The present disclosure is generally directed to ski and binding systems and methods.
Ski binding systems are used to attach a boot to a ski. Ideally, the binding system keeps boot securely attached to the ski during normal use, but releases the boot from the ski during a fall or other mishap in order to prevent the ski from exerting undue torque, tension or force on the skier's leg and thereby causing injury. Present day ski binding systems in mass production use mechanical means, e.g. spring-loaded clamps, to affix the boot to the ski during use and release the boot. Such mechanical means are affixed permanently to the top of the ski, and are designed to mechanically couple with the boots with which they are used. However, existing ski binding systems do not always release when appropriate to prevent injury, and sometimes release at inappropriate times, in particular when the ski flexes during use. Thus, there is a need for improved binding systems.
Some aspects and/or embodiments thereof disclosed herein are directed to a system, apparatus and/or method that use a controllable solenoid in releasably retaining a boot to a ski.
In some aspects, an apparatus for use in releasably retaining a boot plate to a ski comprises: a binding plate attachable to the ski and having a surface to receive the boot plate; a first clamp rotatably coupled to the binding plate; a second clamp spaced laterally from the first clamp and rotatably coupled to the binding plate, wherein the first and second clamps have a first position in which the first and second clamps releasably retain the boot plate to the binding plate, and wherein the first and second clamps have a second position in which the first and second clamps release the boot plate; a solenoid defining a channel and controllable to provide a first state and a second state; a plunger having a first end slidably received within the channel, the plunger having a first plunger position associated with the first state of the solenoid and a second plunger position associated with the second state of the solenoid; and mechanical linkage disposed at least in part between the plunger and the first and second clamps and movably coupled to the binding plate to cause the first and second clamps to rotate toward their second position if the plunger moves from the first plunger position to the second plunger position.
In at least some embodiments, the apparatus further comprises a control system coupled to the solenoid.
In at least some embodiments the mechanical linkage comprises: a slide disposed at least in part between the first and second clamps and slidably coupled to the binding plate, wherein the slide has a first slide position and a second slide position that is forward of the first slide position and in which the slide applies force to the first and second clamps to force the first and second clamps toward their second position; a lever pivotably coupled to the binding plate, the lever having a first lever position and a second lever position and biased toward the second lever position; and a link pivotably coupled between the slide and the lever; wherein with the lever in the first lever position and the plunger in the first plunger position, the plunger prevents the lever from pivoting from the first lever position to the second lever position, and wherein with the plunger in the second plunger position the plunger does not prevent the lever from pivoting from the first lever position to the second lever position.
In at least some embodiments the mechanical linkage comprises: a first motion converter coupled to the first clamp; a second motion converter coupled to the second clamp; a first link coupled to the first cam; a second link coupled to the second cam; and a coupler coupled between the plunger and the first link and coupled between the plunger and the second link.
In at least some embodiments, the first motion converter comprises a first cam; and the second motion converter comprises a second cam.
In some aspects, apparatus for use in releasably retaining a boot plate to a ski comprises: a binding plate attachable to the ski and having a surface to receive the boot plate; a first clamp having a first jaw and a first arm coupled thereto; a second clamp having a second jaw and a second arm coupled thereto, wherein the first and second arms are laterally spaced from one another and pivotably coupled to the binding plate, wherein the first and second arms have a first position in which the first and second jaws have a first lateral spacing and releasably retain the boot plate to the binding plate, and wherein the first and second arms have a second position in which the first and second jaws have a second lateral spacing greater than the first lateral spacing and are spaced apart from the boot plate; a slide disposed at least in part between the first and second arms and slidably coupled to the binding plate, wherein the slide has a first slide position and a second slide position that is forward of the first slide position and in which the slide applies force to the first and second arms to force the first and second arms toward their second position; a lever pivotably coupled to the binding plate, the lever having a first lever position and a second lever position and biased toward the second lever position, the lever having a portion displaced forward if the lever pivots from the first lever position to the second lever position; a link pivotably coupled between the lever and the portion of the lever that is displaced forward if the lever pivots from the first lever position to the second lever position such that the slide is pulled toward the second slide position that is forward of the first slide position if the lever pivots from the first lever position to the second lever position; a solenoid defining a channel and controllable to provide a first state and a second state; and a plunger having a first end slidably received within the channel, the plunger having a first plunger position associated with the first state of the solenoid and a second plunger position associated with the second state of the solenoid; wherein with the lever in the first lever position and the plunger in the first plunger position, the plunger prevents the lever from pivoting from the first lever position to the second lever position, and wherein with the plunger in the second plunger position the plunger does not prevent the lever from pivoting from the first lever position to the second lever position.
In at least some embodiments, the apparatus further comprises a control system coupled to the solenoid.
In at least some embodiments, the apparatus comprises a spring to bias the lever toward the second lever position.
In at least some embodiments, the second plunger position is forward of the first plunger position.
In at least some embodiments, the plunger includes a second end and with the lever in the first lever position and the plunger in the first plunger position, the second end of the plunger is in contact with a surface of the lever to prevent the lever from pivoting from the first lever position to the second lever position.
In at least some embodiments, the second end of the plunger includes a rear facing surface and with the lever in the first lever position and the plunger in the first plunger position, the rear facing surface of the second end of the plunger is in contact with the surface of the lever to prevent the lever from pivoting from the first lever position to the second lever position.
In at least some embodiments, with the lever in the first lever position and the plunger in the first plunger position, only a portion of the rear facing surface of the second end of the plunger is in contact with the surface of the lever to prevent the lever from pivoting from the first lever position to the second lever position.
In at least some embodiments, a lateral width of the portion of the rear facing surface is no greater than one half a lateral width of the rear facing surface.
In at least some embodiments, the apparatus includes: a first pivot pivotably coupling the lever to the binding plate; a second pivot pivotably coupling the linkage to the lever; and a third pivot pivotably coupling the linkage to the slide.
In at least some embodiments, with the lever in the first lever position, the first, second and third pivots are each disposed at least in part on a same line.
In at least some embodiments, with the lever in the second lever position, the first and third pivots each remain disposed at least in part on the line.
Some aspects and/or embodiments thereof disclosed herein are directed to a system, apparatus and/or method for use in binding a ski to a ski boot during use, using controllable electromagnets and/or permanent magnets to keep the boot in place, and using information obtained from electronic sensors to determine when to release the binding by disabling the electromagnets and/or enabling the electromagnets so as to counteract the permanent magnets.
In some aspects, apparatus for use in releasably retaining a boot plate to a ski comprises: a binding plate attachable to the ski, the binding plate including a surface to receive the boot plate and an electromagnet to receive electrical power and provide a magnetic force in response thereto to attract the boot plate to the surface of the binding plate.
In at least some embodiments, the apparatus further comprises a control system coupled to the electromagnet.
In at least some embodiments, the surface of the binding plate includes a raised portion.
In at least some embodiments, the binding plate includes a plurality of electromagnets to receive electrical power and provide a magnetic force in response thereto to attract the boot plate to the surface of the binding plate.
In at least some aspects, the binding plate comprises a toe plate and a heel plate spaced apart from the toe plate, the toe plate includes the electromagnet and the heel plates includes an electromagnet to receive electrical power and provide a magnetic force in response thereto to attract the boot plate to the surface of the binding plate.
In at least some embodiments, the surface of the binding plate includes a plurality of raised portions.
In at least some embodiments, the surface of the toe plate defines one of the plurality of raised portions and wherein the surface of the heel plate defines another of the plurality of raised portions.
