This application claims priority from Italian Patent Application No. 102016000003496 filed on Jan. 15, 2016, the disclosure of which is incorporated by reference.
The present invention relates to a ski boot.
More in detail, the present invention relates to a ski boot for ski mountaineering, use to which the flowing description will make explicit reference without thereby losing in generality.
As is known, ski boots for ski mountaineering currently on the market basically comprise: a rigid shell made of plastic or composite material, which is shaped so as to accommodate the foot of the user, and has the lower part specifically structured so as to be fixed to the back of a downhill ski or similar by means of a special ski binding device; a rigid cuff made of plastic or composite material, which is shaped so as to embrace the lower part of the leg of the user from the behind, and is hinged to the upper part of the shell so as to be able to rotate about a transversal reference axis which is substantially perpendicular to the vertical midplane of the boot, and is also locally substantially coincident with the articulation axis of the ankle; an upper oblong tongue usually made of plastic material, which is arranged resting on the upper part of the shell, outside of the shell, so as to cover the longitudinal slit which extends straddling the midplane of the boot, in the area of the shell above the instep; and an inner liner in soft, thermal-insulating material, which is inserted inside the shell and the cuff, and is shaped so as to receive and protect both the foot and the lower part of the user's leg.
In addition the above-mentioned ski boots comprise a shell closing mechanism and a cuff closing mechanism, both manually operated.
In the more sophisticated models, the shell closing mechanism usually comprises: a manually-operated cable-winding winch which is rigidly fixed on the upper side of the tongue with the winch rotation axis locally substantially perpendicular to the surface of the tongue; a number of fairlead elements which are attached rigidly to the shell, on opposite sides of the longitudinal slit of the latter; and lastly a flexible cable made of metal material, which comes out of the cable-winding winch, slidingly engages in succession the various fairlead elements present on the shell passing alternately from one side of the shell longitudinal slit to the other above the tongue, and lastly returns back inside the cable-winding winch.
Despite working excellently, experimental tests have shown that, when used in conjunction with a shell composed of one or more overlapping layers of carbon fibres embedded in the resin, the above-described winch lacing system has a very limited capability to tighten the shell onto the foot of the user so that the shape of the composite-material shell must be almost tailor-made for the user, with all the drawbacks that this entails.
To better meet the market demands, the manufacturer of ski mountaineering boots must produce the composite-material shells in a larger number of sizes, with the increased costs that this entails.
Aims of the present invention is to realise a shell closing system which overcomes the drawbacks described above, possibly without increasing the overall production costs of the ski boot.
In compliance with the above aims, according to the present invention there is provided a ski boot as defined in Claim 1 and preferably, though not necessarily, in any of the dependent claims.
The present invention will now be described with reference to the accompanying drawings, which illustrate a non-limiting embodiment thereof, in which:
With reference to
Ski boot 1 firstly comprises: a rigid shell 2 which is shaped so as to accommodate the user's foot and has the lower part specifically structured/designed to couple/connect in a rigid and stable, though easily releasable manner, to a ski binding device (not shown) of known type which, in turn, is adapted to be rigidly fixed to the back of a downhill ski or similar; and a rigid cuff 3 which is shaped so as to enclose the lower part of the leg of the user, and is hinged to the upper part of shell 2 so as to be able to freely pivot about a transversal rotation axis A, which is locally substantially perpendicular to the vertical midplane of the ski boot and is also substantially coincident with the articulation axis of the user's ankle.
More in detail, the lower part of shell 2 is preferably provided with a front tip 5 and rear heel 6. The front tip 5 is preferably structured so as to be able to couple/connect in a stable, though easily releasable manner to the toe piece (not shown) of a ski binding device which, in turn, is firmly fixed to the back of a generic downhill ski or similar. The rear heel 6 instead is preferably structured so as to be able to couple/connect in a stable, though easily releasable manner to the heel piece (not shown) of a ski binding device which, in turn, is firmly fixed to the back of a generic downhill ski or similar.
In the example shown, in particular, the front tip 5 of shell 2 is preferably structured so as to be able to couple/connect in a stable, though easily releasable manner to the toe piece of a ski-mountaineering binding device; whereas the rear heel 6 of shell 2 is preferably structured so as to be able to couple/connect in a stable, though easily releasable manner, to the heel piece of the same ski-mountaineering binding device.
