DEVICE AND METHOD FOR MEASURING HEEL TO FOREFOOT HEIGHT DIFFERENTIAL OF A SHOE
A device in the form of a parallelogram for use with an inclinometer for measuring angle of a height differential between two points of a surface such as the angle of heel to forefoot height differential of a shoe.
This is a divisional of U.S. patent application Ser. No. 12/229,720, filed Aug. 26, 2008, which is a continuation-in-part of U.S. patent application Ser. No. 11/412,807, filed Apr. 27, 2006, which claims priority of U.S. provisional patent application Ser. No. 60/680,232, filed May 12, 2005, and such priority is hereby claimed. The disclosures of all of the above applications, as well as all patents/published applications disclosed herein, are hereby incorporated herein by reference. Applicant is the patentee of U.S. Pat. Nos. 7,387,309 and 8,191,918.
The present invention relates generally to ski boots and other shoes or footwear (for example, work shoes, sneakers, roller blades, and ice skates) as well as the attachment of ski boots to skis. More particularly, the present invention relates to the sizing of the footwear to achieve improved balance and/or mobility and/or flexion as well as the attachment of ski boots to skis to achieve improved balance.
Typical ski equipment set-ups leave many people in very poor fore/aft positions, i.e., leaving many people inclined too far backward. This makes it difficult to balance with the result that it is harder to learn to ski, with more tiring and an increased risk of injury. To achieve better balance, the skier's feet should often be inclined relative to the skis so that the heel portion of a ski boot is raised relative to the height of the toe portion thereof. The correct fore and aft position will vary depending on the skier's body type. It is thus considered desirable for a skier to be able to adjust his or her fore and aft position (i.e., adjust the height of the heel end portion of the ski boot) to achieve the correct balance for him or her. Such an adjustment may be characterized as an adjustment of the angle of the leg relative to the ski or ground.
Various devices of interest relative to adjusting the heel portion height are disclosed in my aforesaid patent as well as in the art cited therein.
Additional art which may be of interest (generally relative to foot contour, as discussed hereinafter) to the present invention includes U.S. Pat. Nos. 4,821,420; 5,941,835; 5,979,067; 6,205,230; 6,219,929; 6,334,257; 2004/0193075; 6,829,377; 2006/0030793; 7,125,509; 2006/0225297; and 7,335,167. The hoof angles of horses have been modified by trimming the hoofs.
As discussed at pages 10 to 14 of the booklet Masterfit University the Bootfitters Bible—The Master's Course, Master Fit Enterprises, Briarcliff Manor, N.Y., 1994-2003, the foot has a very intricate network of 26 bones which slip and slide relative to each other. When performing properly, these bones allow very intricate movements easily of the foot. However, if not suitably positioned relative to each other, these bones may also collide with each other or jam together, resulting in trauma such as callus formation and may result in loss of optimum mobility and/or flexion and/or balance. This booklet recommends orthotics and custom footpads for callus formations and, in severe cases, a metatarsal pad and/or a depression. Other suggested solutions include adjusting for pronation with custom footbeds or varus wedges and to use thicker insole and/or eliminator to compensate for a low volume foot. Motions in a group of bones known as the subtalar-transverse tarsal joint complex are said to allow the foot to absorb impacts, accommodate for uneven surfaces, and act as a rigid lever, and it is in this complex where locking and unlocking of the foot may commonly occur. It is thus important that the foot bones be properly positioned relative to each other to achieve optimum movements while skiing or otherwise. While adjustment of the relationship of the leg relative to the ski or ground for improved balance is important, as discussed above, it is also considered important that optimum positioning of the foot bones relative to each other be achieved. Optimum positioning of the foot bones relative to each other is generally related to the contour of the footboard or footbed or bootboard, i.e., the upper surface of the sole or built-up sole within a piece of footwear upon which the foot or an insole rests, an insole being a removable piece (on which the foot rests) which is placed to lie over the sole generally for comfort.
In W. Witherell et al, The Athletic Skier, The Athletic Skier, Inc., Salt Lake City, Utah, 1993, at pages 24 to 44, it is discussed that the desired heel lift (the difference between the heel and forefoot levels) significantly affects fore and aft balance, that some feet are best balanced and aligned when the heel and forefoot are on the same plane while others are best balanced and aligned when the heel is higher than the forefoot. Also discussed therein is a way of measuring a person's heel to forefoot differential by having the person stand on various thicknesses of stacks of paper and then the person sensing their balance, i.e., when the right balance is achieved, “your body will know (the human body senses balance very precisely).” A heel lift under the heel is shown on page 26 thereof. On page 33 thereof, a photo of feet with the left foot supinated and the right foot pronated is shown and another photo is shown with the feet well aligned with proper orthotics. An adjustable cuff is discussed on pages 42 to 44 wherein, after the footbeds or orthotics are put into the boots, the cuff is adjusted so that the space between the leg and shell is equal on both sides.
The Athletic Skier fails to disclose or suggest suitable methods or measuring devices to accurately determine the needs of a person's foot and determine accurately what suitable angles/contours should be on the surface (footboard or footpad) in the footwear that the foot rests upon. For example, one thing this reference fails to take into consideration is that, as the heel to forefoot differential changes, so too does the contour of the foot's arch.
Heel lifts of varying thicknesses and tapers are marketed by Aetrex Worldwide, Inc. of Teaneck, N.J. (www.aetrex.com) and Ski-Kare of Golden, Colo. Aetrex Worldwide, Inc. claims to have patented what it calls the “iStep Evolution-RX” digital foot scanning technology, which it says on its website is in order to help consumers identify their arch type, shoe size, and pressure points and to custom select/order the ideal footwear and orthotics, including insoles, for their feet. The footwear is custom made from the digital information.
