 is coupled to a sliding device with screws 149. Axle pivot pin 61 is used to lock and unlock the free heel touring mode.
FIG. 16 is a side plan view of a mounting axle pivot pin 61 in accordance with the present invention. The axle pivot pin 61 is a long slender rod piece with two ends. On both ends there is a coupling feature 27 for allowing the axle pivot pin 61 to selectively and universally lock in an axis or axes on a mounting plate 90 and or rails 110 or flanges 86 (also see FIG. 6) and be connected to a snowboard, ski, or snowshoe device. In one embodiment the feature on the axle pivot pin 61 which allows coupling devices is material removed from the axle to allow a coupling feature connection thereto. In another embodiment the coupling feature is an interface on the riding device or the boot mounting plate assembly. In one embodiment the coupling devices are from a group consisting of cotter pin, c-clip, or nut etc. It would be obvious with one skilled in the art in light of the present disclosure to construct an axle pivot pin 61 with coupling features on both ends of the axle pivot pin 61 with one at least one end of the axle pivot pin 61 having release ability and use other embodiments not mentioned herein to create or fabricate a quick release of at least one axle end without leaving the scope of this particular invention of a releasable touring pivot axle pin 61.
The benefit of having the coupling parts of the axle pivot pin 61 at both ends is its ability to span transversely a further surface of a mounting plate offering more strength. It also allows the pin to be arranged in more than one axis or locking dock more efficiently. The axle pivot pin 61, in one embodiment, is made of steel or other metal materials and could also be made of any other materials to carry out the invention.
FIG. 17 is a pivot pin found in the prior art. The axle pivot pin 55 found in the prior art is cumbersome in that it requires a clasp to be anchored at one end. This prevents the axle pivot pin 75 from mounting to more than one axis because the clasp will not fit through the axis holes such as axis 59 on the mounting plate 91 or a heel lock 70 using the axle 61. Furthermore it is a shorter length spanning axle and offers less support when anchoring a boot mounting plate 90 to a sliding device.
FIG. 18 is a side perspective view of the snowshoe ski hybrid 400 in a touring ski mode with the mounting plate 90 of the present invention. The mounting plate 90 has a touring pivot 63 which lines up with touring mount hole 64 on flange 86. The mounting plate 90 is shown articulating in a free heel mode on axle pivot pin 59 on a snowshoe type touring device. Detachable cleat 117 is shown connected to the mounting plate 90. In one embodiment a second axle pivot pin 61 is inserted and docked into touring pivot pin dock 63 at the same time a second axle pivot pin 61 is inserted into touring pivot dock 59 forming a locked heel configuration. The mounting plate 90 has quick release axle pivot pin 61 locking features below the foot bed 101. The flange or rail 115 has strap mounts 24 for securing strap systems. 1804 is a movable wing which opens and closes the ski surface to change from snowshoe to ski modes allowing the binding to rotate through the device or not. Traction component 119 is removably coupled to the snowshoe ski hybrid 400 to offer further traction.
FIG. 19 is a side perspective view of the snowshoe ski hybrid 400 in a touring ski mode with the mounting plate 90 of the present invention. The touring pivot axle 63 is shown coupling the mounting plate 90 to the ski flanges 86 allowing a free heel walking motion. Secondary locking position 59 is shown in an open position allowing the heel to move freely in the walking motion. If a second axle pivot pin 61 is docked in position 59 on the ski then the mounting plate 90 or articulation walking mode will be stopped and locked. Thus we see that the snowshoe ski hybrid shown in FIGS. 18-19 has a releasable touring pivot by way of pivot axle pin 63 and secondary separate locking features 59 rear of the touring pivot 63 and a lock below the foot bed 101 all in the same mounting plate 90 which also includes at least one strap 12 mounted to the side of the mounting plate 90 to secure a boot on top the foot bed 101. Climbing and gliding is achieved by one mounting plate 90. Wing 1902 is shown forming a ski surface and plugging the snowshoe mode window for which the mounting plate 90 may optionally pivot through in the snowshoe mode as depicted in FIG. 18.
