The present invention relates to a base for a ski boot, preferably but not exclusively a Nordic ski boot, and to a ski boot incorporating such base.
Although the word “boot” is used throughout this specification and in the claims, it should be interpreted broadly to include shoes and any form of footwear suitable for wear when taking part in skiing.
Ski boots are a specialized form of footwear that is used in skiing to provide a way of attaching the skier's feet to his/her skis via ski bindings. The ski boot should position the skier's body over the ski properly. The base of such a boot usually comprises rigid cleats or outsole elements that are used to fasten the boot to a ski binding. These outsole elements also comprise a walking surface for the boot. It is therefore important for the base of the boot, which incorporates the outsole elements, to provide strength and torsional stiffness yet still be sufficiently flexible for the intended form of skiing and for ease of walking. It is also important for the base to incorporate the outsole elements in a manner which retains them securely in a correctly orientated manner in order that the base will withstand the considerable demands placed upon it during use. Some conventional bases for ski boots are made from injection moulded plastic material in which the outsole elements, in particular an element comprising a front bar that is used to attach a Nordic ski boot to a binding, are moulded into the sole. It has been known for these bars to be pulled out of softer plastic material or for harder plastic material to shear off the outsole element around the bar when high loads have been placed on the bar during use causing the bar to deform relative to the ski boot within the enclosing plastic material. Deformation of the bar, in any event, has a negative effects on ski control. Also, such bases rarely provide the necessary degree of torsional stiffness required to prevent permanent deformation of the boot from happening over time when the boot is in use
It is an aim of the present invention to overcome or substantially mitigate the aforementioned problems and to provide a base and a ski boot incorporating such a base that provides sufficient strength and torsional stiffness to obviate or substantially mitigate permanent deformation of the boot from occurring and that will with stand, in-use, high post clamping forces, preferably those of at least 68,950 N/m2 (10 psi), after connection to a ski binding.
According to a first aspect of the present invention there is provided a base for a ski boot comprising a one-piece sole defining heel and toe portions that is adapted to be secured to one or more outsole elements and that has a fiber-reinforced composite structure wherein a majority of the fibers in at least a mid-section of the sole between the heel and toe portions are angled at an acute angle with respect to a longitudinal axis of the sole.
Preferably, the mid-section of the sole covers a position anatomically beneath the location of the metatarsal bones and the plantar arch of a person wearing the ski boot.
Preferably also, toe and heel outsole elements are bonded to the toe and heel portions of the sole respectively to form a unitary construction.
Preferably also, a majority of the fibers in the mid-section of the sole are angled at an acute angle of substantially ±45°±10° to the longitudinal axis of the sole.
Preferably also, substantially the remainder of the fibers in the mid-section of the sole are either substantially aligned with the longitudinal axis of the sole at angles within ±20° of being parallel to the longitudinal axis or are angled at 90°±20° to the longitudinal axis of the sole.
Preferably also, between 5% and 10% of the fibers in the mid-section of the sole are substantially aligned with the longitudinal axis of the sole at angles within ±20° of being parallel to the longitudinal axis of the sole.
Preferably also, over 80% of fibers in the mid-section of the sole are angled at substantially 45°±10° to the longitudinal axis of the sole.
Preferably also, the fiber-reinforced composite structure comprises a laminate wherein a plurality of layers of woven fabric comprising warp carbon fibre yarns and weft carbon fibre yarns are encapsulated within a polymer matrix, which is preferably an epoxy-based resin.
Preferably also, the layers of woven fabric are each woven in a balanced plain weave.
Preferably also, the layers of the woven fabric are orientated relative to one another and to the longitudinal axis of the sole such that in some of the layers the warp or weft yarns are angled with respect to the longitudinal axis of the sole and in at least one of the layers the warp yarns or the weft yarns are aligned with the longitudinal axis of the sole.
Preferably also, the laminate comprises at least seven layers of woven fabric. Advantageously, at least six of the layers are orientated such that their warp and weft yarns are angled at ±45°±10° to the longitudinal axis of the sole and a seventh layer is orientated such that either its warp yarns or its weft yarns are substantially aligned with the longitudinal axis of the sole at angles within ±20° of being parallel to the longitudinal axis of the sole. Advantageously, the laminate comprises seven layers and said seventh layer is located centrally of the laminate between three outer layers on either side thereof.
In another embodiment, the laminate comprises eight layers of woven fabric of which seven layers are orientated such that their warp and weft yarns are angled at ±45°±10° to the longitudinal axis of the sole and the eighth layer is orientated such that its warp yarns or its weft yarns are substantially aligned with the longitudinal axis of the sole at angles within ±20° of being parallel to the longitudinal axis.
