This application is based upon French Patent Application No. FR 14/01087, filed May 14, 2014, the disclosure of which is hereby incorporated by reference thereto in its entirety, and the priority of which is claimed under 35 U.S.C. § 119.
1. Field of Invention
The invention relates to a sports boot, such as a ski, hiking, or mountaineering boot.
2. Description of Background
A sports boot typically includes a lower portion, referred to as the shell base, and an upper portion, referred to as the collar. The shell base includes a sole, from which two sides extend. The shell base and collar support the foot and calf, respectively, of the user. The collar is hinged in relation to the shell base to facilitate walking, but it may be immobilized with respect thereto during the sporting activity in order to block movements of the user's ankle.
The shell base may be rigid or flexible. A flexible shell base can be tightened around the foot of the user using a lace. Lace devices are simple to set up and they are lightweight. However, when they include closed keepers, such devices hinder the insertion of the user's foot because, even when not tightened, they partially obstruct the opening of the boot. Moreover, it is difficult to tighten a rigid shell base simply with a lace. This is why boots having a rigid shell base are equipped with complementary tightening mechanisms, such as hooks, loops, or notched strap tightening devices that increase the tightening force. In this case, several devices are used to replace a single lace.
While hiking, climbing, or skiing, the user may have to perform sidesteps, pass through branches or climb by taking support on an inner or outer side of his boot. However, the mechanisms for tightening the shell base of known boots are arranged on a side of the shell base. Thus, the tightening mechanisms are susceptible to degradation or deactivation by external elements such as stones or branches during the sporting activity.
The foregoing are drawbacks that the invention remedies by providing a sports boot in which the mechanisms for tightening the shell base are less exposed to external elements such as stones and branches. The risk of the tightening mechanisms being degraded or deactivated during the sporting activity is lower. The invention further provides a device combining the advantages of tightening using a single lace and the advantages of a stronger tightening using a plurality hooks.
The invention also provides a boot whose tightening mechanisms are simple to use, lighter than known devices, and which, when not tightened, do not hinder the insertion of the foot.
To this end the invention relates to a sports boot comprising a rigid shell base for holding the foot of a user, the shell base comprising a sole and two lateral sides extending from the sole, and tightening mechanisms for tightening the shell base around the foot of the user, such tightening mechanisms comprising a filiform element for tightening the sides toward one another which is tightened by pivoting a lever. According to the invention, the lever is designed to be pivoted in a notch of a rack designed to cover the two sides of the shell base in the tightened configuration and to bend the sides towards the sole under the pivoting action of the lever.
The rack is arranged on top of the shell base in the tightened configuration. The rack and the tightening lever are therefore less exposed to stones and branches during the sporting activity. Moreover, the lace provides the boot with a mountain style appreciated by specialists. The shell base is tightened simply by tilting the tightening lever as this involves tightening the lace, on the one hand, and bending the two sides of the shell base around the foot of the user, on the other hand.
According to advantageous but non-essential aspects of the invention, a sports boot thereof may incorporate any of the following features, taken in any technically feasible combination:
The filiform element is a lace, whereas the lever is strung on the lace.
The lever comprises two arms each demarcating a through opening for passage of the lace.
The rack includes a rigid tongue and a notched element fixed to the tongue and including a plurality of notches for receiving the lever.
The rigid tongue is articulated on one of the sides of the shell base.
The rack is configured to bend the sides of the shell base uniformly around the foot of the user.
The tightening lever comprises a pivot shaft within a notch of the rack.
The distance between the pivot shaft of the lever and the lace passage openings is substantially equal to the spacing between two notches of the rack.
The two notches of the rack are separated from one another by an empty notch.
The lever is detached from the shell base.
Other features and advantages of the invention will become more apparent from the following description of an embodiment of a sports boot provided by way of example and with reference to the annexed drawings, in which:
The boot 1 comprises a lower portion 2 for receiving and surrounding the foot of the user. The lower portion 2, referred to as the “shell base”, holds the foot of the user during walking or skiing. The lower portion 2 is rigid, that is to say, it is made of a material having a modulus of elasticity greater than 500 MPa. In practice, the shell base 2 can be made of plastic. The shell base 2 extends between a front and a rear along a longitudinal axis X2, or along a vertical longitudinal median plane thereof, between the heel and the toes of the user, when the user is wearing the boot 1. The upper portion of the shell base 2 forms a passage opening for the foot of the user. A flexible liner 8, made of foam or fabric, is arranged inside the boot 1 to provide comfort for the user.
The shell base 2 comprises a sole 6, particularly an outsole, and two sides 2a and 2b, that is, a medial side 2a and a lateral side 2b, extending generally upwardly from the sole 6. The sides 2a and 2b extend towards the sole 6, that is, they have a concavity facing the sole 6. The sides 2a and 2b, together with the sole 6, define a cavity for receiving the foot of the user. The side 2a is an inner side, that is to say, it faces the right boot of the user, whereas the side 2b is an outer side. The sides 2a and 2b are transversely spaced apart by an upper opening or recess E2; they do not overlap, as is the case in so-called overlap boots.