In some aspects, apparatus comprises: a boot plate comprising a material attracted by a magnetic field from a permanent magnet; a binding plate attachable to a ski, the binding plate including a surface to receive the boot plate and an electromagnet to receive electrical power and provide a magnetic force in response thereto. In one embodiment, the electromagnet acts to negate a magnetic field that attracts the boot plate to the surface of the binding plate. In another embodiment, the electromagnet provides the force to keep the boot plate and the surface of the binding in contact. That is, some embodiments use an electromagnet to add closing force to keep the boot and binding plate together, while in other embodiments the electromagnet is used to apply a repulsive force to overcome the force of the permanent magnet so as to release the boot from the binding.
In at least some embodiments, the apparatus further comprises a control system coupled to the electromagnet.
In at least some embodiments, the boot plate comprises a ferromagnetic material.
In at least some embodiments, the surface of the binding plate includes a raised portion and wherein the boot plate defines an indentation to receive the raised portion.
In at least some embodiments, the surface of the binding plate includes a plurality of raised portions and wherein the boot plate defines a plurality of indentations to receive the plurality of raised portions.
Some aspects and/or embodiments thereof are shown and/or otherwise described herein in the context of alpine skiing, but the aspects and/or embodiments thereof can also be used for cross-country skiing, snowboarding, or any similar activity in which a boot or shoe worn by the user is affixed to a ski, board or other similar implement.
This overview is intended to provide an overview of subject matter of the present patent application. It is not intended to provide an exclusive or exhaustive explanation of the invention. Further limitations and disadvantages of conventional and traditional approaches will become apparent to one of skill in the art, through comparison of such systems with some aspects of the present invention as set forth in the remainder of the present application with reference to the drawings.
The aspects and embodiments described above, as well as additional aspects and embodiments, are described further below. These aspects and/or embodiments may be used individually, all together, or in any combination of two or more, as the technology described herein is not limited in this respect.
For a fuller understanding of the nature and advantages of the present invention, reference is made to the following detailed description of preferred embodiments and in connection with the accompanying drawings, in which:
The following description and drawings set forth certain illustrative implementations of the disclosure in detail, which are indicative of several exemplary ways in which the various principles of the disclosure may be carried out. The illustrative examples, however, are not exhaustive of the many possible embodiments of the disclosure.
Some aspects disclosed herein are directed to a binding system that includes a solenoid to initiate release of a boot from a ski. The binding system may further include a control system having an electrical power source in electrical communication with the solenoid. In at least some embodiments, the binding system is intended to be used in lieu of a conventional ski binding system.
Referring to
Unless stated otherwise, the term “ski” is used herein to mean a ski for any type of skiing, a board for snowboarding and/or a ski or other type of board for any other activity in which a boot or shoe worn (or to be worn) by a user is to be releasably affixed to the ski or other type of board.
The binding system 104 may be mounted (directly and/or indirectly) to an upper and/or other surface of the ski 102. The boot plate 106 may be attached (directly and/or indirectly) to a sole and/or other portion of the boot 108 (e.g., using screws (or other fasteners (threaded or otherwise)), claws and/or any other type of fasteners (not shown)). The boot plate 106 may also be releasably attached to the binding system 104, (thereby releasably attaching the boot 108 to the binding system 104), sometimes referred to herein as a first (or releasably attached) state.
The system 100 may have a longitudinal axis 110 (
Referring also now to
The binding system 104 and/or binding plate 120 may have a longitudinal axis 126 (
Referring also now to
The two clamps 122, 124 may each comprise an arm and a jaw coupled to the arm. In at least some embodiments, including but not limited to the illustrated embodiment, the clamp 122 may comprise an arm 142 and a jaw 146 coupled to the arm 142. The clamp 124 may comprise an arm 152 and a jaw 156 coupled to the arm 152.
The arms 142, 152 may be elongated and laterally spaced from one another, and may be pivotably coupled to the binding plate 120 by bolts 148, 158 (
In at least some embodiments, including but not limited to the illustrated embodiment, the arms 142, 152 are disposed on opposite sides of and/or spaced laterally from the longitudinal axis 110 and/or the longitudinal axis 126, and may pivot towards (to become closer to) and away from (to become further from) the longitudinal axis 110 and/or the longitudinal axis 126.
The arms 142, 152 may have a first position (e.g.,
In at least some embodiments, the first position of the arms 142, 152 may be a position of the arms 142, 152 that is most (pivotably) laterally inward. In at least some embodiments, with the arms 142, 152 in their first position, the jaws 146, 156 contact the boot plate 106 and force the boot plate 106 against the binding plate 120 or otherwise trap the boot plate 106 relative to the binding plate 120, to thereby releasably attach the boot plate 106 (and a boot, e.g., boot 108, to which the boot plate 106 is attached) to the binding plate 120, and in doing so, prevent or otherwise limit movement of the boot plate 106 relative to the binding plate 120. In at least some embodiments, movement may be prevented or otherwise limited in three dimensions (e.g., longitudinal, lateral and vertical).
In at least some embodiments, the second position of the arms 142, 152 may be a position of the arms that is most (pivotably) laterally outward. In at least some embodiments, with arms 142, 152 in their second position, the jaws 146, 156 may be in their position that is most spaced apart from the boot plate 106 such that the boot plate 106 (and a boot, e.g., boot 108, to which the boot plate 106 is attached) is most easily removed from the binding plate 120.
The binding system 104 may further include a processor controlled latch and release system 160 (
The control system 162 may be coupled to the solenoid 168 and configured to receive one or more signals, from one or more sensors or otherwise, indicative of one or more conditions of the system, and to determine, based at least in part thereon, whether (and/or when) to power the solenoid 168 to initiate release of the boot plate 106 (and boot 108 to which the boot plate 106 is mounted).
As stated above, ideally, a binding system keeps the boot plate (and thus the boot attached thereto) securely attached to the ski during normal use, and releases the boot plate (and thus the boot attached thereto) from the ski during a fall or other mishap in order to prevent the ski from exerting undue torque, tension or force on the skier's leg and thereby causing injury.
The control system 162 may have a centralized or distributed architecture. In at least some embodiments, one or more portions of the control system 162 may be disposed on or otherwise coupled to the binding plate 120. In some at least some embodiments, one or more portions of the control system 162 may be disposed on or otherwise coupled to the skier and/or an article (e.g., clothing or otherwise) worn by the skier.
The slide 164 may be disposed at least in part between arms 142, 152 of clamps 122, 124, respectively, and may be slidably coupled to the binding plate 120 so as to be slidable in longitudinal directions 112 and/or longitudinal directions 128. In at least some embodiments, the slide has a first position (e.g.,
As used herein, the term “forward of” means “closer to a front of the binding plate than is”.
As used herein, the term “rearward of” means “closer to a rear of the binding plate than is”.
In at least some embodiments, the slide 164 may be centered about or otherwise disposed on the longitudinal axis 110 and/or the longitudinal axis 126.
The slide 164 may include a body 182 and a head 184 or other abutment coupled thereto. The body 182 may extend in (or at least substantially in) longitudinal directions 112 and/or longitudinal directions 128. The head 184 or other abutment may be elongated in a lateral direction and may have a lateral width greater than that of the body 182 with portions, on laterally opposite sides of the head 184 or other abutment, that extend laterally beyond the sides of the body 182.
The head 184 or other abutment may define abutment surfaces 190, 192, 194, 196. Abutment surfaces 190, 192 may be disposed on a rear side and/or rear surfaces of the head 184 or other abutment. Abutment surfaces 194, 196 may be disposed on a front side and/or front surfaces of the head 184 or other abutment.