Preferably also, the outsole elements comprise rigid elastomeric elements that are bonded to the sole via an adhesive.
Preferably also, an outsole element comprising a rigid bar is fastened to the sole adjacent or at a forward end of said toe outsole element via at least two fasteners.
Preferably also, the outsole element comprising the rigid bar is fastened to the sole at the forward end of said toe outsole element, the fasteners penetrating through the toe outsole element into the sole.
Preferably also, the fasteners penetrate through the sole.
Preferably also, the base comprises a heel portion integrally formed with an upstanding portion that is adapted to wrap up around the back and sides of the heel of the ski boot.
Preferably also, the upstanding portion is adapted for connection to an ankle cuff.
Preferably also, the heel portion of the sole defines an interior cavity. Advantageously, a resilient pad is secured within the cavity to provide heel lift and to cushion the foot during use.
Preferably also, one of the outsole elements and the sole is provided with at least two projections that locate in holes or cavities defined by the other whereby said outsole element is secured to the sole in a predetermined position.
Preferably also, the projections are integrally formed with said outsole element. Alternatively, the projections are formed by injected pins, rivets, fasteners, t-nuts, or screws that locate into the cavities or holes defined by the sole.
According to a second aspect of the present invention there is provided a ski boot incorporating a base comprising a one-piece sole to which is secured one or more outsole elements, the one-piece sole having a fiber-reinforced composite structure wherein a majority of the fibers in at least a mid-section of the sole are angled at an acute angle with respect to a longitudinal axis of the sole.
Preferably, the mid-section of the sole is located between toe and heel portions of the sole to which portions are secured toe and heel outsole elements respectively.
Preferably also, the toe and heel outsole elements comprise rigid elastomeric elements that are bonded to the sole via an adhesive.
Preferably also, an outsole element comprising a rigid bar is fastened to the sole adjacent or at a forward end of said toe outsole element via at least two fasteners that penetrate through the sole.
Preferably also, the outsole element comprising the rigid bar is fastened directly to the sole adjacent said toe outsole element. Alternatively, the forward end of said toe outsole element is located between the outsole element comprising the rigid bar and the sole and the fasteners penetrate through the toe outsole element into and through the sole.
Preferably also, the ski boot has a flexible fabric upper.
Preferably also, the base comprises a heel portion integrally formed with the sole, which heel portion is wrapped up around the back and sides of the heel of the ski boot.
Preferably also, the heel portion is connected to an ankle cuff in a hinged manner.
The various aspects of the present invention will now be described by way of example with reference to the accompanying drawings, in which:
a and 4b are schematic representations, to an enlarged scale, of two layers of a laminate used to form the base shown in
The upper 3 is configured to encase a wearer's foot and is equipped with appropriate conventional fastening arrangements which will not be described here as the present invention is primarily concerned with the base 1 of the boot 2. The base 1 comprises a one-piece sole 4 defining heel and toe portions 5 and 6 respectively and a mid-section 7 that is located between the heel and toe portions 5 and 6 in a position anatomically beneath the location of the metatarsal bones and the plantar arch of a person wearing the ski boot 2. The heel and toe portions 5 and 6 are adapted to be secured to one or more rigid elastomeric outsole elements 8, 9, 10 to form a base 1 that can then be connected to the upper 3 during manufacture of the boot 2. Generally, therefore, the heel and toe portions 5 and 6 of the sole 4 lie adjacent respective heel and toe outsole elements 5 and 6. In the illustrated embodiment, the heel and toe outsole elements 8 and 9 respectively are permanently bonded to the heel and toe portions 5 and 6 of the sole 4 to form a base 1 of unitary construction that can then be secured to the upper 3. However, the outsole element 10 comprises a rigid bar 11 and is fastened, possibly in a releasable manner via releasable fasteners 12, to the sole 4 at a forward end of the toe outsole element 8. The fasteners 12 therefore penetrate through the toe outsole element 9 into the sole 4. Preferably, the fasteners 12 also penetrate through the sole 4 so that they can be unfastened and the outsole element 10 detached and replaced, if necessary. In an alternative arrangement (not shown) the outsole element 10 may be secured directly to the sole 4 adjacent a forward end of the toe outsole element 9, which in this case does not need to extend as far as the front tip of the sole 4.
