EP0133476A1 - Ski boot - Google Patents

Abstract

The upper part of the skiing boot has a cap part and a leg, the latter having a tibia side leg portion and a calf side leg portion. Between the tibia side leg portion and an inner boot is provided a support member which, on drawing together the two leg portions, exerts on the instep part the pressure necessary for tightening the skiing boot. Compared with known tightening devices, this leads to a much simpler solution for the same pressing force action in the instep region.

Description

The invention relates to a ski boot which is composed of a lower part provided with a sole and an upper part adjoining the lower part, the upper part having a cap part and a shaft.

In ski boots, in which both the upper part and the lower part are made almost exclusively of plastic, it is known to make it easier for the driver to get in and out of the ski boot by separating the calf-side part of the shaft from the rest of the shaft and as a calf part pivotally mounted in the heel area is formed. This calf part is held together by at least one drawstring with the rest of the shaft part.

In a known ski boot of this type (DE-OS 2 523 744 or USPS 3 975 838), the pivotable calf part is pulled against the calf by a drawstring attached to the shin-side part of the shaft and held together with the remaining part of the shaft. The contraction and the tight, play-free pressing of the ski boot against the foot of the driver, especially in the area of the instep, is achieved by a shin provided with a tensioning bracket. In this case, the tensioning device also tensions a tensioning cable running across the instep in a zigzag shape, thereby pulling and pressing the instep area of the ski boot against the foot of the skier.

In another known ski boot (US Pat. No. 3,793,749), a pivotable calf part is also provided which is separate from the shaft and is pulled against the calf by a drawstring fastened to the shin-side part of the shaft. In contrast to the first _- mentioned embodiment, however, no use is made of a tibia-side tensioning device in order to generate the tension required for smooth tensioning of the ski boot in the area of the instep. Rather, a pressing and tensioning part is arranged in the instep area and this is connected to the pivoting calf part by at least one tensioning cable. With this connection, in which the tension cable is connected to the swiveling calf part in the heel area, it is achieved that the tension cable is tensioned when the calf part is pivoted against the driver's calf and by pulling the tension band together. As a result, the pressing and tensioning part arranged on the instep is pulled firmly onto the instep and onto the foot of the driver, which achieves the rich and play-free connection required for skiing between the ski boot and the foot of the driver in the instep area.

In both of the above-mentioned known embodiments, the common feature is a tension element which transmits the tensioning movement for tight, play-free tensioning of the ski boot in the instep area. The clamping element is in both embodiments at least one tension cable guided over guides, which is actuated in the first-mentioned embodiment by the shin-side tensioning device and in the second-mentioned embodiment by the pivotable calf part. The tension cable with its guides, which are designed either as a Bowden cable or as a cable laid in guide grooves, represents a relatively complex part of the ski boot, which also requires careful assembly, because the length of the tension cable must be able to be adapted to different foot shapes.

This is where the invention comes in, which is based on the object of designing a ski boot of the type described at the outset in such a way that the ski boot is tensioned in the instep area without a tension cable, but in the same way as with a tension cable.

This object is achieved according to the invention in that a dimensionally stable support body extends over both a part of the instep and a part of the shin, which is held by a tightening strap which surrounds and contracts the shank part by pressing the support body against the same. It is thereby achieved that the pressing of the support body, in particular in the area at the transition from the shin area to the instep area, is carried out by the tensioning band without switching on an additional tensioning element.

• Fig. 1 einen vertikalen Längsschnitt eines Skischuhs vor dem Spannen des Spannbandes und
• Fig. 2 einen vertikalen Längsschnitt des Skischuhs in Fig. 1, jedoch nach Bendigung des Spannens des Zugbandes.

The invention is shown in the drawing in one embodiment and described below. Show it:

• Fig. 1 is a vertical longitudinal section of a ski boot before tensioning the strap and
• Fig. 2 is a vertical longitudinal section of the ski boot in Fig. 1, but after completing the tensioning of the drawstring.