A lift to accommodate leg length discrepancy up to ⅜ inch (it has 3 layers with instructions to peel away one layer for ¼ inch or two layers for ⅛ inch), finished with a leather cover, is marketed, under the name Adjust-a-Lift, and under the trade name Treadeasy by Prime Materials Corporation of Batavia, N.Y. See their Treadeasy Catalog 08-09 at page 19 (or see their web page at www.treadeasy.com—under Product Catalog, Materials, Metatarsal Supports, Adjust-a-Lift).
The heel lifts are typically placed between the heel and the insole. The thicker part of a wedge-shaped or tapered heel lift is typically placed toward the rear. Typically, a person is instructed to put a heel lift in, go skiing, and leave the heel lift in if the skiing is improved.
The cuff is typically attached to the shell of a ski boot with cammed fasteners or knobs or studs, such as in the Vento ski boot marketed by the Italian company Technica, having a web site of www.technica.it, which are advertised (Technica, Vento Instruction Manual) to allow longitudinal flex of the boot to be adjusted and to allow the cuff to be adjusted from a neutral position to an inwards or outwards tilt. The boot is further advertised (in the above instruction manual) as having an upper liner construction to ensure perfect adaptation to the female calf and to have a patented ratchet system that may be adjusted to 3 different positions to adapt to any type of leg. The boot is further advertised (in the above instruction manual) as providing a specific insert to be applied onto a wedge inside the shell so that the fit in the heel area may be customized more to the female anatomy. Such flex and tilt adjustments may have the incidental consequence merely as a result of their functioning of effecting a small movement of the cuff 710 vertically relative to the shell 702 of typically less than about ¼ inch.
If a foot orthotic insole is made flat and then placed in footwear with a raised footboard in the heel area, the insole may no longer follow the foot's contour correctly and may accordingly still result in jammed foot bones, thus not suitably correcting the balance and/or mobility and/or flexion.
An insole may typically be custom made to fit the impression of the foot from a custom insole blank, which is a flat flexible or cushion sheet of uniform thickness which may have an underlying more rigid thin sheet for the heel and arch to hold the form in these areas (or the more rigid sheet may extend all the way to the toe area). In order to custom form the sheet, the foot is first placed into a beaded bladder (or other form) to form an impression of the foot lower surface. Then the sheet is suitable heated such as by placing in hot water or in an oven at a recommended temperature (for example, about 180 degrees F.) so that it may be conformable, and the conformable blank is then put into the impression and allowed to cool, thus taking on the shape of the foot lower surface. Undesirably, such a custom made insole for a orthotically lifted heel still may not conform properly with the thusly altered sole and may accordingly still result in jammed foot bones, thus not suitably correcting the balance and/or mobility and/or flexion.
It is accordingly an object of the present invention to accurately determine the foot's optimum position and to provide an insert or inserts or otherwise adjust the footboard so that it receives the foot in that optimum position.
It is another object of the present invention to prepare or adjust the footboard so that it follow's the foot's contour correctly.
It is a further object of the present invention to conform an insole to the altered footboard to properly correct balance and/or mobility and/or flexion.
It is yet another object of the present invention to optimize mobility and flexion and balance in skiers as well as other persons.
It is still another object to more easily determine heel to forefoot height differential and heel angle in footwear.
It is another object of the present invention to mass market a higher quality of shoes.
The above and other objects, features, and advantages of the present invention will be apparent in the following detailed description of the preferred embodiments thereof when read in conjunction with the appended drawings in which the same reference numerals depict the same or similar parts throughout the several views.
Height adjustment on a ski of the heel end portion of a ski boot relative to the toe end portion thereof is discussed hereinafter with reference to
Referring to
The mechanism 20 includes an elongate plate 28 to which the bindings 24 and 26 are suitably and conventionally attached in accordance with principles commonly known to those of ordinary skill in the art to which the present invention pertains, the plate 28 having a toe end portion 30 to which the toe binding 24 is attached and a heel end portion 32 to which the heel binding 26 is attached. The plate 28 has a width and length equal generally to the width and length of the bindings for the boot 25 to be bound thereto (which is generally equal to the width and length of the boot).
For purposes of providing a means for attachment of the elongate plate end portions 30 and 32 to the ski 22, as hereinafter discussed, corresponding plates 34 and 36 respectively are fixedly attached to the ski 22 such as by screws 38 or other suitable means. The width of each of the plates 34 and 36 is generally equal to the width of the elongate plate 28, and the length of each of the plates 34 may, for example, be generally equal to the width thereof, or otherwise as suitable. Each plate 34 and 36 may, for example, have 4 of the screws 38, one at each corner, or other suitable number of screws.
The toe end portion 30 is pivotly connected to the plate 34 by a conventional pivot or hinged connection, illustrated at 40, including a hinge pin 41, to allow the elongate plate 28 to be adjusted through the angle illustrated at 42 so that the height of the skier's heel relative to the skier's toes may be adjusted to achieve the optimum balance for the particular skier. The hinged connection 40 may, for example, be similar to the hinged connection illustrated in the aforesaid U.S. Pat. No. 4,353,575 and discussed at column 3, lines 1 to 5, thereof, which patent is hereby incorporated herein by reference. For another example, the hinged connection may be similar to a conventional door hinge, such as shown at 86 in
In order to provide an easy to use, stable, uncomplicated, reliable means for adjustment of the height of the heel end portion 32 relative to the toe end portion 30 through the angle 42, in accordance with the present invention, a height adjustment assembly, illustrated generally at 43, is provided wherein the heel end portion 32 is attached to the ski plate 36 by upper and lower members 44 and 46 respectively having complementary teeth or serrations, illustrated at 48, on facing sides for interlockingly engaging each other. The lower serrated member 46 is pivotly attached to ski plate 36 by a conventional pivot or hinged connection, illustrated at 50, which may be similar to hinged connection or otherwise as suitable. The upper serrated member 44 is attached to the elongate plate heel end portion 32 as hereinafter discussed. The members 44 and 46 are fixedly attached at an adjusted position by at least one but preferably a pair of bolts 52 and corresponding nuts 54 or other suitable fasteners, the shanks of the bolts 52 received in apertures (not shown) in member 44 and in vertically elongated adjustment slots, illustrated at 56, in the other member 46. It should be evident that the adjustment slots 56 may be provided in either of the members 44 and 46 and that the bolts 52 and nuts 54 may be interchanged. It should also be understood that either the bolt heads or the nuts may desirably be conventionally fixed to the respective member so as to be free from turning thereby making height adjustment easier for the skier. The width, illustrated at 58, of each of the members 44 and 46 is generally equal to the width of the elongate member 28 to thereby provide stability. Thus, it can be seen that the members may be attached by the bolts 52 and nuts 54 at any of various heights to which the heel portion 32 is to be desirably adjusted, with the serrations 48 on the upper member 44 bearingly and interlockingly engaging the complementary serrations 48 on the lower member 46 to stably provide the needed support. The serrations 48 are desirably sized, in accordance with principles commonly known to those of ordinary skill in the art to which the present invention pertains, to provide height adjustments of, for example, as little as ⅛ degree.