The method of aligning and attaching the outsole elements 8, 9 and 10 to the sole 4 is described in more detail below. These outsole elements 8, 9, 10 locate between the sole 4 and a ski binding and least one of them, namely element 10 in the present example, is adapted for attachment to a Nordic ski binding. In other embodiments (not shown), one or more of the other outsole elements 8, 9 may also be adapted for securement to a ski binding in place of or in addition to the outsole element 10 to fit the base for attachment to different types of ski boot. In addition, the heel and toe outsole elements 8 and 9 provide walking surfaces that contact the ground when the boot 2 is not connected to a ski binding.
The construction of the base 1 will now be described in more detail.
The sole 4 has a fiber-reinforced composite structure wherein a majority of the fibers in the mid-section 7 of the sole 4 are angled at an acute angle with respect to a longitudinal axis L of the sole 4. In the present example this is achieved by manufacturing the sole 4 in the form of a laminate wherein a plurality of layers 13 of woven fabric comprising warp yarns 14 and weft yarns 15 are encapsulated within a polymer matrix. Preferably the warp yarns 14 and the weft yarns 15 are both carbon-fiber yarns and the polymer matrix is preferably an epoxy-based resin. The sole 4 is therefore moulded in a known manner, for example using a vacuum bag moulding process wherein a plurality of polymer-coated fabric layers 13 are laid up one on top of the other over a rigid mould to which suction is applied and the polymer is cured using heat and pressure applied via a flexible membrane or bag. The individual fibres of the fabric layers 13, which generally align along the longitudinal axis of the yarn in which they are incorporated, are therefore encapsulated by the polymer matrix so that the resulting moulded sole 4 has strength yet retains flexibility.
It is generally thought that it is important for the sole 4 to have isotropic qualities so that its stiffness properties are substantially the same in all directions. To achieve this the fabric layers 13 making up the laminate would be orientated so that half of them have either their warp yarns 14 or their weft yarns 15 aligned with the longitudinal axis L of the sole 4, as shown in
In preference, a more optimal relationship between flexure and torsion is required, namely a high torsional stiffness and a moderate to low flexural stiffness. Hence, in accordance with the present invention, the fabric layers 13 making up the laminate are arranged so that a majority, that is more than half, of the fibers forming the warp and the weft yarns 14, 15 in at least the mid-section 7 of the sole 4 and beneath the ball of the foot are angled at an acute angle with respect to the longitudinal axis L of the sole 4. Preferably, the remainder of the fibers forming the warp and weft yarns 14, 15 in the mid-section 7 of the sole 7 are either substantially aligned with the longitudinal axis L at angles within ±20° of being parallel to the axis L or are angled transversely at 90°±20° to the axis L. This is because it has been found that if there are no fibers aligned or substantially aligned with the longitudinal axis L, the sole 4 can become permanently deformed during prolonged use.
Advantageously, however, the quantity of fibers in the laminate that is substantially aligned with the longitudinal axis L is substantially reduced over the isotropic example above. Surprisingly, it has been found that a non-isotropic arrangement wherein less than 10% of the fibers, but preferably no less than 5%, are aligned with the longitudinal axis L and more than half are arranged at 45°±20° to the axis L provides substantially increased torsional stiffness, which is an advantage, without the longitudinal stiffness being reduced sufficiently to allow the resulting boot to become permanently deformed during repeated use. In this regard it should be understood that a degree of latitude must be allowed for in the angling of the fibers as absolute precision is difficult and whilst angling at 45° is preferred, angling at a small degree of variation from 45°, say ±10°, still provides acceptable results.
In a first preferred embodiment of base 1 in accordance with the present invention, the sole 4 is made of a laminate comprising 7 layers of balanced plain weave fabric arranged with their warp and weft yarns 14, 15 orientated as follows with respect to sole 4 as a whole, including the mid-section 7.
In this regard it should be understood that a degree of latitude must be allowed for in the angling of the fibers as absolute precision is difficult and whilst angling at 45° is preferred, angling at a small degree of variation from 45°, say ±10°, is still within the scope of the invention. Similarly, with regard to the fibers angled at 90° to the longitudinal axis L of the sole 4 some degree of latitude, say ±20° must be allowed for in the angling of the fibers.
Also, it is assumed that the woven layers 13 are all woven in balanced plain weaves, as shown in
It will be appreciated that in this example only around 7% of the fibers in the warp and weft yarns 14, 15 of the laminate as a whole are aligned with the longitudinal axis L and over 85% of the fibers in the warp and weft yarns 14, 15 are orientated at ±45° to the axis L. It has been found that such an arrangement increases the torsional stability of the sole 4 by approximately 50% over the isotropic example given above while decreasing the longitudinal stiffness by around a 33%. Such an arrangement maximizes the torsional stiffness of a boot 2 incorporating such a sole 4 while optimizing its longitudinal stiffness. This is a significant advantage in use as it increases the performance of the boot, enabling a skier to ski with confidence on the edge of the skis with the boot distorting.
