The present invention pertains to binding strap mechanisms, and particularly to snow board binding strap mechanisms that ease securing a foot into a binding.
Snowboard bindings secure a snowboarder's foot onto his or her snowboard. Current bindings are effective during snowboarding, but still cumbersome to bind to a foot.
Snowboard binding need to be removed often, unlike ski bindings. This is because of the nature of most chair lifts. Upon boarding a chair lift, one foot needs to be removed from the snow board binding and reattached after exiting the chairlift. The reattachment of the one foot into the binding is preferably done rapidly and efficiently. Upon chairlift egress, the snowboarder typically slides down a slope with one foot bound and one free. The snowboarder must stop to re-attach the binding prior to commencing further down-hill travel.
Difficulty is found when the snow board binding strap overlays and area where the foot is to be inserted. This requires the snowboarder to bend over and physically remove the binding strap then insert the foot. This may sound simple, but when one is wearing bulky snow pants and a thick jacket, bending is not easy. On a slippery snow-covered hill there may be movement of the snowboard down the hill during this process. Accordingly it takes a special degree of skill to efficiently move the binding strap from the foot area, insert the foot into the binding while bent over, and to attach the binding strap. Both novices and experienced boarders recognize the cumbersome nature of re-attaching the binding every time a chairlift is used.
U.S. Pat. No. 6,679,515 B2 to Carrasca discloses a mechanism that helps the binding strap sets to more likely be free from the foot area. In particular, each binding strap set includes two sides. One side has a buckle and another side has ribs that engage the buckle. A hinge attaches the side with the buckle to the snowboard binding. The hinge enables the one side of the binding strap to flay open and thus enable the foot to be placed into the foot area of the binding.
While this represents a step forward in the art of binding straps, several drawbacks of this design are apparent. In particular there is a possibility when the binding strap is open such as during an exit from the chairlift that it could interfere with stability of the snowboard. There is also a possibility that the hinged side of the binding strap could flop inwards and cover the foot area thus providing little benefit to a snowboarder that must bend over and remove the strap from the foot area. A third drawback is that the hinge is in line with the strap. Every time the strap is tightened stress is endured by the hinge this creates a situation where either failure of the hinge is possible or very robust hinges are required.
U.S. Pat. No. 7,487,992 B2 to Pascal et al. discloses a pivoting binding strap hinge that biases a snowboard strap into the open position. While the pivoting binding strap hinge performs multiple functions, it also suffers from the drawback that the pivot mechanism and biasing mechanism are in line with the strap. This causes the mechanisms to endure stress applied by the strap.
U.S. Pat. No. 8,597,318 B2 to Hall discloses a strap design for snowboard bindings. Each strap is bifurcated with materials of varying thicknesses to enable the strap to naturally bias into an open position. This also represents a step forward in the art of snowboard bindings however, there are drawbacks. One limitation is that the width of the binding strap near where it's mounted to the snowboard binding is much greater than the width of a normal strap. This is cumbersome.
What is desired is a better way to bias a snowboard binding strap into an open position. It is also desired is a way of biasing the snowboard binding strap into an open position which is reliable, not cumbersome, and that can retrofit on existing snowboard straps.
The present invention includes a snowboard binding. The bindings have binding straps. The binding straps include binding strap assist mechanisms to bias the binding straps into an open position which enables a snowboard user to easily place his or her foot into a foot area of the binding. The bindings are then buckled and secured to maintain a snowboarder's foot in the bindings.
Biasing the binding straps and open configuration provides convenience and enables haste. The present invention is safe and even if the binding strap assist mechanism breaks or otherwise fails the binding straps continue to operate unhindered.
Two variations of the binding strap assist mechanism are disclosed one including a compression spring which generates power through axial compression and extension of the spring the compression spring is a helical spring. The other variation includes torsion spring which generates power from rotation of the spring about its axis.
In both embodiments provide the advantage of having a binding strap pass through each binding strap assist mechanism. The binding strap carries the tensile force necessary to hold a foot in the binding. The binding strap assist mechanism does not need to bear this tensile force.