FIG. 20-21 is a side perspective view of a mounting plate 2104 in accordance with the present invention. The mounting plate 2104 includes a touring pivot dock 2110 for a quick releasable axle pivot pin 61 (not shown). A secondary pivot dock 1602 is shown rear of the touring lock position 2110. Pivot dock is where axle pivot pin 61 can be inserted through a flange 86 connect to a ski, touring device, or snowshoe device and the hole 1602 or 2110 to secure an axle pivot pin 61. Axle pivot pin position 1602 provides a free heel snowshoe pivot position or a locked heel position dependent on what the user desires a climbing or sliding mode. A third lock position is shown in heel lock feature 70. The mounting plate 90 locking points 1602 and 70 are found behind the touring pivot 2110. Walls or rails 110 show lock supporting positions within the side rails or walls of 110 and below the foot bed 101 in accordance with the present invention though it has been explained that in a separate embodiment the locking positions could be above the foot bed 101.
In one embodiment deployable 2108 traction spike and retractable 2106 traction spike 2102 can be utilized on the mounting plate 2104 for the snowshoe mode and also a detached mounting plate 2104 from the riding device mode or crampon mode.
FIG. 22 is a bottom perspective view of an embodiment of the mounting plate 90M in accordance with the present invention of a climb and glide equipped mounting plate 90M able to transition articulating pivot modes and lock heel modes quick-release style directly on the mounting plate 90M surface area without the need of interfaces or extra base plates and multiple stacked bolted parts. The axle pivot pin 61 is shown extended beyond the periphery of both sides of the mounting plate 90M. Features 27 may be in the form of a groove or hole on both sides of the axle pivot pin 61 allow attachment of the pivot axle 61 for quick-release means so the axle pivot pin 61 to the plate either in a manufacturing step or other step so the mounting plate can be moved from its position from a touring mode to a secondary travel mode. In one embodiment C-clips 69 or cotter pins 23 are placed to in position 27 to selectively lock the axle pivot pin 61 in its docked position 63 or 59 in the mounting plate 90M. Rails 110 can be seen stabilizing or supporting the locking mechanisms 70, 59, below the foot bed as well as walls 115 for stabilizing a boot on the mounting plate 90M. In one embodiment rails 110 are connected to and under the foot bed 101 or extend from the foot bed 101 allowing locks to pass under the foot bed through the rails to connect and disconnect climbing and sliding travel modes.
FIG. 23 is a top perspective view of a touring ski in accordance with the present invention. Mounting plate 90 is shown anchored to the ski binding interface 64 of a ski 100 with axle pivot pins 61 in rear docking slot 59 offering a locked heel sliding mode. When the axle pivot pin 61 is transferred to slot dock 63 the mounting plate is able to pivot in a free heel walking motion about axis 63.
FIG. 24 is a top perspective view of a snowboard 200 with a mounting plate 90 attached to the snowboard binding interface 33 with bolts or screws (not shown) through holes 46 to the top side of the snowboard. The mounting plate 90 can be mounted to the interface 33 by placing an axle pivot pin 61 through holes 96 on the snowboard binding interface 33 flange 86 and holes 59 and 63 on the mounting plate 90 locking the mounting plate 90 in a locked heel position.
FIG. 25 is an exploded view of the mounting plate 90 and binding assembly above a sliding device 100 or 200 in accordance with the present invention. The top perspective view of a mounting plate 90 with a touring mode section 60 at the axle pivot pin dock 63 of the mounting plate 90 which accepts the detachable quick attaching pivot axle pin 61 in hole 63 and allows the mounting plate 90 to attach to the top surface of a separate skiing device interface and detach from that location from the skiing device interface. The mounting plate 90 also has at least one secondary locking feature portion behind the touring pivot axle pin 61 location toward more rear ward part of the mounting plate 90. This second locking feature 70 may be located on wall structures 110 below portions of the foot bed 101 on the mounting plate 90. In one embodiment a locking feature 61 moves in a back and forth motion 15 through feature 63 in wherein the motion is perpendicular to the side 115 of the mounting plate 90 forming a transverse axle pivot pin 61 position on the mounting plate 90. In other words the touring mode 63 allows the axle pivot pin 61 to enter from the side of the mounting plate 90 with its two ends extending the periphery of the mounting plate 90 when the axle pivot pin is in place in the touring mode 63.
In one embodiment the binding assembly consists of a heel support 11 and a high back 16 connected to the heel support 11. Also connected to the heel support 11 is rear strap 31. Heel support 11 is connected to the mounting plate 90 flange 115 at holes 24. Holes 24 on the flange 115 can also connect a second strap 12. Foot bed surface 101 is where the boot rests when mounted to the binding system. The toe region 512 or front portion of the mounting plate 90 has a turned up or bent upward toe section 295 to help keep the boot stable (see also FIGS. 1, 6 and 8.)