In a second preferred embodiment of base 1, the sole 4 is made of a laminate comprising 8 layers of balanced plain weave fabric arranged with their warp and weft yarns 14, 15 orientated as follows with respect to sole 4 as a whole, including the mid-section 7.
In this example around 6% of the fibers in the warp and weft yarns 14, 15 of the laminate as a whole are aligned with the longitudinal axis L and over 87% of the fibers in the warp and weft yarns 14, 15 are orientated at ±45° to the axis L.
In addition to the laminate structure of the sole 4 described above, the sole 4 is preferably moulded with a heel portion 5 that comprises upstanding portions 16 which wrap up around the back and sides of the heel of the ski boot 3. The upstanding portions 16 at the sides of the sole 4 may be provided with moulded-in holes 17 to enable an ankle cuff or part of an ankle cuff 18, as shown in
In addition to the foregoing, the heel portion 5 of the sole 4 is moulded to define an interior cavity 20 into which is bonded a resilient pad 21. The pad 21 is dimensioned to provide a predetermined heel lift and made of a suitable material that will cushion the foot during use.
After moulding of the sole 4 as described above, the outsole elements 8 and 9 are bonded thereto to form the base 1 that can then connected to a boot upper 2, which is preferably a flexible fabric upper, in a conventional way. The outsole elements 8 and 9 are preferably made of a resilient material, such as rubber or a similar synthetic material, so as to cushion the foot during skiing. When this material is softer it gives a smoother, softer feeling in the ice conditions. It is also more comfortable during walking before and after skiing, especially on hard surfaces like cement and asphalt. If this material is harder it gives a more stable, direct, rigid contact platform that is an advantage in unstable softer snow conditions.
It is important for the outsole elements 8, 9 and 10 to be orientated correctly with regard to the longitudinal axis L of the sole 4 so that the boot can be properly attached to a ski binding and sit in the correct alignment with regard to the ski. This is often a difficult procedure and slight misalignment of the outsole elements 8 and 9 can seriously affect the ski binding attachment capability of the resulting boot and the ski alignment with respect to the boot.
In order to facilitate the correct alignment of the outsole elements 8, 9 and 10, the sole 4 is moulded with three pairs of cavities or holes 22, 23 and 24 in addition to the through-hole 17 for attachment of the cuff 18. The pairs of cavities or holes 22, 23 and 24 are precisely located in the sole 4 with respect to the longitudinal axis L. The first pair 22 is located respectively towards the front and rear ends of the toe portion 6 of the sole 4 whereas the second pair 23 is located respectively towards the front and rear ends of the heel portion 5 of the sole 4. Both of the pairs of cavities or holes 22, 23 align along the longitudinal axis L of the sole 4 and are used to locate the outsole elements 8 and 9 in the correct positions on the sole 4. To this end, each of the outsole elements 8 and 9 is provided with a pair of projections, 25 and 26 respectively that can be fitted into the respective pair of cavities or holes 22, 23 during attachment of the elements 8 and 9 to the sole 4. This ensures that the outsole elements 8 and 9 are positioned and orientated correctly with regard to the sole 4. The projections 25 and 26 may be unitary with the moulded material forming the rest of the elements 8 and 9 or may comprise injected pins, rivets, fasteners, t-nuts, screws or other secure alignment fastening means than can be located into the cavities or holes 22 and 23.
In the case of the pair of holes 24, these are located at the forward end of the sole 4 on either side of the longitudinal axis L and accommodate the fasteners 12 used to secure the outsole element 10 that comprises the rigid bar 11. These holes 24 are therefore preferably through holes so that the fasteners 12 can penetrate through the sole 4 rather than being cavities or blind holes, which is a possibility with the pairs of cavities or holes 22 and 23. In the present embodiment the outsole element 10 sits beneath the toe outsole element 9 and in order to align the two elements 10 and 9 together, a pair of projections 27 on one, in this case the element 10, that locate in cavities or holes (not shown) in the other may also be provided.
Hence, the outsole elements 8, 9 and 10 and the sole 4 can all be precisely aligned together relative to the centreline of the medial to lateral balance point of a ski. In particular, the outsole elements 8, 9 and 10 and the sole 4 can all be precisely aligned together in a forward and aft manner to form a base 1 that is individually adapted for a particularly sized upper to achieve a particular skier's optimal forward, aft balance point, side-to-side alignment and ideal power transfer zone and pivot point. Hence, a ski boot 2 can be manufactured to a skier's precise requirements.