The embodiment having the compression spring is advantageous because during use of the snowboard, the compression springs are compressed to limit the entry of particulate matter between the compression spring windings.
Additionally when the snowboard binding straps are released from a closed configuration to an open configuration the interstitial space between the compression spring windings expands releasing any particulate matter that could've been trapped between the coils of the compression spring.
Similarly, in the embodiment utilizing torsion spring the interstitial spaces between the coils of the torsion spring can be minimized when the binding straps are holding a foot during operation to inhibit accumulation of particulate matter. The interstitial space between spring windings is maximized when the binding straps move to the open configuration to release accumulated particulate matter such as ice or snow when the binding straps release the foot.
Accordingly the present invention provides a reliable, simple, lightweight and safe mechanism for assisting binding straps of the snowboard into an open configuration. This makes the present invention convenient to use.
In each embodiment the binding strap passes through the binding strap assist mechanism. This is a distinctive attribute of the present invention that enables the binding straps to bear the tensile load to firmly hold a foot in a binding.
The binding straps 20, 21, 22, and 23 are shown in an open position to enable the foot of a snowboarder to readily be placed in the foot area 15.
The binding straps 22 and 20 are positioned on the medial side of the binding 12. Both straps 20 and 22 are an open position. The straps 20 and 22 both include strap pads 24 and 26 that respectively pad and cover portions of the binding strap 22 and 20.
The binding straps 20 and 22 also include a clasp 28 and 30 respectively that are fixed on the pads 24 and 26, respectively, of the binding straps 20 and 22. The clasps 28 and 30 attached to a free ends of each respective pad 24 and 26 of the binding straps 20 and 22. The clasps 28 and 30 enable the binding straps 21 and 23 to adjustably mate with the binding straps 20 and 22, respectively.
The binding straps 20 and 22 are typically integrated to the strap pads 24 and 26, respectively though a fastener such as a bolt. The fastener is removable to enable disassembly of the binding straps 20 and 22. Disassembly of the binding straps 20 and 22 through use of the removable fastener enables the binding strap assist mechanism of the present invention to slide over each binding strap 20 and 22 into an operative position. The binding straps 20 ad 22 are then re-assembled by fastening the strap pads 24 and 26 into an original position.
Although a bolt is shown as an example of a removable fastener, any removable fastener used in snow board binding straps can be used in accordance with the present invention.
Each binding strap 20 and 22 further includes a binding strap assist mechanism 18 and 16 attached in a pass through arrangement on each binding strap 20 and 22, respectively. The strap assist mechanisms 18 and 16 bias the binding straps in the open position as shown.
The binding strap 20 and 22 pass through the binding strap assist mechanisms 18 and 16, respectively. It can be appreciated that when the binding straps 20 and 22 connect with the binding straps 21 and 23 to hold the foot in the binding 12 that tensile stress along the length of each of these binding straps is significant and sufficient to hold the foot in the binding during rigorous snowboarding activity. This tensile stress is isolated to the binding straps and only insignificantly affects the binding strap assist mechanisms 18 and 16. This is because the pass-through connection does not require the binding strap assist mechanisms 18 and 16 to endure these tensile stresses. Accordingly, the pass-through connection isolates tensile stress applied to the binding straps 20 and 22.
An advantage of the present invention is that the binding strap assist mechanisms can retrofit on existing snowboard bindings by simply removing the binding pads 26 and 24 and slidably connecting the binding strap assist mechanisms 18 and 16, respectively into place. Once in place the binding pads 26 and 24 can be remounted to the snowboard binding 12. In this embodiment, there is no need to remove the binding straps 20 and 22 to make the present invention retrofitable on existing bindings without the need for tools in most instances.
An alternate embodiment the snowboard bindings 12 originally equipped with the snowboard binding strap assist mechanisms and sold as a single unit. The advantage of utilizing the binding strap assist mechanisms 18 and 16 is that standard binding straps 20 and 22 can be utilized, thus eliminating the need for custom binding straps to achieve the goals of the present invention.
In yet another embodiment snowboard 10 is sold with bindings 12 attached the bindings 12 include the binding strap assist mechanisms 18 and 16 on the binding straps 20 and 22, respectively. The advantage of this is that a snowboard customer can test the efficacy of the present invention while making a purchase decision.