The abutment surfaces 190, 192, 194, 196 may be configured to contact abutment surfaces 200, 202, 204, 206, respectively, of clamps 122, 124. In at least some embodiments, the clamps 122, 124 define channels 208 (
In at least some embodiments, the abutment surfaces 190, 192 of the slide 164 define a catch to force the arms laterally inward (and/or toward their first position) and/or to trap the arms in their laterally inward position. To facilitate such, the abutment surfaces 190, 200 may be angled and/or complementary. The abutment surfaces 192, 202 may be angled and/or complementary.
In at least some embodiments, the abutment surfaces 194, 196 of the slide 164 define a wedge to force the arms laterally outward and/or toward their second position. The abutment surfaces 194, 204 may be angled and complementary to one another to facilitate sliding contact therebetween. The abutment surfaces 196, 206 may be angled and complementary to one another to facilitate sliding contact therebetween.
The slide 164 may define a slot 220 or other channel, which may be elongated and may extend in (or at least substantially in) longitudinal directions 112 and/or longitudinal directions 128.
As used herein, the term “at least substantially in” means “in, +/−5 degrees,”.
The slot 220 or other channel may receive a rail 222 or other raised portion that extends from or is otherwise coupled to the binding plate 120 to guide at least in part sliding movement of the slide 164 relative to the binding plate 120. In some other embodiments, the binding plate 120 may define the slot 220 or other channel and the slide 164 may define the rail 222 or other raised portion.
The solenoid 168 may have a first state (e.g., unpowered,
The plunger 170, which may also be elongated and may extend in (or at least substantially in) the longitudinal directions 112 and/or the longitudinal directions 128, may include a first (or proximal) end 228 (
The plunger 170 may have a first position (e.g.,
The lever 174, the spring 176 (or other bias element(s)) and the link 178, may collectively define a mechanical amplifier that is disposed at least in part between the plunger 170 and the slide 164.
The lever 174 may be pivotably coupled to the binding plate 120 by a shaft 240 or other type of pivot. Thus, the lever 174 may have a first position (e.g.,
The lever 174 may be elongated and may have first and second ends 241, 242. The shaft 240 (or other pivot) may be disposed at, proximal to or otherwise toward the first end 241. The lever 174 may define a bend having a centerline 243 (
As used herein, the term “toward the second end” means closer to the second end than to the first end.
The lever 174 further includes an abutment surface 244. In at least some embodiments, the abutment surface 244 may be disposed at or otherwise proximal to the first end 241.
In the first position (e.g.,
In the second position (e.g.,
In at least some embodiments, lateral direction(s) is/are perpendicular to longitudinal directions 112 and/or longitudinal directions 128.
In at least some embodiments, with the lever 174 in the second position, the lever 174 may extend in a direction that is pivotally offset from the first position by 90 degrees or substantially 90 degrees.
As used herein, the term “substantially 90 degrees” means 90 degrees+/−10%.
In at least some embodiments, with the lever 174 in the second position, the lever 174 may extend in a direction that is pivotally offset from the first position by an angle in the range of 60 degrees to 120 degrees.
In at least some embodiment, with the lever 174 in its first position and the solenoid 168 in its first state (
In at least some embodiments, the contact is provided by only a portion of the rear facing surface of the second end 230 of the plunger 170. In at least some embodiments, a lateral width 260 of such portion of the rear facing surface is no greater than one half a lateral width 262 of the rear facing surface. In at least some embodiments, this may reduce the possibility of undesired interference between the plunger and the lever and/or speed release of the boot plate 106 when it is desired to release the boot plate 106.
The lever 174 further includes a portion 245 that is displaced forwardly if the lever 174 pivots from the first position to the second position.
As used herein, the term “displaced forwardly” means “displaced so as to be closer to a front of the binding plate,” and does not preclude additional displacements in other dimensions, e.g., laterally in addition to forwardly. (In the illustrated embodiment, the portion 245 is also displaced laterally.)
In at least some embodiments, the lever 174 is rigid and/or has a fixed shape.
The spring 176 or other bias element(s) may have first and second ends 270, 272 (
A second end 272 of the spring 176 or other bias element(s) may be coupled to the binding plate 120. In at least some embodiments, the second end 272 of the spring 176 or other bias element(s) may attach to a location of the binding plate 120 that is laterally offset from the first shaft 240 or other pivot. In at least some embodiments, the location may have the same longitudinal position as the first shaft 240. In at least some other embodiments, the location may be forward of or rearward of the first shaft 240.
The link 178 is coupled (directly and/or indirectly) between the slide 164 and the lever 174. Thus, the link 178 may also have a first position (e.g.,
In at least some embodiments, the link 178 is pivotably coupled to the lever 174 by a shaft 246 (or other pivot) and pivotably coupled to the slide 164 by a shaft 248 (or other pivot).
The link 178 may be elongated and may have first and second ends 250, 252. One shaft 246 (or other pivot) may be disposed at, proximate to or otherwise toward the first end 250. The other shaft 248 (or other pivot) may be disposed at, proximate to or otherwise toward the second end 252.
In at least some embodiments, the link 178 has a rigid and/or a fixed shape. In at least some embodiments, the link comprises only one link stage. In at least some embodiments, the link comprises one link stage that includes a plurality of parallel link portions 256, 258 (e.g.,
In at least some embodiments, the link 178 attaches to the lever at a portion 245 of the lever 174 that is displaced forward if the lever 174 pivots from its first position to its second position so as to cause the slide to be pulled forward if the lever pivots from the first lever position to the second lever position. In at least some embodiments, the link 178 attaches to the lever 174 at, proximal to or otherwise toward the second end 242 of the lever 174. In at least some embodiments, this may increase forward displacement of the slide 164 in the second state, which may speed or otherwise assist in release of the boot plate 106.
In at least some embodiments, the link 178 attaches at a portion of the lever 174 that is displaced forwardly by an amount that is at least 50% of the amount that the second end 242 of the lever 174 is displaced forwardly.
In its second position (e.g.,
As used herein, the term “substantially 45 degrees” means 45 degrees+/−10%.
In some embodiments, in its second position (e.g.,
The location of the three shafts 240, 246, 248 or other types of pivots may be chosen such that with the lever 174 in its first position, the link 178 may also extend in (or at least substantially in) longitudinal directions 112 and/or longitudinal directions 128, and may be aligned with the lever 174. In some embodiments, the above may include arranging the three shafts 240, 246, 248 or other type pivots so as to be at least in part on a same line 254. In at least some embodiments, with the lever 174 in its second position, two of the shafts 240, 248 or other type pivots may remain disposed at least in part on the line 254.
In at least some embodiments, the binding system 104 has a latch state (e.g.,
In at least some embodiments, the release state operates as follows. The solenoid 168 is powered (energized) and the resulting magnetic field results in a force that counters the bias of the spring 232 or other bias element and pulls the plunger 170 out of contact with the lever 174, thereby allowing the lever 174 to pivot from its first position to its second position, in response to bias from the spring 176 or other bias element. As the lever 174 pivots, the portion 245 is displaced forwardly. The forward displacement causes the slide 164 coupled to the second end 252 of the link 178 to move toward a second position (e.g.,
In at least some embodiments, the binding system 104 may further include one or more additional solenoid, e.g., solenoids 280, 282 (which may be controlled by the control system 162) and/or one or more other bias element that is coupled to one or more portions of the binding system 104 to provide one or more additional force, e.g., force 284, 286, respectively, or other bias to supplement one or more force or other bias provided by the lever 174, spring 176 and/or link 178 to speed or otherwise assist in release of the boot plate 106 (and boot 108 attached thereto).