It is important that the ski 22 be able to flex as much as possible to make turning easier, and modern skies are typically constructed to maximize their flexing ability. During flexing of the ski, the distance between the plates 34 and 36 varies. In order to compensate for this variance in distance so that the ski 22 may be enabled to sufficiently flex as well as to evenly flex, the upper serrated member 44 is slidably attached to the heel portion 32 by an overhanging upper portion 60 of upper member 44 which is slidably received in a track, illustrated at 62, on the lower surface of heel portion 32. The track 62 comprises a pair of underhang portions 64 which are spaced apart a distance which is less than the width of the member overhanging portion 60 so that the portion 60 is retained slidably within the track 62. The track 62 may be open-ended at one or both ends to allow the member portion 60 to be inserted into the track 62 and is desirably long enough so that the member portion 60 does not come out of the track 62 during skiing.
In order to adjust the angle 42 so as to adjust the height of the skier's heel relative to the toes for improved balance as well as to achieve increased leverage, even while on the ski slopes, the skier may easily and quickly loosen the nuts 54, incrementally raise or lower the upper member 44 relative to the lower member 46, tighten the nuts 54 on the bolts 52 to firmly secure the members 44 and 46 in the newly adjusted position, and then go about enjoying skiing even more at the improved balance and leverage and with the upper member portion 60 sliding within the track 62 so that flexing of the ski for better turning is not unduly hampered.
It should be understood that the boot and ski plates 28, 34, and 36 are not essential to the present invention and that the toe binding 24 may be directly or otherwise pivotly connected to the ski 22 and the serrated members 44 and 46 directly or otherwise connected to the heel binding 26 and ski 22 respectively. The device of the present invention need not be a separate device but may instead be built into the ski and/or binding. Thus, a reference to the toe or heel end portion or to a ski in the claims is meant to also refer to plates attached or attachable thereto.
Referring to
Referring to
The upper end portions 88 of the members 82 are attached to the heel end portion 32 of plate 28, as hereinafter discussed. Intermediate the height of the members 82, elongate members 91 and 92 such as bars or tubular members are mounted to extend between the respective flanges 83 of the members 82 respectively and are suitably attached to the respective flanges 83 such as by screws (not shown) so that they can pivot (i.e., are rotatable about the longitudinal axis). The head end portion 107 of an adjustment bolt or screw 90 is received in an unthreaded aperture in member 92 and a nut 94, similar to nut 134 in
The placement of an adjustment screw so that it is rigidly attached to the ski at the ski end of the “scissors” members, as in the aforesaid U.S. Pat. No. 4,007,946, detracts from the ability of the ski to flex as needed. Thus, in accordance with the present invention, the hinge 86 is instead placed at the ski plate 36. In order to provide increased stability, the “scissors” members 82 have a width which is generally equal to the width of each of plates 28 and 36.
The present invention is not limited to the particular components for the height adjustment assembly, which components are disclosed for exemplary purposes only. Thus, the present invention may be otherwise embodied for providing the desired height adjustment while allowing the ski to suitably flex. For example, the member 82 on the right side in
Referring to
Referring to
Referring to
Referring to
In accordance with a preferred embodiment of the present invention, in order to be able to adjust the angle 42 to a very small angle approaching zero degrees, the member 202 is pivotly attached to the rear end of the plate 28. Thus, the rear end of the plate 28 has a cut out, illustrated at 228, therein providing a pair of laterally spaced rearwardly extending protrusions 230. The member 202 is received in the cut out 228, and a pivot rod 232 is received in apertures, illustrated at 234, in the protrusions 230 and in an aperture, illustrated at 236, in the member 202. It should of course be understood that variations may be made in the assembly 200 as well as the other assemblies discussed herein. For example, instead of a single pin 232 or a single pin 206, a pair of short pins may be provided, each received on one side or the other of the respective member 202 and 204.
Referring to
Referring to
Race plates have been provided to raise the boots and bindings above the skis for greater leverage. In order to accommodate almost any size boot, these race plates are often made long, for example, 24 inches. Thus, if plate 300 were 24 inches long, it would accommodate the boots of all or almost all skiers. However, since the plate 300 must be of sufficient thickness to suitably accommodate forces acting thereon, such a length undesirably increases the weight thus undesirably increasing the burden of carrying the skis, especially for smaller people who have boot sizes which do not require such long plates. In order to reduce the carrying burden on smaller (as well as larger) persons while also accommodating larger boot sizes of larger persons, in accordance with the present invention, the bindings plate 300 is made to a relatively smaller length of, for example, 18 inches, and a decreased thickness extension 330 is attached to the top surface of flat plate portion 314 at the forward end portion 332 thereof to increase the length thereof by, for example, about 2 inches, to 20 inches overall. If desired, the extension may be provided to increase the length thereof by, for example, about 4 inches or longer, to 22 or more inches overall. The extension 330 is attached to the plate 300 by screws 334, for example, 4 no. 10-32 flat head screws, received in counterbored (to accommodate the flat heads) apertures, illustrated at 336, in the rearward end portion of the extension 330 and threadedly received in threaded apertures, illustrated at 338, in the forward end portion 332 of the flat plate portion 314. The forward end portion 331 of the lighter (less thickness) extension thus extends forwardly beyond the plate 300 to increase the overall plate length by as much as 2 or more inches.