The binding straps 21 and 23 include grooves or teeth that adjustably slide into the latches (e.g. 28) of the respective binding straps 20 and 22.
The lever arm 32 and the lever arm 34 cooperate with the hinge 35 to form a buckle that holds the binding strap assist mechanism on a binding strap with friction.
The lever arm 32 is has a smooth end 38 for contacting the binding strap. The lever arm 34 includes a pin 40 contacting the binding strap. And the hinge 35 includes a smooth portion for contacting the binding strap. Together the smooth end 38, the pin 40 and the hinge 35 cooperate to hold the binding strap assist mechanism 18 in a desired position on the binding strap.
The lever arm 34 includes a reinforcement pin 36. The smooth end 38 of the lever arm 32 includes a reinforcement pin 37. The reinforcement pins assure that contact between a binding strap and the mechanism 18, does not deform the mechanism 18 due to contact between the binding strap and the regions of the mechanism 18 surrounding the reinforcement pins.
Manipulation of the lever arm 32 with respect to the lever arm 34 about the hinge 35 enable selective adjustment of the position of a binding strap assist mechanism 18 on a binding strap. Once manipulated into a desired position on a binding strap the cooperation of the smooth end 38, the pin 40 and the hinge 35 hold the binding strap assist mechanism 18 in the desired position.
The lever arm 34 includes constraint tabs 39 and 41 which are affixed to extend from the lever arm 34 in a position adjacent to pins 36 and 40. The constraint tabs inhibit undesired movement of the mechanism 18 on a binding strap while distancing the mechanism away from a binding strap to optimize moment forces that move the binding strap to an open configuration. The constraint tabs 39 and 41 assure optimal alignment of the mechanism 18 on a binding strap.
The lever arm 32 has an end 52 in contact with the compression spring 30. The lever arm 34 has an end 50 in direct contact with an opposite end of the compression spring 30. Relative movement between the lever arm 34 and the lever arm 32 in rotation about the hinge 35 compresses and extends the compression spring 30 in the directions of the arrows 56. It is shown that the ends 50 and 52 of the lever arms 32 and 34, respectively are angled slightly from each other, i.e. they are not axially aligned with each other. This assures that the spring 30 buckles slightly forming a curved axis. Buckling enables the spring 30 to apply energy both from axial extension and compression, but also from the buckling of the spring. Utilizing both compressive energy storage and energy storage yielded from buckling, the spring can apply more force against the mechanism 18 than would be possible through use of axial compressive forces only.
In the closed position the compression spring 30 is nearly fully compressed to optimize axial extension capability of the compression spring and to minimize interstitial space between the windings of the compression spring 30. Minimizing interstitial space between the windings of the compression spring minimizes the buildup of ice and snow or other disruptive particulate matter in the compression spring. Accordingly during use the compression spring 30 is less likely to become bound with particulate matter such as ice, dirt and snow.
Additionally operation of the compression spring 30 between the closed position is shown to an open position (
Accordingly operating a snowboard while utilizing the present invention for downhill travel when the compression spring closed position has the dual benefit of inhibiting buildup of particulate matter surrounding the coils of the compression spring by minimizing interstitial space between the spring windings during operation, and upon releasing the binding straps into the open position to increase such interstitial space and thereby release any built-up particulate matter.
The invention includes a method of attaching a binding strap assist mechanism to a snow board binding. The binding has straps that attach to hold a foot in the binding. Preparing the binding for attachment to a foot includes providing a binding strap having an integrated strap pad with a clasp. The strap pad being removeably attached to the binding strap with a removeably fastener or other device. The fastener can include a self-fastening fabric, or a threaded fastener, for example. Next, the strap pad is removed from the binding strap to make room for step of fastening the present invention to the binding strap.
Next, the binding strap assist mechanism slides over the binding strap. The binding strap assist mechanism includes a first lever arm and a second lever arm connected by a hinge. The hinge defines a spring side with a spring and a strap side that contacts a portion of the binding strap. The hinge moves to accommodate the binding strap. When the binding strap assist mechanism is optimally positioned on the binding strap the strap pad is replaced on the binding strap.