In at least some embodiments, the binding system 104 further includes a step-in closure.
In at least some embodiments, the binding system 104 may have a step-in closure as described above with respect to
Referring now to
In an aspect, a servo motor can be used to retract the slide 164 of
Some of the following embodiments are directed to a type of ski binding system, for affixing a skier's boot to a ski during use, that primarily uses controllable electromagnets and/or permanent magnets to hold the boot in place and negating electromagnets (operating counter to the permanent magnet's force) to release when appropriate. In a typical embodiment, the system consists of a binding, or one or more binding plates, that is/are mounted on the top of a ski, and a metal boot plate or plates that is/are mounted on the bottom of a ski boot. In an embodiment, the binding comprises a piece of somewhat stiff rubber or other similar material with a plurality of permanent electromagnets embedded therein. The permanent magnets turn off or turn on depending on whether a current is passed through them. The binding also comprises an electrical power source and microprocessor that are in electrical communication with the electromagnets, and that allow the electromagnets to be enabled or disabled. The binding system is intended to be used in lieu of conventional, mechanical ski binding systems, but in some embodiments may be used in conjunction with such systems.
Although twelve round electromagnets 2108 are shown, in at least some embodiments, other quantities, shapes and/or sizes of electromagnets may be used. Additionally, although the electromagnets 2108 are shown in an array (2×6), in at least some embodiments, other arrangements of electromagnets may be used.
The boot plate 2606 can be constructed of any ferromagnetic material of sufficient strength, preferably stamped steel. The boot plate 2602 can be attached to the bottom of a ski boot (e.g.,
Although three round electromagnets 3528 are shown and described, in at least some embodiments, other quantities, shapes and/or sizes of electromagnets may be used. Additionally, although the electromagnets 3528 are shown in an array (1×3), in at least some embodiments, other arrangements of electromagnets may be used.
Only one sided of the binding plates 3510, 3512 can be seen in
The ability of the binding plates 3510, 3512 to pivot and translate permits the binding plates 3510, 3512 to maintain good contact with a ski boot while the ski 3502 flexes during use. Such flexing changes the distance between the mounting brackets 3516, 3518 for the toe plate 3510 and the heel plate 3512, as well as the angle between them. A conventional, mechanical ski binding system typically has a forward pressure spring that keeps the toe of the boot pressed forward into front toe latch. Since the toe and heel mechanisms in such systems are rigidly attached to the ski, the ski's flexing during use pushes these mechanisms together and pulls them apart, which can result in premature release, particularly during conditions of high flexing, such as bumpy terrain, or racing conditions, and so forth. In the present ski binding system 3504, by allowing the binding plates 3510, 3512 to pivot and the heel plate 3512 to translate, the binding plates 3510, 3512 can maintain full contact with the underside of the boot (which is much more rigid than the ski) at all times while the ski 3502 flexes.
The top surfaces of the binding plates 3510, 3512 depicted in
In
The electrical power source and microprocessor (not shown in the illustrations) allow the magnets, e.g., magnets 2108 and/or magnets 3528, to be switched on and off as appropriate, such as when a user is putting on or taking off his/her skis, e.g., ski 2402 and/or ski 3502, or when a release is appropriate to prevent injury to the user. The power source can comprise a rechargeable battery, such as a lithium ion battery, a lithium polymer battery, and/or a capacitor. The capacitor may in some embodiments comprise part of the laminate of the ski, e.g., ski 2402 and/or ski 3502. In some embodiments, the invention comprises piezoelectric transducers that harvest energy from vibrations of the ski, e.g., ski 2402 and/or ski 3502, during use and use such energy to recharge the battery and/or capacitor that is used to power the magnets, e.g., magnets 2108 and/or magnets 3528, in the binder, e.g., binding 2104 and/or binding 3504 and/or the processor and/or the solenoid.
The microprocessor is in electrical communication, by either wired or wireless means, with one or more strain gauges, pressure transducers, accelerometers and/or other mechanical sensors (collectively, sensors). Such sensors can be attached to the ski 3502, the boot 3908 and/or the skier and/or other equipment or clothing worn by him/her. In some embodiments sensors, e.g. pressure sensors, are located inside the boot 3908, such as between the plastic shell and the soft liner of the boot 3908. The microprocessor continuously receives signals from these sensors and determines, based on such signals, when to transmit a signal to disable the magnets 3528, or enable magnets that will counteract other magnets in the binding, and thereby release boot from the binding. In some embodiments the boot plates are held to the binding plates by permanent magnets, which are active in the absence of any electrical current or signal, embedded in the binding plates, and the boot plates are released from the binding plates by means of electromagnets embedded in the binding plates, activated by the microprocessor, that create a magnetic field in the opposite direction from that created by the permanent magnets, such that the magnetic fields superpose and largely cancel each other, to a degree sufficient to weaken the resulting magnetic force holding the boot plates and binding plates together, and thus release them from each other. In some embodiments, the electromagnets may be configured so that they reinforce the magnetic fields created by permanent magnets during use, thus providing a strong magnetic attractive force between the boots and the bindings, and so that the electromagnets reverse polarity in the case of a release event, allowing them to create a magnetic field that will offset the field created by the permanent magnets.
In some embodiments, the binding system operates by creating magnetic attractive forces, or “clamping” forces, between binding plates and boot plates, that are designed to be of magnitudes such that the clamping forces will not hold them together if there is sufficient external force pulling or twisting them apart, such as could be experienced during use if the skier loses control. In other words, the bindings are designed to create a mechanical threshold, whereby the bindings would no longer hold the skier if this threshold is overcome, even in the absence of any signal from the microprocessor to reduce the magnetic force holding the boot plates to the binding plates, thus providing an additional layer of safety.
The magnitudes of the clamping forces during use, as well as the parameters used by the microprocessor in determining when to send a release signal, are adjustable, by mechanical means such as adjustment screws and/or electronic means such as commands transmitted to the microprocessor. In this way adjustments can be made to accommodate the mass and height of the skier, the terrain, the intended skiing style, and so forth.
Although reference has been made to a microprocessor, the systems disclosed herein are not limited to use of a microprocessor. In at least some embodiments, the systems disclosed herein may include a processor of any type.
Referring to
In at least some embodiments, the one or more power circuit 5564 may comprise one or more power supply 5570 and one or more power switch 5572. The one or more power supply 5570 may comprise one or more battery (rechargeable or otherwise) and/or any other type of power source(s). The one or more power switch 5572 may comprise one or more power semiconductor devices and/or any other type(s) of power switch(es).
The control system 162 may further include a plurality of signal lines or other communication links 5566 that couple the processor 5560 to the plurality of sensors 5562 and one or more control line or other communication link(s) 5568 that couple the processor 5560 to the one or more power circuit 5564.
The control system 162 may further comprise one or more power line or other power link(s) 5574 from the one or more power circuit 5564 to the solenoid 168 and/or other portion(s) of the binding system 104.
The control system 162 may further include a plurality of status indicators 5580 and a plurality of signal lines or other communication links 5582 that couple the processor 5560 to the plurality of status indicators 5580. The plurality of status indicators 5580 may indicate one or more status of the control system 162 and/or the binding system 104.
The control system 162 may further include one or more communication link 5590 to one or more user device 5592.