Snow may tend to build up and cake between the plate 300 and the ski 22. This is a type of problem which used to be encountered under boots with the solution in recent years being that the soles of boots have been conventionally contoured to allow the escape of the snow. In order to allow snow to escape from between the plate 300 and the ski 22 as well as to reduce the carrying burden even more for both small and large people, a lightening cutout, illustrated at 340, is provided centrally of the length of the plate 300 (between the attachments of the bindings). While the cutout 340 is shown to be rectangular in shape, it should be understood that it may otherwise be suitably shaped or provided in other ways such as a series of apertures.
The following dimensions of the plate 300 and extension 330 as well as other dimensions and examples contained herein (unless the context clearly indicates otherwise) are for exemplary purposes only and not for purposes of limitation. The overall length and width of plate portion 314 may, for example, be about 18 inches and about 2¼ inches respectively. The flange portion height, illustrated at 342, may, for example, be about ½ inch. The thickness of each of the plate and flange portions 314 and 316 respectively may, for example, be about ¼ inch. The extension 330 may have a length, width, and thickness of about 4 inches, about 2¼ inches, and about 3/16 inch respectively and is attached to the plate 300 so as to extend, for example, about 2 inches forwardly thereof. The cutout 340 begins, for example, about 4½ inches from the forward edge of the plate 300, extends lengthwise of the plate 300 a distance of, for example, about 4 inches, and extends widthwise, for example, over the entire distance between the flange portions 316. The plates 300, 306, and 330 are made of aluminum or other suitable material.
It should be understood that, while tracks such as at 62 in
It should be understood that, as used herein and in the claims, the term “serrations” is intended to include various teeth or saw-like notches or other suitable segments on one member which are formed to interlock with teeth or saw-like notches or other suitable segments on another member. For example, the serrations may have a staircase-like shape.
Referring to
A suitable member 406, which may be composed of molded plastic or metal or other suitable material, is fixedly attached or locked in place, such as by one or more screws, bolts, pins, or other suitable fasteners or locking devices, illustrated at 409, to the toe end portion 408 of the track 402, but alternatively the member 406 may be formed integral with the track 402. The lower portion of the member 406 is suitably shaped so that it can be slid onto and along the track 402. The member 406 has a pair of laterally spaced upper ears 410 (one shown) between which the toe end portion 30 of the plate 28 (for receiving the bindings) is received and pivotly attached by a pin 412 suitably received in apertures in the end portion 30 (adjacent the end of the plate 28) and ears 410.
A block 414, which may be composed of molded plastic or metal or other suitable material, has a pair of laterally spaced upper forward ears 416 (one shown). The heel end portion 32 of the plate 28 is received between the ears 416 and pivotly attached to the block 414 by suitable means such as a pin 418 suitably received in apertures in the end portion 32 (adjacent the end of the plate 28) and ears 416.
A block 420, which may be composed of molded plastic, metal, or other suitable material, is formed to have a lower portion 421 suitably shaped to slide onto the rear end of and engage rail 402 for sliding of the block 420 longitudinally of the ski 22 along the rail 402, as illustrated at 422. Thus, the lower surface of the block 420 has a longitudinal recess, illustrated at 424 in
Two vertically oriented members with interlocking serrations connecting a heel binding with a ski, such as shown in FIGS. 10 and 11 of the aforesaid U.S. Pat. No. 4,135,736, may be considered to not provide as much stability as may be desired. In order to distribute the pressure better on the serrated surfaces so as to provide improved stability, the block 420 is suitably formed so that the serrated surface 426 thereof is inclined. Thus, for example, as illustrated, it has a vertical rear wall 434, an inclined wall 436 extending from the upper edge of the rear wall 434 downwardly and forwardly to the forward edge of the bottom wall 438 in which the recess 424 is contained, and a pair of generally triangular side walls 440, leaving a generally hollow space, illustrated at 442, which will be discussed in greater detail hereinafter. As a result of the inclined surface 426, it can be seen in
In order to lock the inclined block 420 at a desired heel binding height, the inclined wall 436 has a pair of longitudinally extending spaced parallel grooves, illustrated at 448, therein extending therethrough substantially over the length thereof. The block 414 has a pair of similarly spaced apertures, illustrated at 450, extending therethrough. Bolts 452 or other suitable fasteners are received in grooves 448 and apertures 450 respectively, as illustrated at 458, and nuts 456 applied and tightened to fix or lock the serrations 428 and 430 together to lock the inclined block 420 in the position for the desired heel binding height, illustrated at 458. The hollow space 442 is provided to allow the bolts 452 to be placed in position. Preferably, the bolts 452 (or studs) are threadedly received tightly in threaded spaced (equal to the spacing between grooves 448) apertures, illustrated at 460, in a suitable plate 462 and their heads 464 (or stud ends) may be welded to the plate 462. In order to adjust the position of the inclined block 420 for height adjustment, the nuts 456 are suitably loosened and the inclined block 420 moved along the track 402 to the desired new position, then the nuts 456 tightened at the new position. It is unnecessary that the nuts 456 be removed from the bolts 452 during such adjustment. However, a stop member 466 may be applied to the end of each bolt 452 to prevent the respective nut 456 from becoming inadvertently removed. The stop member 466 may, for example, be a nut or washer or a pin welded or otherwise suitably fixed thereto. It should of course be understood that the locking of the serrated surfaces in a desired position may be achieved by other suitable means such as, for example, by the use of a single slot 448 and/or by the use of another suitable fastening mechanism such as, for example, a cam locking device used with the slot or slots 448. For another example, the plate 462 may be dispensed with and the pair of bolts 452 may have heads large enough so as not to pass through the slots 448. For another example, the inclined block 420 may be formed not to have the hollow space but instead have a slot underneath the inclined wall 436 which allows movement of the plate 462 along the length of the inclined wall 436 (which might require the inclined block 420 to be composed of two pieces which are then welded or otherwise suitably attached together and the plate 462 and bolts 452 placed in position before such attachment). For another example, the inclined block 420 may be formed to have two or more narrow slots underneath the inclined wall 436 which allow movement of the heads of bolts (without a plate) along the length of the inclined wall 436.