Preferably, the lower part of shell 2 additionally has a threaded profile so as to allow the user to walk on snow and ice.
In addition, the ski boot 1 moreover comprises an inner liner 4 with a soft and thermal-insulating structure, optionally of the thermoformable type, which is inserted into shell 2 and optionally also into cuff 3 preferably, though not necessarily in removable manner. The inner liner 4 is shaped so as to accommodate, cover and protect the user's foot substantially up to the ankle and optionally also the lower part of the user's leg roughly up to the top of the calf.
With reference to
In the example shown, in particular, casing 7 is preferably made of PEBAX (polyester-amide), Nylon (polyamide) or other similar plastic polymer.
In an alternative embodiment, however, casing 7 might also be made of a composite material preferably made up of one or more overlapping layers of carbon fibres and/or glass fibres and/or aramid fibres, suitably interwoven and/or superimposed to one another and embedded in a matrix of epoxy, phenolic or polyester resin, preferably of thermosetting type.
Preferably shell 2 furthermore comprises a first metal-material insert 9, which is firmly embedded/incorporated in the bottom wall of casing 7 at the front tip 5 of shell 2, and is structured so as to emerge outside of the casing 7 on opposite sides of the midplane of the boot, so as to be able to couple/connect in known manner to the toe piece (not shown) of the ski-mountaineering binding device; and optionally also a second metal-material insert (not visible in the figures) which is instead recessed into the casing 7 at the heel 6, and is structured so as to be able to couple/connect in a known manner to the heel piece (not shown) of the same ski-mountaineering binding device.
With reference to
Cuff 3, furthermore, is preferably fixed in free rotatable manner to the upper part of shell 2, or rather of casing 7, by means of two connecting hinges 12 preferably made of metal and which are placed on the inner and outer side walls of shell 2 and of cuff 3, aligned along axis A, so as to allow the cuff 3 to freely rotate on the shell 2 both forwards and backwards, while always remaining on a reference plane perpendicular to axis A and substantially coinciding with the midplane of the ski boot.
In the example shown, moreover, the rigid casing 7 preferably presents, on each side wall of shell 2, a long longitudinal stiffening rib 13 which has an arched or roughly L-formed shape, and extends along the side wall of shell 2 so as to connect the rear heel 6 to the front tip 5 preferably simultaneously intersecting the axis A, i.e. the seat accommodating the connecting hinge 12.
With reference to
The shell closing means 14 are structured so as to selectively close/tighten the shell 2, or rather the casing 7, against the user's foot to immobilize the user's foot inside the shell 2, or rather the inner liner 4.
The cuff closing means 16, instead, are structured so as to selectively close/tighten the upper part of the cuff 3 against the user's leg, so as to immobilize the user's leg inside the shell 3, or rather the inner liner 4.
More in detail, with reference to
The shell closing means 14 are placed at the longitudinal slit 18, and comprise:
The distal ends of flexible tabs 20 are structured so as to allow the flexible cable 23 to freely slide within the same tabs; while the winch-type cable-winding assembly 22 is structured so as to be able to selectively wind the flexible cable 23 inside itself, firmly block the flexible cable 23, and lastly unwind the flexible cable 23.
The winch-type cable-winding assembly 22 is thus able to tighten and keep taut the flexible cable 23, thus forcing the flexible tabs 20 and, as much as possible, also the casing 7 to flex towards the floating body 19, i.e. towards the centre of the longitudinal slit 18, so as to immobilize the user's foot inside the shell 2, or rather the inner liner 4.
With particular reference to
Preferably the rigid floating body 19 is additionally oblong in shape, and extends substantially straddling the centerline of longitudinal slit 18, resting on the upper part of the inner liner 4 for its entire length. Preferably the rigid floating body 19 is additionally substantially saddle-shaped so as to follow/copy the profile of the upper part of inner liner 4 covering the instep of the user's foot.
In addition, the rigid floating body 19 is preferably engaged in pass-through and free sliding manner by one or more sections of the flexible cable 23.
More specifically the upper face of rigid floating body 19 is preferably provided with one or more cable-pass bridges 24 (two bridges 24 in this example) each of which is preferably located substantially straddling the midplane of the boot, and is engaged in a pass-through and free sliding manner by the flexible cable 23.