Unless stated otherwise, a “user device” may comprise a smart phone, a tablet and/or any other type of computing device (mobile or otherwise).
In at least some embodiments, one or more of the one or more user device 5592 may comprise a computing device (mobile or otherwise) of a user that is using and/or will use the binding system 104.
In operation, in at least some embodiments, the processor 5560 receives one or more signals, from one or more of the plurality of sensors 5562 or otherwise, indicative of one or more conditions of the skier and/or system 100 (or portion(s) thereof), and determines, based at least in part thereon, whether (and/or when) to power the solenoid 168 to initiate release of the boot plate 106 (and boot 108 to which the boot plate 106 is mounted). In at least some embodiments, if the processor 5560 determines to initiate release, the processor 5560 generates one or more control signal to initiate release, which may be supplied to the one or more power circuit 5564 via the one or more control line or other communication link(s) 5568. The one or more power circuit 5564 receives the one or more control signal from the processor 5560 and in response at least thereto, provides power to the solenoid 168 and/or other portion(s) of the binding system 104 via one or more of the one or more power line or other power link(s) 5574.
In at least some embodiments, the one or more power supply 5570 may comprise one or more rechargeable battery, such as a lithium ion battery, a lithium polymer battery, and/or a capacitor. The capacitor may in some embodiments comprise part of the laminate of the ski, e.g., ski 102. In some embodiments, the system 100 may include piezoelectric transducers that harvest energy from vibrations of the ski, e.g., ski 102, during use and use such energy to recharge the battery and/or capacitor.
In at least some embodiments, the plurality of sensors 5562 may comprise one or more strain gauges, pressure transducers, accelerometers and/or other mechanical sensors (collectively, sensors). Such sensors can be attached to the ski 102, the boot 108 and/or the skier and/or other equipment or clothing worn by the skier. In some embodiments one or more sensors, e.g. pressure sensors, may be located inside the boot 108, such as between the plastic shell and the soft liner of the boot 108.
In at least some embodiments, the processor 5560 may continuously receive signals from the plurality of sensors 5562 and determine, based at least in part on such signals, whether (and/or when) to initiate release of the boot plate 106 and/or boot 108.
In at least some embodiments, any of the binding systems disclosed herein may include a control system having one or more portions that are the same as and/or similar to one or more portions of the control system 162 of the binding system 104.
In some embodiments, one or more of the methods (or portion(s) thereof) disclosed herein may be performed by a system, apparatus and/or device having an architecture that is the same as or similar to the architecture 5500 (or portion(s) thereof). The architecture may be implemented as a distributed architecture or a non-distributed architecture.
Referring to
In at least some embodiments, the architecture 5500 may include one or more communication devices 5540, which may be used to interconnect the architecture to one or more other devices and/or systems, such as, for example, one or more networks in any suitable form, including a local area network or a wide area network, such as an enterprise network, and intelligent network (IN) or the Internet. Such networks may be based on any suitable technology and may operate according to any suitable protocol and may include wireless networks or wired networks.
In at least some embodiments, the architecture 5500 may have one or more input devices 5545 and/or one or more output devices 5550. These devices can be used, among other things, to present a user interface. Examples of output devices that may be used to provide a user interface include printers or display screens for visual presentation of output and speakers or other sound generating devices for audible presentation of output. Examples of input devices that may be used for a user interface include keyboards, and pointing devices, such as mice, touch pads, and digitizing tablets. As another example, the architecture 5500 may receive input information through speech recognition or in other audible formats.
In at least some embodiments, the method (or one or more portion(s) thereof) may be performed by one or more of the systems or portion(s) thereof, described herein.
In at least some embodiments, the method (or one or more portion(s) thereof) may be performed by the processor 5560.
The method is not limited to the order shown, but rather may be performed in any practicable order. For that matter, any method disclosed herein is not limited to any particular order but rather may be performed in any practicable order.
One or more portions of the method may be used without one or more other portions of the method. For that matter, one or more portions of any method (or system) disclosed herein may be used without one or more other portions of such method (or system).
In at least some embodiments, the method (or one or more portion(s) thereof) may be performed using one or more portions of one or more other methods disclosed herein. For that matter, in at least some embodiments, any method (or one or more portions thereof) disclosed herein may be performed using one or more portions of one or more other methods disclosed herein.
In at least some embodiments, the method (or one or more portion(s) thereof) may be performed in performance of one or more portions of one or more other methods disclosed herein. For that matter, in at least some embodiments, any method (or one or more portions thereof) disclosed herein may be performed in performance of one or more portions of one or more other methods disclosed herein.
Referring to
In at least some embodiments, the one or more signals may be indicative of a positioning and/or movement of one or more portions of a skier and/or one or more portions of the system.
At 5554, the method may further include determining, by the processor, whether to initiate release (e.g., of a boot plate and/or boot) based at least in part on the one or more signals.
At 5556, the method may further include, if the processor determines to initiate release, generating, by the processor, at one signal to initiate release.
In at least some embodiments, any of the binding systems disclosed herein may be used in conjunction with conventional mechanical ski brake systems, known in the art, by which a ski is preventing from sliding freely on the snow unless a boot pressed onto a spring-loaded plate or other mechanism mounted on the top of the ski surface. Such a mechanism can be disposed over or between binding plates in various embodiments. In some embodiments, a ski brake system could be linked to the processor (e.g., the microprocessor discussed above and/or the processor 5560, which may be a microprocessor or any other type of processor) and activated by means of an electronic signal when there is a release event, and then reset when a skier mounts his/her boots into the bindings.
In some embodiments, any of the systems disclosed herein may comprise storage means, such as a memory card, storage drive, or the like, in electrical communication with the processor (e.g., the microprocessor discussed above and/or the processor 5560, which may be a microprocessor or any other type of processor), by which settings and data from sensors are recorded and stored. In some embodiments, new sensor data will overwrite older, stored sensor data as the storage means becomes full, so that the most recent sensor data is retained. In some embodiments, the system may be in wireless communication, over the internet or otherwise, with storage means located external to the ski and binding system, including so-called “cloud” storage, by which sensor data are recorded. The stored sensor data can be used to analyze the performance of the system, and to improve the system over time by adjusting programming parameters based on such analysis. Such analysis may aid in understanding where a skier's leg is applying pressure to the boot, and in creating or improving models and maps of the boot, skis and/or binding to better understand their behavior during use. Such analysis may focus on the performance of the system when an incident occurs, such as a skier crashing due to an unintended release, or a skier being injured resulting from a failure to release. Such analysis and adjustment can be especially valuable when it takes into account a larger data set, such as may be obtained from many different skiers using the system disclosed herein or similar systems. By using data analysis, the system is an intelligent system that is capable of evolving over time as ski equipment changes and knowledge of industry conditions improves.
Referring to
The binding system 5604 may be mounted (directly and/or indirectly) to an upper and/or other surface of the ski 5602. The boot plate 5606 may be attached (directly and/or indirectly) to a sole and/or other portion of the boot 5608 (e.g., using screws (or other fasteners (threaded or otherwise)), claws and/or any other type of fasteners (not shown)). The boot plate 106 may also be releasably attached to the binding system 5604 (thereby releasably attaching the boot 5608 to the binding system 5604), sometimes referred to herein as a first (or releasably attached) state.