As previously discussed, the pre-assembled rail and ski may come in different configurations. For example, referring to
It should be understood that an inclined block may be moved along a track for height adjustment and held in an adjusted position by other means than interlocking serrations. Referring to
The inclined block 602, which may be composed of molded plastic, metal, or other suitable material, has a longitudinal (along the length of the ski 22) recess, illustrated at 604, in its upper surface, the recess 604 having an inner laterally increased width portion, illustrated at 606, which defines laterally spaced tracks 608 having inclined upper surfaces 610 on the laterally opposite sides. The inclined surfaces 610 extend downwardly from the rear or heel end toward the front or toe end. The bottom surface 612 of the recess 604 has a plurality of longitudinally spaced indents or notches or recesses, illustrated at 614, suitably formed therein generally laterally centrally thereof.
A block 616 has a generally cylindrical laterally extending portion 618 which is received in a cutout, illustrated at 620, between a pair of lateral end portions 622 of the plate 28 (the end portions 622 defined by the cutout 620). A pin 624 is suitably received in each of the apertures, illustrated at 626 (one shown), in the end portions 622 and in an aperture, illustrated at 628, extending axially through the entire width of the generally cylindrical portion 618, thereby pivotally connecting the block 616 to the ski binding plate 28.
The block 616, which may be composed of molded plastic, metal, or other suitable material, is formed to have a pair of upper portions 630 which are laterally projecting so as to be positioned to ride on the inclined surfaces 610 respectively and a pair of lower portions 631 (one shown) which are also laterally projecting so as to be positioned to fit within the increased width portion 606 and underneath the tracks 608 respectively so that the block 616 is lockingly but slidingly received on the tracks 608. The block 616 is further formed to have front and rear laterally centrally disposed walls 632 and 634 respectively (
The screw 636 may be otherwise suitably embodied. For example, referring to
It should be understood that it is within the scope of the present invention that other suitable means may be provided for advancing block 616 or other suitable block along the inclined surface of block 602 or other suitable block. For example, the indents 614 may instead be raised bumps or projections, with the screw thread engaging between the bumps for advancing the block 616 along the inclined surface of block 602.
It should be understood that it is within the scope of the present invention that either of the blocks 414 or 616 be attached directly to heel binding rather than the plate 28. Thus, a recitation herein or in the claims that a member engages or is attached to a boot or a heel or toe portion thereof or to a ski is intended to mean that it is engaged or attached directly thereto or to a plate or track or other member which is attached thereto. Likewise, a recitation that a member engages such a plate or track or other member is intended to include that it is engaged or attached to the boot or a heel or toe portion thereof or to the ski.
Referring to
Good balance as well as mobility and flexion while skiing not only depends on the adjustment of the boot heel portion height, as discussed above, but also on the contour of the footboard to match the optimum positioning of the bottom of the foot itself as it fits within the boot 25. Moreover, good balance as well as mobility and flexion in any footwear also depends on the contour of the footboard to match the optimum positioning of the bottom of the foot itself as it fits within the footwear, including the heel to forefoot height differential, illustrated at 716. As used herein and in the claims, the heel to forefoot height differential is the difference in height of the footboard or bootboard, illustrated at 718, between where the forefoot rests, illustrated at 720, and where the heel rests, illustrated at 722, the footboard or bootboard 718 being the upper surface of the sole (or built-up sole as described hereinafter with respect to
Conventional ski boots which are not adjusted for this differential 716 and other footboard contour may leave the numerous bones in the foot in a jammed or misaligned condition, which makes balancing and athletic movement difficult for many skiers, especially women. In order to provide better balance and athletic movement for a skier, the desired or optimum differential 716 as well as other footboard contour, after it is determined as discussed hereinafter based on what is optimum for the individual as perceived by the individual, is shown to be achieved by positioning one or more inserts 724 of plastic or other suitable material and of the same or varying thicknesses between the liner 710 and the sole 704, thereby providing a “built-up sole.” These inserts 724 are shown to be held in place by, for example, one or more protruding portions 726 on one insert 724 which are interlockingly received in indents 728 in an adjacent insert 724, it being understood that they may be held in place by other suitable means such as screws. For example, the lower insert 724 may have a thickness (at the heel end) of about ½ inch, and the upper inserts 724 may have a thickness (at the heel end) of about ⅛ inch, and all the inserts 724 suitably taper towards the toe portion to provide the arch, illustrated at 730, to suitably provide for the resting of the arch of the foot thereon. Thus, the heel to forefoot height differential 716 in the boot 25 may, for example, be about ⅞ inch.
The liner 710 may be a single piece with a cushionary bottom or it may have a cushionary member (insole) in the bottom which receives the foot. If the inserts 724 are suitably sized and shaped to provide the optimum foot position, as discussed hereinafter, then it is unnecessary to alter the conformable liner, which, being flexible, should suitably conform thereto.
The determination of the contour of the footboard 718 will be discussed hereinafter with respect to various footwear, it being understood that the discussion thereof will apply to the boot 25.
As seen at 732, the insertion of the inserts 724 results in a narrowed passage for the foot. In order to accommodate for such a narrowing, the upper front of the shell 702 has a cut-out, illustrated at 734, which provides an opening over the foot instep to allow the liner 710 and the foot received therein to protrude through the cut-out. To secure the forefoot, the liner 710 is provided with laces, illustrated at 736, or with other suitable means such as, for example, Velcro material or straps.