In an alternative embodiment, however, the flexible cable 23 might also extend from side to side of the rigid floating body 19 grazing the upper face of the latter.
In other words, the rigid floating body 19 could be passed over at the top by one or more sections of the flexible cable 23.
With particular reference to
In addition, the distal end of each flexible tab 20 is preferably provided with a transversal through hole which is engaged in a pass-through and free sliding manner by a corresponding section of the flexible cable 23.
Preferably flexible tabs 20 are additionally made of plastic material, and are preferably rigidly fixed to the casing 7, inside the same casing 7.
More specifically, the proximal ends of the flexible tabs 20 are preferably rigidly attached to the inner surface of the casing 7.
In the example shown, in particular, the proximal ends of the flexible tabs 20 are preferably rigidly attached to the lateral walls of casing 7 by rivets 25 or other mechanical attachment members.
In an alternative embodiment, however, the proximal ends of the flexible tabs 20 may also be snapped or heat-welded directly onto the lateral walls of the casing 7.
The winch-type cable-winding assembly 22 and flexible cable 23 are components already widely known and used in the footwear industry, and do not require further explanations since they are extensively described and illustrated, for example, in the patent applications US19970917056, WO1998US16314, JP20000507254, US20010956601, US20010099566, US19990337763, JP20010519784, WO2000US19440, US19990388756, US20010993296, US20030459843, US20050263253, US20070841872, US20070842009, US20070841997, US20070842013, US20070842005, WO2005US39273 and US20040623341P. Documents to which direct reference is to be made for any further details on the structure and/or cable-winding assembly 22.
In the example shown, in particular, winch-type cable-winding assembly 22 and flexible cable 23 are preferably made by the US company BOA TECHNOLOGY INC.
With reference to
More specifically, the lower part of the gaiter 28 is preferably irremovably and/or fluid-tight attached to the upper part of casing 7, preferably by welding or gluing.
Preferably the lower part of gaiter 28 is additionally suitable to at least partly cover the shell closing means 14.
In other words, with particular reference to
More specifically, the winch-type cable-winding assembly 22 is preferably rigidly fixed onto the floating body 19 below the gaiter 28, and in addition projects cantilevered above the gaiter 28 engaging in pass-through manner a small, complementary-shaped auxiliary opening 29 specifically formed on the area of the gaiter 28 which lies immediately above the floating body 19.
With reference to
With reference to
In the example shown, in particular, the cuff closing means 16 preferably comprise:
With reference to
Operation of ski boot 1 is easily inferred from the description above, and does not need further explanations.
As regards instead operation of the shell closing means 14, the tightening of flexible cable 23 forces the flexible tabs 20 to flex towards the floating body 19, i.e. towards the centre of the longitudinal slit 18, firmly pressing the foot of the user against the bottom of shell 2, or rather against the bottom of casing 7.
The advantages resulting from the particular structure of the shell closing means 14 are remarkable.
Firstly, the shell closing means 14 lend themselves to be used in conjunction with a casing 7 made of highly rigid composite material, because the capability to immobilize the foot of the user inside the shell 2, or rather the inner liner 4, is not affected, except to a minor extent, by the stiffness of casing 7.
The flexible tabs 20 in fact allow to directly embrace the upper part of user's foot and therefore permit to more effectively immobilize the user's foot inside the shell 2, or rather the inner liner 4.
In addition, the presence of flexible tabs 20 makes it possible to push/press the user's foot down against the bottom of the shell 2, or rather against the bottom of the basin-shaped casing 7, significantly improving the comfort of fit and the ability to transmit, during use, the forces to the skier.
Lastly, the particular structure of the shell closing means 14 makes it possible to eliminate the tongue that is traditionally placed to cover the longitudinal slit 18 of casing 7, allowing a small reduction in the overall weight of the ski boot.
Finally, changes and variations may be clearly made to the ski boot 1 described above without, however, departing from the scope of the present invention.
For example, the flexible tabs 20 can be over-injected directly onto the body of casing 7 during the injection moulding process of the casing 7.
Number | Date | Country | Kind |
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102016000003496 | Jan 2016 | IT | national |