The axle pivot pin 61 includes two coupling features 27 to selectively lock the axle pivot pin 61 in hole 63 of the touring mode. The coupling features 27 are found securing either end of the axle pivot pin 61 to hold a quick-release lock anything suitable to quick-release or quick attach at least one end of the two on the axle pivot pin 61 in accordance with the present invention.
It must be noted that one skilled in the art could utilize a multitude of embodiments without leaving the scope of the invention. The invention is unique in that it offers a direct lock and unlocking boot mounting plate 90 on a sliding device with the said mounting plate 90 intended for soft shelled boots primarily. The mounting plate 90 having a detachable touring pivot 63 or movable touring pivot 63 with a secondary locking mechanism 70 in a mounting plate 90 portion rear of the touring mode 63. Thus we see that the mounting plate 90 does not need a snowboard binding base connected to it nor does it have the ability. The mounting plate already contains strap mounts and the climb and glide touring modes made possible by the axle pivot pin 61 which constitute the basics of the invention.
FIG. 26 is a bottom perspective view of a snowboard boot binding 201 mounting plate in accordance with the present invention. The snowboard boot binding 201 has quick release climbing traction 1502. The binding 201 also has a touring mode 64 with touring dock structure 1704 to selectively hold a mounting pin axle 1002. Mounting pin 1002 may also be moved to dock 1002 touring position or locked heel position depending on if heel lock 1702 is engaged or not. Flanges for securing straps can also be seen as part of the design. Window or aperture in the 1702 region can also be seen in this embodiment drawing. Snowboard boot binding 201 is very versatile allowing 4 positions of transportation across snow. A locked heel sliding stance with lock area 1702 and 1003 engaged, a secondary locked heel stance with 1704 and 1702 engaged, a free heel touring stance with 1702 and 1003 disengaged and 1704 engaged, and a secondary free heel touring stance with 1704 and 1702 disengaged while 1003 is engaged and finally, a detached mode or crampon mode wherein the snowboard boot binding 201 is detached from a ski device as just a crampon with 1502 attached.
FIG. 27 is a top plan view of a snowboard boot binding 201 incorporates all of the features described in FIG. 26 snowboard boot binding 201. FIG. 27 snowboard boot binding 201 has Flanges 204 for strap mounts 1102 for securing straps and the straps for securing a snowboard boot (not shown) to the snowboard boot binding 201 top surface 202 and directly over windows 1509. Touring modes 1704 and 1002 are shown. Touring mode 1002 is shown securing a axle pin 1002 in rails 205 on the front half portion 202 of the snowboard boot binding 201. Rails 205 in the rear half 203 of the snowboard boot binding 201 secure heel lock components 107 and interfaces of the riding device. Aperture/window 1509 of the snowboard boot binding 201 secure a climbing cleat interface 1506. In one embodiment the snowboard boot binding 201 is mounted directly to a ski device interface via 1002 axle pin.
FIG. 28 is a top plane view of a split ski/board device “climbing/touring mode” 600 with a snowboard boot binding 201 mounted to the said split ski/board device 600 with axle pivot pin 1002 in the snowboard boot binding 201 and the split ski/board device 600 interface. The split ski/board device “climbing/touring mode” 600 has two ski sections 100a/110b which have two modes and positions of travel arrangement. The first travel arrangement mode is an “open” split ski climbing mode shown in FIG. 28 wherein the two ski sections 110a/b are separated or split from each other forming a climbing mode while the snowboard boot binding 201 is also in a climbing mode interface. In one embodiment while in climbing mode 600 the heel lock 107 can be engaged in the heel region of the snowboard boot binding 201 preventing the snowboard boot binding 201 from articulating/rotating on axle 1002 and a further embodiment wherein the lock 107 is not engaging the snowboard boot binding 201 allowing the binding to freely move and articulate in a touring mode 1002 while connected to the split ski/board device touring or climbing/touring mode 600. When heel lock 107 is disengaged and unlocked from the snowboard boot binding 201 the binding can articulate in a walking motion while coupled to the split ski/board “climbing mode” 600. The ski device 600 has a front ski section 104 and a back ski section 106 that is generally shaped like a snowboard, skiboard, ski, or typical ski shape and the like. Rails and windows 203 in the snowboard boot binding 201 help with binding structure, locking mechanisms, supporting the boot and the like. (See also FIG. 6, FIG. 8, FIG. 30B, and FIG. 31)
FIG. 29 is a bottom plane view of a FIG. 28 climbing/touring 600 device transitioned into a sliding mode 700 split ski/board device “sliding mode” 700 with a snowboard boot binding 201 mounted to the said split ski/board device 700. The snowboard boot binding 201 mounted to and directly over the split ski/board device 700 two ski sections 702a and 702b. Said two ski sections have been locked with two ski section locks 107 locking two ski sections parallel to each under the snowboard boot binding forming a more uniform sliding or skiable surface and locked heel sliding stance for the rider of the split ski/board device 700 sliding mode. The ski shape of the sliding mode 700 could have side cut 708 of the ski edge to aid turning the ski device on snow. In a further embodiment the edge 708 could also have metal edging. The split ski/board device 700 has a front ski section 704 and a rear ski section 706 and the snowboard boot binding 201 mounted between the two ski sections 702a and 702b in accordance with the present invention and may be in the form of a board, ski, split ski/board, snowboard, touring ski, and the like. (see also FIGS. 9, 29, and 30A).