Unlike in a typical ski boot, the cut-out 734 does not allow the liner 710 to be secured by the shell 702 extending over the forward portion thereof. In order to suitably secure the liner 710 so that, for example, the foot does not come out of the boot 25 if the skier leans back, the toe portion of the liner 710 is suitably affixed to the toe portion of the sole 704 such as, for example, by one or more screws 738 each received in an aperture, illustrated at 740, and threadedly received in a small rigid plate 742 suitably built into the liner 710 or by other suitable fasteners or interlocking arrangements such as, for example, bolts or pins.
The cuff is typically attached to the shell of a ski boot with cammed fasteners or knobs or studs, such as in the above discussed Vento ski boot, which are advertised to allow longitudinal flex of the boot to be adjusted and to allow the cuff to be adjusted from a neutral position to an inwards or outwards tilt. Except as discussed herein, the boot 25 may as applicable be similar to the Vento ski boot. Such flex and tilt adjustments may have the incidental consequence merely as a result of their functioning of effecting a small movement of the cuff 710 vertically relative to the shell 702 of typically less than about ¼ inch.
As the heel height is increased within the boot 25, the lower leg 700 may extend higher above the cuff 710 than is comfortable or suitable, and, especially for a woman, her calf muscle, illustrated at 744, may undesirably get moved forward. In order to provide for suitable placement of the cuff 710 as the heel height is increased within the boot 25, in accordance with the present invention, the cuff 710 is height adjustable relative to the shell 702. Such height adjustment may be provided, for example, by one or more circumferentially spaced vertical slots, illustrated at 744, in the shell 702 (for example, 3 such slots, one on either side of the boot and one in the back thereof). Referring to
In order to provide adequate vertical adjustment to suitably accommodate the various heel height changes that may be made, in accordance with the present invention, the height adjustability of the cuff 710 relative to the shell 702 is at least about 1 inch (for example, about 2 inches) and accordingly the length, illustrated at 756, of the slot 744 is preferably at least about 1 inch (for example, about 2 inches). Preferably, the height adjustability of the cuff 710 relative to the shell 702 is at least equal to the maximum heel height change that may occur.
Referring to
The heel end assembly 808 includes a lower flat member 812 hingedly connected as by hinge, illustrated at 814, at its upper inner corner to the lower inner corner of an upper flat member 816 providing an upper surface 818. An elongate member (square of rectangular in cross-section) 820 extends cross-wise of the assembly 808 and is suitably attached, as by gluing, to the lower surface of member 812 adjacent the inner end thereof, thus resulting in the member 812, with its outward end resting on the support member 810, being inclined upwardly as it extends inwardly to the hinge 814. A wedge member 822, which may be similarly shaped as member 820, is removably receivable between the flat members 812 and 816 for reasons which will be discussed hereinafter.
The toe end assembly 806 includes a flat member 824 providing an upper surface 826. A plurality of flat members 828, which may be of varying thickness but need not be so, are removably receivable between the flat member 824 and the support member 810 for reasons which will be discussed hereinafter.
An assembly, illustrated generally at 830, interconnects the the upper inner ends of the flat members 816 and 824. The assembly 830, whose parts may be composed of a suitable metal, includes a hinge 832 one leaf 834 of which is suitably connected to flat member 816 as by spaced screws 836 and the other leaf 838 of which is connected to plate 840 as by rivets 842. The assembly 830 similarly includes a hinge 844 one leaf 846 of which is suitably connected to flat member 824 as by spaced screws 848 and the other leaf 850 of which is connected to plate 852 as by rivets 854. Plate 840 has a pair of laterally spaced elongate slots, illustrated at 856, which extend in a direction toward and away from the flat members 816 and 824. Plate 852 similarly has a pair of laterally spaced elongate slots, illustrated at 858, which also extend in a direction toward and away from the flat members 816 and 824. The plates 840 and 852 vertically overlap each other so that their respective slots 856 and 858 are alignable, and a screw 860 is receivable in each respective pair of aligned slots 856 and 858 and secured by a wing nut 862 to connect the plates 840 and 852.
In order to use the apparatus 804, a mark, illustrated at 864, is placed on the foot 802 at the forward end of the heel 866. The length, illustrated at 868, of the foot arch is measured, the foot arch being from mark 864 forward to the fifth metatarsal joint (near the rear of the ball of the foot). The distance, illustrated at 870, between the flat members 816 and 824 is adjusted so that it is equal to the distance 868. The foot 802 is then placed on the surfaces 818 and 826 with the mark 864 (or forward end of the heel 866) aligned with the hinge 832 so that the foot arch extends between the flat members 816 and 824, with the heel of the foot 802 resting on the flat member 816 and the ball of the foot 802 resting on the flat member 824, as illustrated in
The difference in height, illustrated at 872, between the surfaces 818 and 826 when the foot 802 is in the optimum position (determined as discussed hereinafter) is the desired heel to forefoot height differential 716 for the footwear 800 as well as for boot 25. To test the foot 802 in different positions, one may start with the surface 818 level by moving the wedge 822 back and forth, as illustrated at 874, until surface 818 becomes level. One may also start by adjusting the height of flat member 824, by suitable addition of shims 828, until surface 826 is at the same height as surface 818. However, one may start at different positions. Then, as shims 828 are added or subtracted, balance and mobility and flexion are tested at each of different heights 872 by having the person roll the feet/ankles, forward flex, and the like, until he reports a height at which he feels that he has the best balance and mobility and flexion. In most cases, it is expected that this optimal height 872 is with the forefoot lower, as illustrated in
Not only is it considered important to provide the optimum heel to forefoot height differential in the footwear 800, but it is also considered important for optimal balance and mobility and flexion that the heel angle, illustrated at 878, be optimal. In accordance with the present invention, in order to determine the optimal heel angle (the angle of the heel portion of the footboard), the wedge 822 is moved back and forth, as illustrated at 874, thereby changing the heel angle 878, the balance and mobility and flexion are tested at each of different heel angles 878 by having the person roll, forward flex, and the like, until he reports a heel angle 878 at which he feels that he has the best balance and mobility and flexion. This optimum heel angle 878 is also measured with the angle measuring device 876, as discussed hereinafter. The apparatus 804 is retained in the optimal position for heel to forefoot height differential and heel angle for use at that optimal position as discussed hereinafter. It should be understood that apparatus 804 may be embodied differently to provide a determination of optimal heel to forefoot height differential and heel angle, and such other embodiments of the apparatus 804 are meant to come within the scope of the present invention.