The spring is a helical spring that initially extends axially when the binding strap assist mechanism is attached to the binding strap, and the helical spring compresses axially when the binding strap is utilized to hold a foot in a snowboard.
Another method in accordance with the present invention attaches a foot into a snow board binding that includes a binding strap and the mechanism of the present invention. First, a snow board with a binding having a binding strap is provided. The binding strap having a binding strap assist mechanism to hold the binding strap in an open configuration. The binding strap assist mechanism includes two lever arms attached by hinge. The binding strap passes one side of the hinge, a spring mounts on another side of the hinge to bias the binding strap in the open configuration. The foot is inserted into the binding while the binding strap is in the open configuration. The foot is secured in the binding by moving the binding strap into a closed configuration. The spring compresses when the binding strap is in the closed configuration to inhibit snow from interfering with operation of the spring. The spring does not buckle when compressed, or buckles an insignificant amount. In this way the spring exerts at least 99% of its force in an axial direction with respect to the axis of the spring.
The spring extends when the binding strap is in the open configuration to release snow from the spring, particularly between the helical windings of the spring.
In a preferred embodiment, the spring buckles slightly when extended to exert an axial force, and additionally a force due to the flexion (buckling) of the spring. This enables a spring of compact design to be used. This also maximizes the amount of energy the spring can apply in moving the binding strap into an open configuration to receive a foot.
The hinged connection between the lever arm 34 and the lever arm 32 includes an axle 72 that press fits and extends through the smooth surfaces 70 and 68 of the lever arm 32. The lever arm 32 and the lever arm 34 cooperate to form a buckle that holds the binding strap assist mechanism 18 on a binding strap. The axle 72 also extends through a tube 73 defined on the lever arm 34.
The lever arm 32 is has a smooth end 38 for contacting the binding strap. The smooth end 38 is hollow for receiving a reinforcement bar 64 in a press fit arrangement. The reinforcement bar 64 improves the integrity and durability of the smooth end 38. The reinforcement bar 64 is made from stainless steel.
The lever arm 34 includes a smooth portion 40 for contacting a binding strap. The smooth portion 40 receives reinforcement bars 66 and 67 to improve the integrity and durability of the smooth portion 40. The reinforcement bars 64, 66 and 67 are made from stainless steel.
The cylinders 68 and 70 receive the hinge tube 73 of the lever arm 34 to form a portion of the hinge 35. The axle 72 inserts through the cylinders 68 and 70 and the hinge tube 73 of the lever arm 34 to hinge the lever arm 32 to the lever arm 34.
In an alternate embodiment, a single torsion spring can be used instead of the torsion springs 80 ad 82. In another alternate embodiment, the two torsion springs can be replaced with a one double torsion spring.
The lever arm 34 includes an end having a strap support plate 84. The strap support plate 84 lines the strap 20 and helps to prevent the strap 20 from contacting the ground beneath the snowboard when the binding strap assist mechanism 18 maintains an open configuration.
An advantage of this embodiment having the torsion spring design is that it is a low-profile and compact configuration that effectively biases a binding strap in an open configuration.
It can be appreciated that although the springs disclosed in the specification include compression and torsion springs having helically wound coils, the springs can also be made from any other material that stores energy when compressed or extended, or stores energy in response to torsion, and releases that energy in a manner similar to compression or torsion springs. Preferably the spring material would be able to endure temperatures of between −35° C. to 30° C. Additionally, the springs may include a cover to further achieve the goals of the invention. It can be further appreciated that the compression spring in various embodiments can also be replaced with multiple compression springs.
This patent application claims the benefit of U.S. Provisional Patent application No. 62/113,414, filed 7 Feb. 2015, and U.S. Provisional Patent Application No. 62/138,314, filed 25 Mar. 2015, the disclosures of which are incorporated herein by reference. This patent application is also a continuation-in-part of co-pending U.S. Design patent application No. 29519129, filed 2 Mar. 2015, the disclosure of which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 29519129 | Mar 2015 | US |
Child | 15017625 | US |