The system 5600 may have a longitudinal axis 5610 and/or may extend in longitudinal directions 5612 (
Referring also now to
Referring also now to
Referring also now to
The two clamps 5622, 5624 may each comprise an arm and a jaw coupled to the arm. In at least some embodiments, including but not limited to the illustrated embodiment, the clamp 5622 may comprise an arm 5642 and a jaw 5646 coupled to the arm 5642. The clamp 5624 may comprise an arm 5652 and a jaw 5656 coupled to the arm 5652.
The arms 5642, 5652 may be laterally spaced from one another, and may be pivotably or otherwise rotatably coupled to the binding plate 5620 by shafts 5648, 5658 (
In at least some embodiments, the arms 5642, 5652 are disposed on opposite sides of and/or spaced laterally from the longitudinal axis 5610 and/or the longitudinal axis 5626.
The arms 5642, 5652 may have a first position (e.g.,
In at least some embodiments, with the arms 5642, 5652 in their first position, the jaws 5646, 5656 contact the boot plate 5606 and force the boot plate 5606 against the binding plate 5620 or otherwise trap the boot plate 5606 relative to the binding plate 5620, to thereby releasably attach the boot plate 5606 (and a boot, e.g., boot 5608, to which the boot plate 5606 is attached) to the binding plate 5620, and in doing so, prevent or otherwise limit movement of the boot plate 5606 relative to the binding plate 5620. In at least some embodiments, movement may be prevented or otherwise limited in three dimensions (e.g., longitudinal, lateral and vertical).
In at least some embodiments, with arms 5642, 5652 in their second position, the jaws 5646, 5656 may be in their position that is most spaced apart from the boot plate 5606 such that the boot plate 5606 (and a boot, e.g., boot 5608, to which the boot plate 5606 is attached) is most easily removed from the binding plate 5620.
The binding system 5604 may further include a processor controlled latch and release system 5660. The latch and release system 5660 may include a processor based control system 5662, a solenoid 5668, a plunger 5670, linkage 5672 and a spring 5676 (or other bias element(s)).
As stated above, ideally, a binding system keeps the boot plate (and thus the boot attached thereto) securely attached to the ski during normal use, and releases the boot plate (and thus the boot attached thereto) from the ski during a fall or other mishap in order to prevent the ski from exerting undue torque, tension or force on the skier's leg and thereby causing injury.
The control system 5662 may be coupled to the solenoid 5668 and configured to receive one or more signals, from one or more sensors or otherwise, indicative of one or more conditions of the skier and/or system 100, and determine, based at least in part thereon, whether (and/or when) to power the solenoid 5668 to initiate release of the boot plate 5606 (and boot 5608 to which the boot plate 5606 is mounted).
The control system 5662 may have a centralized or distributed architecture. In at least some embodiments, one or more portions of the control system 5662 may be disposed on or otherwise coupled to the binding plate 5620. In some at least some embodiments, one or more portions of the control system 5662 may be disposed on or otherwise coupled to the skier and/or an article (e.g., clothing or otherwise) worn by the skier.
In at least some embodiments, the control system 5662 (or one or more portions thereof) may be the same as and/or similar to one or more portions of one or more embodiments of the control system 162.
The solenoid 5668 may have a first state (e.g., unpowered,
The plunger 5670, which may also be elongated and may extend in (or at least substantially in) the longitudinal directions 5612 and/or the longitudinal directions 5628, may include a first (or proximal) end 5728 and a second (or distal) end 5730. The first end 5728 may be slidingly received within the channel 5726 defined by the solenoid 5668. The second end 5730 may be biased away from the solenoid 5668 by a spring 5732 (or other bias element(s)), which may be disposed circumferentially about the plunger 5670. In at least some embodiments, including but not limited to the illustrated embodiment, the plunger 5670 may be centered about (or otherwise disposed on) and extend along the longitudinal axis 5610 and/or the longitudinal axis 5626.
The plunger 5670 may have a first position (e.g.,
The linkage 5664 may be coupled between the plunger 5670 and the arm 5642 of the first clamp 5622 and between the plunger 5670 and the arm 5652 of the second clamp 5624.
In at least some embodiments, including but not limited to the illustrated embodiment, the linkage 5664 may include a coupler 5800, first and second links 5802, 5804 and first and second cams 5812, 5814 (or other motion converters, e.g., bevel gears).
The coupler 5800 may have a forward end and/or other portion slidably or otherwise coupled to the plunger's second end 5730 (which may comprise a raised portion) or other portion of the plunger 5670. Thus, the coupler 5800 may have a first position (e.g.,
In at least some embodiments, including but not limited to the illustrated embodiment, the coupler 5800 may be coupled to a portion of the plunger 5670 that is displaced in (or at least substantially in) the longitudinal directions 5612 and/or the longitudinal directions 5628 if the plunger 5670 moves from its first position to its second position, such that the coupler 5800 will be displaced in (or at least substantially in) the longitudinal directions 5612 and/or the longitudinal directions 5628 if the plunger 5670 moves from its first position to its second position.
The coupler 5800 may define a slot 5820 or other channel, which may be elongated and may extend in (or at least substantially in) longitudinal directions 5612 and/or longitudinal directions 5628. The slot 5820 or other channel may receive the second end 5730 (which may comprise a raised portion) or other portion of the plunger 5670 to guide at least in part any sliding movement between the plunger 5670 and the coupler 5800. In at least some embodiments, including but not limited to the illustrated embodiment, the slot 5820 may be centered about (or otherwise disposed on) and extend along the longitudinal axis 5610 and/or the longitudinal axis 5626.
The coupler 5800 may have a rear end or other portion coupled to a first end 5826 of the spring 5676 (or other bias element), which may have a second end 5828 coupled to the rear side 5632 of the binding plate 5620 to bias the coupler 5800 rearward toward its first position. In at least some embodiments, including but not limited to the illustrated embodiment, the spring 5676 may be centered about (or otherwise disposed on) and extend along the longitudinal axis 5610 and/or the longitudinal axis 5626.
In at least some embodiments, including but not limited to the illustrated embodiment, the coupler 5800 may comprise a plate having a diamond or other shaped perimeter (which may be symmetrical about one or more axis).
The first and second links 5802, 5804 may be disposed on opposite sides of the coupler 5800 and may be coupled between the coupler 5800 and the first and second cams 5812, 5814, respectively (which in turn may be coupled to the arms 5642, 5652, respectively, of the first and second clamps 5622, 5624, respectively).
Thus, the first and second links 5802, 5804 may have a first position (e.g.,
The first link 5802 may have a first end 5830 (Fig, 67), a second end 5832 (
The first end 5830 or other portion of the first link 5802 may be pivotably coupled to a first side or other portion of the coupler 5800 by a shaft 5838 or otherwise. The second end 5832 or other portion of the first link 5802 may be pivotably coupled to a first end or other portion of the first cam 5812 by a shaft 5839 or otherwise. The first cam 5812 may have a second end pivotably or otherwise rotatably coupled to the arm 5642 of the first clamp 5622.
The second link 5804 may have a first end 5840 (Fig, 67), a second end 5842 (
The first end 5840 or other portion of the second link 5804 may be pivotably coupled to a second side or other portion of the coupler 5800 by a shaft 5848 or otherwise. The second end 5842 or other portion of the second link 5804 may be pivotably coupled to a first end or other portion of the second cam 5814 by a shaft 5849 or otherwise. The second cam 5814 may have a second end pivotably or otherwise rotatably coupled to the arm 5652 of the second clamp 5624.