Referring to
The vertical bar 880 extends downwardly beyond the lower bar 886 a short distance, illustrated at 891 (
The structure 896 is adjustably movable along the length of bar portion 900 to adjust to the distance (between points 892 and 898) over which the angle of surface slope or incline (defined for the purposes of this specification and the claims as the angle of the differential between the heights of the surface at points 892 and 898) is to be measured.
As seen in
Referring to
In order to determine the optimum heel to forefoot height differential for the foot 802 as determined by use of the apparatus 804 of
The angle determined to be optimum for the heel to forefoot height differential with reference to
Referring to
It should of course be understood that the measurements for the apparatus 804 and corresponding measurements in the shoe 800 can be accurately compared as long as each measurement is obtained while the apparatus 804 and the shoe 800 are on the same or similarly inclined surfaces.
In order to unobstructively and conveniently make measurements inside typical shoes/boots, as illustrated in FIGS. 33 and 34, the vertical bars 880 and 882 are desirably long enough to extend above the top of the shoes/boots, and the upper bar is desirably short enough to fit within the shoe opening, illustrated at 926. In addition, the length of the lower bar 886 is desirably short enough that it can fit easily into the shoe/boot 800 while allowing sufficient adjustment of the distance between points 892 and 898. Accordingly, the length, illustrated at 928, of bar 882 is preferably at least about 9 inches, more preferably at least about 12 inches, with the bar 880 extending an added distance equal to the length 891 (in the range of about ¼ inch to ½ inch) of portion 890. The length, illustrated at 930, of bar 884 is preferably less than about 3 inches, for example, about 2½ inches. The length, illustrated at 932, of the lower bar 886 is preferably about 6 inches or less. While these dimensions are considered preferred for a typical shoe/boot, they may of course vary depending on shoe type/size.
Referring to
To determine the amount of added thickness 936 needed in the shoe 800 (if such added thickness is needed) to achieve the determined optimum heel to forefoot height differential 872, the attachment 934 is slid upwardly until the points 934 and 892 are even with each other. While using inclinometer 916, the bar 886 is moved to the angle corresponding to the determined optimum heel to forefoot height differential 872 (the point 892 being above the heel), and the attachment 934 is slid downwardly until point 944 contacts the heel surface of the shoe 800. The distance 936 is then a measure of the added heel lift thickness needed in the shoe 800 to achieve the determined optimum heel to forefoot height differential 872.
Once the optimum heel to forefoot height differential 872 and heel angle 878 are determined, heel lifts of various thicknesses and tapers, as needed, as illustrated at 724 in
After the heel is built up to the determined optimum heel to forefoot height differential 872 and heel angle 878, an insole, illustrated at 948 in
In order to provide a footboard 718 suitably to prevent or reduce such misalignment or jamming of foot bones, in accordance with the present invention, the bottom surface of the custom insole 948 is conformed to the upper surface of the built-up sole 946 as described hereinafter.
Referring to
Alternatively, the bottom surface 956 may be shaped by use of the apparatus illustrated generally at 960. The casting block 950 is received on a platform 962 one end portion of which is received within a frame 964 which has a bottom wall 966 and a pair of side walls 968 which extend above the platform 962. On each wall 968 are provided a pair of longitudinally spaced vertical slots, illustrated at 970, which allow the frame 964 to be height-adjustably attached to the platform 962 by wing screws 971 (or other suitable fasteners) received in the slots 970 and in corresponding threaded apertures (not shown) in the platform 962. This allows height adjustment of the frame 964 relative to the upper surface of the platform 962 (for example, from flush with the platform upper surface to about 1 inch above the platform upper surface) thereby vertically positioning a blade 972 received in tracks or grooves 974 in the inner surfaces of the side walls 968 for pushing longitudinally, as illustrated at 976, to make the cut in the foam block 950 which is illustrated at 978, to correspond to the determined optimum heel to forefoot height differential 872. The longitudinal spacing of the slots 970 allows the corresponding longitudinal spaced portions of the frame 964 to be adjusted to different heights to thereby tilt or incline the tracks 974 so that the cut 978 can be made at an angle corresponding to the determined heel angle 878.
In order to form the cut illustrated at 980 in the foam block 950, a fixture 982 is mounted on one side of the platform 962. A portion 984 of the fixture 982 is mounted to the platform 962 by a wing screw 986 (or other suitable fastener) received in an aperture, illustrated at 988, in the portion 984 and threadedly received in a nut (not shown) which is held in a longitudinally extending T-slot, illustrated at 990, which allows the fixture 982 to be adjustably positioned along the length of T-slot 990 as needed for the determined length 870 of the arch. The fixture 982 has a portion 992 normal to portion 984 which supports a pair of lips 994 between which a blade or cutter 996 is receivable thereby providing a track for holding and guiding the blade 996 for its movement cross-wise of the platform 962, as illustrated at 998, for making the cut 980 of the desired length 870. It should be noted that the fixture 982 is rotatable about wing screw 986 so that the track 994 is adjustably inclined to conform to the desired angle of the cut 980. During the making of the cut 980, an edge portion 1000 (opposite from the edge portion received in the track 994) of the blade 996 may rest on the end portion of the blade 972 when blade 972 is pushed all the way in. It should of course be understood that the present invention is not limited to the apparatus and process for making the cuts 958 and 980 as disclosed herein, and other embodiments thereof are meant to come within the scope of the present invention as defined by the appended claims.
Referring to
Referring to
It should of course be understood that other suitable means such as, for example, a beaded bladder, may be used to form the foot bottom impression, and such other means are meant to come within the scope of the present invention as defined in the appended claims.