FIG. 30A is a top perspective view of a snowboard boot binding 201 mounted with axle pin 208 to a split ski/board device 100 in sliding mode 102. Two ski sections 110 locked side by side forming a uniform skiing surface with the snowboard boot binding positioned over the two ski sections 110 (see also FIG. 9, 29). Ski section hinges 108/112 assembly help with keeping the ski sections in a locked state. The snowboard boot binding 201 has features 204 for securing boot mounting devices to the binding 201. Heel lock 107 for the snowboard boot binding 201 locked heel mode 203 for sliding also secures the two ski sections 110 in the uniform sliding mode 102. Ski section lock 107 is shown on ski portion 106 and ski portion 104 allowing each ski section 110 at least two locks 107 to hold the ski sections 110 in a ski mode 102 though further embodiments could construct less or more ski lock or section scenarios. Touring mode interface 63 is shown along with front lock interface 208 with axle pin is also shown in the engaged state. Rail and aperture window 203 is shown as part of the snowboard boot binding 201 design in accordance with the present invention. Snowboard boot binding 201 is shown with an upward turned section at the toe region (202FIG. 30B).
FIG. 30B is a split ski/board device 100 in touring mode/climbing mode 202. The two ski sections 110 are separated using ski section locks 107 and releasing ski lock 104 from ski lock 107 interface. The snowboard boot binding 201 is in the touring mode 208 with axle pivot pin allowing articulation in the walking attached mode of the split ski/board device. Strap mounts 206 are available on flanges 204. The rear portion of the mounting plate 201 has a design of girders, beams, or rails and the like.
FIG. 31 is a bottom plan view of the snowboard boot binding 201 mounted to a split ski/board device 102 with the said device having at least two ski sections 110 which separate to form a touring mode. The two ski sections 110 are locked in ski mode (see FIGS. 9 and 29) by means of ski section 110 locks 107 and interface 408 and 406. The ski sections 110 in the climbing mode may have traction structure 404 to aid in touring and climbing. Additionally separate removable cleat traction 402a can also be implemented to create even more traction on the split ski shaped device.
FIG. 32 is a top plan view of the two ski sections 110 forming a uniform sliding position with ski section lock 107 engaged. Ski lock interface 406 is engaged with lock interface 107 pins 502. The snowboard boot binding 201 (not shown) is positioned directly over ski sections 110 in accordance with the present invention. The ski lock 107 may have structures 302 aiding in a quick release motion to lock and unlock the ski sections 110. Such structures could be spring loaded, memory flex, buttons, tabs, levers, and the like. In one embodiment, the ski sections may be joined under the snowboard boot binding and connected to a portion of the snowboard boot binding.
FIG. 33A is an illustration of a ski shaped device.
FIG. 33B is an illustration of a ski shaped devices 102 ability to expand skiable tour able surface by moving a plurality of ski sections parallel to each other selectively away from each other for a touring mode or selectively joining together forming a skiable sliding mode of winter travel on a ski shaped devices in combination with the snowboard boot binding, mounting plate, or mounting base of the present invention.
FIG. 34 is a flow chart 1200 illustrating a boot binding 1204 able to climb or glide 1206 a two section split ski/board touring device 1208 in a sliding mode 1209 or a touring mode 1210/1211 in accordance with the present invention.
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. All changes which come within meaning and range of equivalency of the claims are to be embraced within their scope.