In at least some embodiments, including but not limited to the illustrated embodiment, the first ends 5830, 5840 of the first and second links 5802, 5804, respectively, may be displaced in (or at least substantially in) the longitudinal directions 5612 and/or the longitudinal directions 5628 if the first and second links 5802, 5804 move from their first position to their second position. The second ends 5832, 5842 of the first and second links 5802, 5804, respectively, may be displaced in (or at least substantially in) lateral directions if the first and second links 5802, 5804 move from their first position to their second position.
In at least some embodiments, including but not limited to the illustrated embodiment, the first and second cams 5812, 5814 convert the displacement of the first and second ends 5832, 5842 (or other portions) of the first and second links 5802, 5804, respectively, into pivotal or otherwise rotational motion, which causes pivotal or otherwise rotational motion of the first and second clamps 5622, 5624, e.g., from their first position (e.g.,
In at least some embodiments, the binding system 5604 has a latch state (e.g.,
In at least some embodiments, the release state operates as follows. The solenoid 5668 is powered (e.g., energized,
In at least some embodiments, the binding system 5604 further includes a heel lock.
In at least some embodiments, the binding system 5604 may have a heel lock as described above with respect to
As stated above, the plurality of sensors 5562 may comprise any type(s) of sensors.
In at least some embodiments, one or more of the sensors 5562 may provide one or more of the following types of motion and position sensing for tracking body movements: mechanical, magnetic, optical, acoustic and/or inertial. Mechanical trackers often include linkages with linear and rotary potentiometers to determine relative angle and position between limbs. They are physically mounted to the body by which one sensor measures one degree of freedom the joint. Magnetic sensors utilize AC or DC magnetic fields to determine the position and orientation of a sensor relative to a source transmitter. Optical sensors include both camera and laser-based systems. Cameras utilize a pixel array for 30 Hz-120 Hz frame rates that are processed via a computer to determine position and orientation. Laser based systems, such as LIDAR, typically produce a point cloud designated by distances and angles. Processing of the point cloud reveals body position and orientation. RADAR is similar but relies more heavily on wave functions for higher resolution imaging. Acoustic sensors rely on time-of-flight measurements over an array of sensors to triangulate sensor position relative to the source transmitter. Inertial sensors include accelerometers and gyroscopes to map motions of the bodies that the sensors are mounted to. In at least some embodiments, a model may be used to relate the inertial measurements to the body orientation and position.
In some embodiments, it may be desirable to employ a combination of the above different types of sensors so as to provide a hybrid sensor system that may be capable of improving upon any given singular solution by drawing on their unique advantages.
Referring to
In at least some embodiments, the plurality of sensors, e.g., sensors 6904-6912, may be positioned to capture orientation of the knee and hip joints. To that effect, each sensor may be positioned on the leg such that the difference between relative measurements can be used to calculate knee and hip position and motion. The tibia sensors may be positioned in the center-front of the tibia. The femur sensors may be positioned on the center top of the femur. The hip sensor or sensors may be positioned above the crotch and below the belly button where a belt-buckle might fall, central to the skier's hip.
In at least some embodiments, one or more portions of the control system 162 may be integrated into or otherwise mounted on clothing or other article(s) worn by a skier.
Referring to
Sensors to be positioned on the legs of the skier, e.g., sensors 6906-6912 (
A wiring harness (or wiring in any other form) 7004 may distribute power to, and communication signals to and/or from, some or all of the sensors positioned on the legs of the skier. In at least some embodiments, the wiring harness may be routed on an interior seam of the leg to help reduce potential damage from falls and general abuse. In at least some embodiments, the wiring may have the form of a power and communication bus, which may connect the sensors. In some embodiments, the power and/or communication bus may run the length of the leggings 7002.
One or more other portions 7006 of the control system 162 may be integrated into or otherwise mounted on the belt 7000. In at least some embodiments, these other portions may include: (1) a motherboard, (2) a radio for communication to: a smart phone and/or a network (Bluetooth or otherwise) enabled device, (3) a battery, e.g., for powering the control system 162 or portions thereof, (4) battery charging circuitry, (5) a waist sensor and/or (6) one or more visible network status indicators, integrated into or otherwise mounted on the belt 7000. In at least some embodiments, the motherboard itself includes the: (2) radio for communication to: a smart phone and/or a network (Bluetooth or otherwise) enabled device, (3) battery, (4) battery charging circuitry, (5) waist sensor and/or (6) one or more visible network status indicators, and is integrated into or otherwise mounted on the motherboard.
Data from the sensors, e.g., sensors 6904-6912, may be sampled (continuously or otherwise) by the processor 5560.
In at least some embodiments, the processing may include a model of the skier. In at least some embodiments, this model is a physiological model is used to “observe” all sensors. In at least some embodiments, the sensor data is supplied to the model which may generate one or more signals in response at least thereto. Sensor data may be combined via a digital filter that incorporates the model to recursively update the current skier orientation, speed, and heading. Such data may be used to predict if a potential injury will occur. In at least some embodiments, the ski binding safely releases prior to the injury.
In at least some embodiments, the processor 5560 may be responsible for updating the skier model, determining the release decision (i.e., a decision as to whether to release the ski boot), recording performance data and/or communicating to an application on a user device and/or a separate computer.
In at least some embodiments, the model of the skier may comprise a set of equations relating model inputs and sensor readings. The set of equations may be integrated using a variant of traditional Kalman filtering to output limb and body position, velocity, and muscle activity.
In at least some embodiments, the model of the skier is used within a feedback structure as an “observer” whereby the model is used to inform predictions of future body position, but incorrect predictions update the model when necessary. In this way, the algorithm is able to predict danger of ACL damage and skier injury.
In at least some embodiments, the control system 162 may include a self-check process that has the purpose of measuring and diagnosing the health of each critical component. In at least some embodiments, the result of the system check is readable via a ski-binding light with pre-programmed sequences (red, yellow, green, blinking red, for example) and/or via a smart phone application which may contain more detailed diagnostics. Each system check result may be tracked via personal profile linked to the binding to alert the skier of component damage of health degradation.
In at least some embodiments, the system check isolates key system features including: (1) binding release mechanism via a current and position monitor, (2) sensor response and calibration via a user sequence of actions and/or (3) software and firmware version control.
In at least some embodiments, if the system-check determines that the system is not suitable for skiing, the system does not allow the ski binding to close and the user is unable to use the ski binding or it's features. A log may be stored for individual diagnostic troubleshooting.
In at least some embodiments, a wireless controller is installed on the binding or on the ski pole to manually trigger the entry and release of the binding. In at least some embodiments, a system check is performed with each entry of the ski. In at least some embodiments, the user need not access their phone for usage, all controls are ergonomic for glove wearing skier.
There have been numerous studies investigating the proper DIN number for ski bindings across gender and age boundaries that typically consider number of false releases compared to number of ankle and knee injuries caused by a lack of release. In at least some embodiments, an extensive profile of the profile should enable data better correlated for physical conditions most relevant to likelihood of an ACL injury.
In at least some embodiments, the skier model is an important dataset that is initially calibrated to the skier via an extensive physical evaluation. The model may include: (1) a questionnaire with traditional height, weight, skiing ability, gender, age, (2) a model using the sensors for limb length, form, and musculature, (3) a process to update the model based on skiing performance. For example, the forces and positions of the sensor array can be compared against the expectations from the model and updated accordingly and/or (4) a database keeping track of each model, skiing data, and an event log documenting releases and their conditions to better predict misses, false alarms, or hits. (Miss=did not release when it should have, False Alarm (FA)=a release when it should have not, Hit=a release when it should have).