A suitable insole blank 948 (which may typically be a generally flat sheet having a generally uniform thickness and which may have a softer or more flexible or cushion-like upper portion 1004 over its length and a more rigid lower portion 1006 over generally the heel and arch areas to hold the form thereof, although the lower portion 1006 may extend all the way to the toes) is suitably heated (placed in hot water or otherwise as suitable) to a suitable temperature as may be recommended by the manufacturer (for example, about 180 degrees F.). The heated blank 948 is then placed on the foot bottom impression surface 952 of the cast block 1002 and allowed to conform thereto and cool, thereby to desirably conform the thusly tailored insole 948 to the upper surface of the built-up sole as well as to the foot. The tailored insole 948 is then placed in the shoe 800 over the built-up sole 946 to thereby achieve an insole surface which conforms to the surface of the built-up sole so that the built-up sole and conforming insole are both contoured to optimize balance and/or mobility and/or flexion.
As previously discussed, the heel height of a ski boot is adjusted along with providing a optimum bootboard contour in the boot in order to optimize balance and/or mobility and/or flexion while skiing.
In accordance with the present invention, a line of shoes or other footwear is marketed wherein each shoe size (currently sized in length and width) is also sized in various increments of heel to forefoot height differentials 872 and may be further sized in various increments of heel angle 878 and/or arch length 870. The customers would be sized utilizing the principles disclosed herein. In order to reduce shopkeeper inventory, the manufacturer may sell to the shopkeeper as the orders are received and may wait to make a particular sized shoe until the order is received.
It should be understood that, while the present invention has been described in detail herein, the invention can be embodied otherwise without departing from the principles thereof, and such other embodiments are meant to come within the scope of the present invention as defined by the appended claims.
Claims
1. A device for use with an inclinometer for measuring angle of heel to forefoot height differential of a shoe, the device comprising four bars pivotally connected to define a parallelogram wherein each pair of opposite ones of said bars are parallel, and the device further comprising means for positioning the device inside a shoe so that a lower of said bars is inclined at the angle of heel to forefoot height differential of a shoe and so that an upper of said bars is disposed above an opening of the shoe, whereby, with the shoe on a level surface, the measured inclination of said upper bar is equal to the angle of heel to forefoot height differential of the shoe.
2. A device for use with an inclinometer for measuring angle of a height differential between two points of a surface, the device comprising first, second, third, and fourth bars, said first and second bars pivotally attached to said third bar at first and second pivot points respectively, said first and second bars pivotally attached to said fourth bar at third and fourth pivot points respectively, wherein distance between said first and second pivot points is equal to distance between said third and fourth pivot points, wherein distance between said first and third pivot points is equal to distance between said second and fourth pivot points, wherein said second bar extends beyond said fourth bar to a terminal end to define at said terminal end a first contact point, wherein said fourth bar has a portion which extends beyond said first bar, and the device further comprising a member which is adjustably positionable along the length of said portion and which extends from said portion the same distance that said second bar extends beyond said fourth bar to define a second contact point, whereby with the first and second contact points contacting two points respectively of a surface, a measurement of the angle of height differential of said third bar is equal to the angle of height differential between the two points of the surface.
3. A device according to claim 2 wherein the lengths of said first and second bars are such that the device is insertable into a shoe for measurement of angle of heel to forefoot height differential of a shoe with the third bar disposed out of the shoe.
4. A device according to claim 3 wherein the lengths of said first and second bars are such that the device has a height of at least about 9 inches.
5. A device according to claim 3 wherein the lengths of said first and second bars are such that the device has a height of at least about 12 inches so that the device is insertable into a boot for measurement of angle of heel to forefoot height differential of the boot.
6. A device according to claim 2 wherein the length of the third bar is less than about 3 inches, and the length of the fourth bar is less than about 6 inches.
7. A device according to claim 2 further comprising an attachment which is formed to slidably engage said second bar to provide a contact point to engage and determine height differential of a surface point between actual position thereof and a position thereof when at a selected angle of height differential.
8. A device according to claim 2 wherein said first and second bars do not extend beyond said third bar whereby the device is invertible to contact said third bar along a surface to measure the angle of incline thereof by measuring the angle of incline of said fourth bar.
9. A device according to claim 2 wherein the device is sized to measure angle of heel to forefoot differential of a shoe.
10. A method for measuring angle of a height differential between two points of a surface, the method comprising:
- providing a device which comprises first, second, third, and fourth bars, the first and second bars pivotally attached to the third bar at first and second pivot points respectively, the first and second bars pivotally attached to the fourth bar at third and fourth pivot points respectively, wherein distance between the first and second pivot points is equal to distance between the third and fourth pivot points, wherein distance between the first and third pivot points is equal to distance between the second and fourth pivot points, wherein the second bar extends beyond the fourth bar to a terminal end thereof to thereby define a first contact point, wherein the fourth bar has a portion which extends beyond the first bar and includes a member whose position along the length of the portion is adjustable and which extends from said portion the same distance that said second bar extends beyond said fourth bar to define a second contact point;
- adjusting the position of the member along the fourth bar portion so that the distance between the first and second contact points is equal to the distance between the two points of the surface;
- contacting the first and second contact points to the two points respectively of the surface; and
- measuring the angle of height differential of the third bar while the two points of the surface are contacted by the first and second contact points respectively;
- whereby the angle of height differential between the two points of the surface is equal to the measured angle of height differential of the third bar.
11. A method according to claim 10 wherein the two points are the heel and forefoot of a shoe, the method including inserting the device into the shoe so that the two points contact the heel and forefoot of the shoe and so that the third bar is above the shoe, whereby the angle of heel to forefoot height differential of the shoe is equal to the measured angle of height differential of the third bar.
Type: Application
Filed: May 27, 2015
Publication Date: Sep 17, 2015
Inventor: Michael M. Pupko (Colden, NY)
Application Number: 14/722,527