The boot 1 also comprises an upper portion 4 for holding the calf of the user, which extends the shell base 2 and is provided to surround the lower leg, that is to say, the calf of the user. This upper portion, referred to as the “collar”, is articulated on the shell base 2, in particular about an axis Y4 perpendicular to the longitudinal vertical plane of the longitudinal axis X2 and parallel to the sole 6. The articulation between the collar 8 and the shell base 2 can be blocked during the sporting activity by a locking mechanism, not shown, which is arranged at the rear of the collar 8. Thus, the user's ankle is held during walking or skiing.
The boot 1 comprises mechanisms M1 for tightening the collar 4 around the calf of the user. These mechanisms M1 include a notched tightening device 100 and a self-gripping strip 102, such as a hook-and-loop fastener.
The boot 1 is also equipped with mechanisms M2 for tightening the shell base 2 around the foot of the user. These tightening mechanisms M2 are manipulated by the user between completely loosened configurations shown in
The tightening mechanism M2 includes a filiform element which, in the example, is a lace 10 running along the sides 2a and 2b. The lace 10 is a fabric cord extending through keepers 12 fixed to the sides 2a and 2b of the shell base 2. In the example, the keepers 12 are screwed onto the sides 2a and 2b, but they can also be welded or glued. Tightening the lace 10 makes it possible to bring the sides 2a and 2b closer to one another and to narrow the upper recess E2.
The tightening mechanisms M2 also include a rack 17 and a tightening lever 14. In the tightened and intermediate configurations, the lever 14 is engaged in the rack 17. A loosened configuration is suitable for inserting the user's foot in the boot 1, because the mechanisms M2 do not prevent the elastic deformation of the shell base 2 for passage of the user's foot.
The rack 17 extends transversely to the axis X2 and comprises a notched metal element 16 for receiving the lever 14, and a rigid tongue 18 which supports the notched element 16. The rigid tongue 18 is bulged or curved, with a concavity facing the sole 6 when the tightening mechanisms M2 are in the intermediate or tightened configuration, that is to say, that its center of curvature is arranged on the side of the sole 6. The notched element 16 can be glued or welded onto the tongue 18. It is provided with notches 160. The rack 17 is articulated on the side 2a of the shell base 2 by a hinge 20. The hinge 20 is fixed beneath a proximal end 18a of the tongue 18 and comprises a hook 200 yoking a triangular ring screwed to the side 2a.
The lever 14 includes a hinge shaft 140, provided to be housed in a notch 160 of the notched element 16. As shown in
To put on the boot, the user begins by clearing the rack 17 by tilting it around the shaft end straddled by the hook 200. The lace 10 is also loosened and the user can easily insert his foot inside the boot 1.
To tighten the foot within the shell base 2, the user folds the rack 17 towards the side 2b as shown by the arrow R1 in
Then, the user tilts the lever 14 from his left to his right, that is to say, towards the side 2a. The tilting of the lever 14 is shown in
In the tightened configuration, the rack 17 covers, or overlaps, the sides 2a and 2b due to the tensile force T2 of the lever 14. In other words, the rack 17 serves as a bridge between the sides 2a and 2b. Indeed, the rack 17, or more precisely the rigid tongue 18, takes support on the side 2a, via the hinge 20, and on the side 2b, via the distal end 18b of the tongue 18. Furthermore, the rack straddles across the recess E2 and the lever engages the rack at a position above the recess or opening and, in the configuration shown in
The tensile force T2 on the rack 17 makes it possible to bend the sides 2a and 2b in the direction of the sole 6, which has the effect of compressing the foot of the user height-wise. More specifically, it is the rigid tongue 18 which bends the sides 2a and 2b of the shell base 2. The tongue 18 pulls on the side 2a, on the one hand, and presses on the side 2b, on the other hand. The recess E2 provides a certain flexibility to the shell base 2, thereby enabling the shell base 2 to deform elastically under the pivoting action of the lever 14. F1 and F2 designate the bending forces of the rack 17 on the sides 2a and 2b, respectively. The bending forces F1 and F2 are directed towards the sole 6, that is to say, they make it possible to accentuate the curvature of the sides 2a and 2b. The bending forces F1 and F2 are equivalent, that is to say, the rack 17 substantially uniformly presses on the sides 2a and 2b of the shell base 2. Therefore, the user does not have the sensation of having one side tighter than the other.
The tilting of the lever 14 also causes the lace 10 to be housed in a notch 160 of the notched element 16. More specifically, the passage openings O14 for the lace 10 are separated from the hinge shaft 140 by a distance d1 corresponding to the spacing d2 between two notches of the notched element 16. Thus, the lace 10 is automatically blocked in the notched element 16 by tilting the lever 14. The two notches for receiving the shaft 140 and the lace 10 are separated by an empty notch.
In an alternative embodiment not shown, the lever 14 can be immovably strung on the lace 10.
In an alternative embodiment not shown, the lever 14 is attached to the shell base 2.
According to another alternative embodiment not shown, the lace 10 and the lever 14 may be linked by weld spots.
According to an alternative embodiment not shown, the notched element 16 and the rigid tongue 18 are integral or one-piece.
According to another alternative embodiment, the lace 10 is replaced by a metal cable, which is also a filiform element.
The technical features of the embodiments and alternatives considered above can be combined to generate other embodiments of the invention.
Further, at least because the invention is disclosed herein in a manner that enables one to make and use it, by virtue of the disclosure of particular exemplary embodiments of the invention, the invention can be practiced in the absence of any additional element or additional structure that is not specifically disclosed herein.
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