In at least some embodiments, the ski model and data recording may be used by an individual or coach to gauge skier performance for safe and proper ski technique. In at least some embodiments, the system may include software (artificial intelligence software or otherwise) to label where poor or unsafe technique was measured. The software may record the data that would be necessary for visual replay. In at least some embodiments, akin to a race car driver re-driving a race track or course, the user will be able to replay their downhill run via a simulator or other similar device.
In at least some embodiments, the system may be used to augment skier performance in real time via auxiliary systems such as: (1) ski stiffeners, (2) muscle/limb enhancements, (3) Ski shape deformation and/or (4) trajectory/terrain mapping.
In at least some embodiments, the ski binding system may be a suitable platform for integrating safety features that may be especially useful for off-trail skiing. These may include (1) location tracking, (2) avalanche detection, (3) emergency alert system and/or (4) audible and visual signals.
It should be understood that the features disclosed herein may be used in any combination or configuration. Thus, in at least some embodiments, any one or more of the embodiments (or feature(s) thereof) disclosed herein may be used in association with any other embodiment(s) (or feature(s) thereof) disclosed herein. In at least some embodiments, any one or more of the features disclosed herein may be used without any one or more other feature disclosed herein.
Also, as described, some aspects may be embodied as one or more methods. The acts performed as part of the method may be ordered in any suitable way. Accordingly, embodiments may be constructed in which acts are performed in an order different than illustrated, which may include performing some acts simultaneously, even though shown as sequential acts in illustrative embodiments.
Unless stated otherwise, a processor may comprise a microprocessor and/or any other type of processor. For example, a processor may be programmable or non-programmable, general purpose or special purpose, dedicated or non-dedicated, distributed or non-distributed, shared or not shared, and/or any combination thereof. A processor may include, but is not limited to, hardware, software (e.g., low-level language code, high-level language code, microcode), firmware, and/or any combination thereof.
The terms “program” or “software” are used herein in a generic sense to refer to any type of computer code or set of computer-executable instructions that may be employed to program a computer or other processor to implement various aspects as described above. Additionally, it should be appreciated that according to one aspect, one or more computer programs that when executed perform methods of the present application need not reside on a single computer or processor, but may be distributed in a modular fashion among a number of different computers or processors to implement various aspects of the present application.
Computer-executable instructions may be in many forms, such as for example, but not limited to, program modules, executed by one or more computers or other device(s).
Unless stated otherwise, a program or software may include, but is not limited to, instructions in a high-level language, low-level language, machine language and/or other type of language or combination thereof.
Also, data structures may be stored in computer-readable media in any suitable form. For simplicity of illustration, data structures may be shown to have fields that are related through location in the data structure. Such relationships may likewise be achieved by assigning storage for the fields with locations in a computer-readable medium that convey relationship between the fields. However, any suitable mechanism may be used to establish a relationship between information in fields of a data structure, including through the use of pointers, tags or other mechanisms that establish relationship between data elements.
Unless stated otherwise, a processing device is any type of device that includes at least one processor.
Unless stated otherwise, a computing device is any type of device that includes at least one processor.
Unless stated otherwise, a control system is any type of control system that includes at least one processor.
Unless stated otherwise, a processing system is any type of system that includes at least one processor.
Further, it should be appreciated that a computer may be embodied in any of a number of forms, such as a rack-mounted computer, a desktop computer, a laptop computer, or a tablet computer, as non-limiting examples. Additionally, a computer may be embedded in a device not generally regarded as a computer but with suitable processing capabilities, including a Personal Digital Assistant (PDA), a smart phone or any other suitable portable or fixed electronic device.
Unless stated otherwise, a mobile (or portable) computing device includes, but is not limited to, any computing device that may be carried in one or two hands, worn on a body (or portion(s) thereof), affixed to a body (or portion(s) thereof) and/or implanted in a body (or portion(s) thereof).
Unless stated otherwise, a “communication link” may comprise any type(s) of communication link(s), for example, but not limited to, wired links (e.g., conductors, fiber optic cables) or wireless links (e.g., acoustic links, radio links, microwave links, satellite links, infrared links or other electromagnetic links) or any combination thereof, each of which may be public and/or private, dedicated and/or shared. In some embodiments, a communication link may employ a protocol or combination of protocols including, for example, but not limited to the Internet Protocol.
Unless stated otherwise, information may include data and/or any other type of information. Also, unless stated otherwise, data or other information may have any form(s) and may be received from any source(s) (internal and/or external).
Unless stated otherwise, a signal (control or otherwise) may have any form, for example, analog and/or digital, and is not limited to a single signal on a single line but rather, for example, may comprise multiple signals on a single line or multiple signals on multiple lines. Also, unless stated otherwise, a signal (control or otherwise) may have any source(s), internal and/or external.
Unless stated otherwise, terms such as, for example, “in response to” and “based on” mean “in response (directly and/or indirectly) at least to” and “based (directly and/or indirectly) at least on”, respectively, so as not to preclude intermediates and being responsive to and/or based on, more than one thing.
Unless stated otherwise, terms such as “coupled to” and “attached to” mean “coupled (directly and/or indirectly) to” and “attached (directly and/or indirectly) to,” respectively.
Unless stated otherwise, terms such as, for example, “comprises,” “has,” “includes,” and all forms thereof, are considered open-ended, so as not to preclude additional elements and/or features.
Unless stated otherwise, terms such as, for example, “a,” “one,” “first,” are considered open-ended, and do not mean “only a”, “only one” or “only a first”, respectively.
Unless stated otherwise, the term “first” does not, by itself, require that there also be a “second.”
Unless stated otherwise, the phrase “and/or,” as used herein in the specification and in the claims, should be understood to mean “either or both” of the elements so conjoined, i.e., elements that are conjunctively present in some cases and disjunctively present in other cases. Multiple elements listed with “and/or” should be construed in the same fashion, i.e., “one or more” of the elements so conjoined. Elements other than those specifically identified by the “and/or” clause may optionally be present, whether related or unrelated to those elements specifically identified. Thus, as a non-limiting example, a reference to “A and/or B”, when used in conjunction with open-ended language such as “comprising” may refer, in one embodiment, to A only (optionally including elements other than B); in another embodiment, to B only (optionally including elements other than A); in yet another embodiment, to both A and B (optionally including other elements); etc.
Having thus described several aspects and embodiments of the technology of this application, it is to be appreciated that various alterations, modifications, and improvements will readily occur to those of ordinary skill in the art. Such alterations, modifications, and improvements are intended to be within the spirit and scope of the technology described in the application. For example, those of ordinary skill in the art will readily envision a variety of other means and/or structures for performing the function and/or obtaining the results and/or one or more of the advantages described herein, and each of such variations and/or modifications is deemed to be within the scope of the embodiments described herein.
This application is a divisional of U.S. application Ser. No. 15/921,068, filed on Mar. 14, 2018, entitled “Processor-Controlled Snow Sport Boot Binding”, which claims benefit of and priority to U.S. Provisional Application No. 62/471,230, filed on Mar. 14, 2017, entitled “Electromagnetic Ski Binding System with Microprocessor Control” and U.S. Provisional Application No. 62/559,174, filed on Sep. 15, 2017 entitled “Electromagnetic Ski Binding System with Microprocessor Control”, each of which is incorporated by reference.
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Number | Date | Country | |
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20200047058 A1 | Feb 2020 | US |
Number | Date | Country | |
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62559174 | Sep 2017 | US | |
62471230 | Mar 2017 | US |
Number | Date | Country | |
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Parent | 15921068 | Mar 2018 | US |
Child | 16656938 | US |