The ski boot shown in FIGS. 1 and 2 has an upper part 1 and a lower part 2. The upper part 1 is composed of a cap part 3, which extends against the instep area, and a shaft 4, the shaft being formed in two parts and having a shin part 5 and a calf side part 6. The shin part 5 of the shank is pivotally mounted about an axis of rotation 8 running perpendicular to the longitudinal plane of the ski boot and the calf side part 6 of the shaft around an axis of rotation 9 running parallel to it and in the heel area.

The lower part of the ski boot 2 essentially has a sole 10; any fitting parts on the cap or on the heel of the sole 10 are omitted for the sake of simplicity.

The shin part 5 of the shin is provided with a tensioning strap 11, which is equipped with a tension lock (not shown), with which the two shaft portions (5, 6) are pulled together, so that an inner shoe 12 located in the interior of the upper part 1 passes through the tensioning strap 11 lays tightly around the driver's leg. The shin part 5 of the shin has an extension part 13 on the instep side, with a tension in the area of the transition from the sheep part to the instep part device 14, for example a clamping screw, is arranged.

The calf-side shaft part 6 has a material reinforcement 16 against the heel-side end 15, which gives the calf-side shaft part 6 greater rigidity. The wall reinforcement 16 can be designed in various ways and can also have ribs. The wall reinforcement 16 serves to prevent an impermissible change in shape due to the force exerted by the tensioning band 11.

Between the shin-side shaft part 5 and the inner shoe 12, a rigid support body 17 is mounted, which extends both over a part of the instep and over a part of the shin. The term "dimensionally stable" is to be understood as a shape in which practically no or only small elastic deformations can occur. In particular, the support body 17 should be able, after it is initially supported with its edge 17 ′ on the shin and attracted by the tensioning band 11 underneath, to also apply in an analogous manner to the part of the support body on the instep. 1 and 2, the support body 17, which is designed essentially as a reinforced shell part, is made of plastic and is provided with reinforcing beads or ribs 18 to increase its rigidity. It would also be possible to produce the support body 17 from metal in such a way that it also lies against the shin and instep and can thereby be elastically deformed by the forces that occur.

In Fig. 1 the insertion of the support body 17 and the start of the clamping process is shown. When the foot is inserted into the ski boot, the shine is located sheep on both sides part 5 in the dash-dotted position. After the support body 17 rests on the inner shoe 12, the shin part 5 of the shin is moved against the shin and pressed tightly against the support body 17 using the tensioning band 11, see FIG. 2. Because the support body lies snugly against the shin, the part of the support body 17 on the instep part of the instep part of the foot, see FIG. 2, from which the position of the part of the support body 17 on the instep side can be seen. The support body 17 produces the same pressing effect by this pivoting movement as if it were tensioned by a tensioning cable used in the embodiments of the prior art. By means of a tensioning device 14, for example a tensioning screw, the pressing force that occurs can also be adjusted sensitively.

The support body 17 not only easily achieves the pressing force required for skiing on the instep area of the skier's foot, but also further simplifications are possible. For example, it would be possible to dispense with the swiveling of the calf-side shaft part 6, since if the shin-side shaft part 5 can be swiveled sufficiently, entry is also possible without swiveling the shin-side shaft part 5.

A further simplification could be achieved in that the tibia-side shaft part 5 is dispensed with and the tensioning band 11 is fastened directly on the tibia-side part of the support body 17, and this then forms the tibia-side shaft part.

If the shin part 5 of the shin is used to hold the support body 17, this can optionally be designed without bearing on the pivot axis 8 if it can be held in position by the tensioning band 11. If the support body 17 is used without a shank part 5 on the shin side, its position is ensured by the tensioning band 11, which is prevented from slipping upwards by suitable means. Finally, the support body 17 could be e.g. resilient bracket, which is anchored in the region of the pivot shaft 8, are held in position.

Claims (8)

1. Ski boot, which is composed of a bottom part (2) provided with a sole and an upper part (1) adjoining the lower part, the upper part having a cap part (3) and a shaft (4), characterized in that both a part of the instep and a part of the shin extends a dimensionally stable support body (17) which is held by a tightening strap (11) enclosing and contracting the shaft part (4) on the shin area by pressing the support body against the same. 2. Ski boot according to claim 1, characterized in that the supporting body (17) is located below a shin-side shaft part (5) arranged above the cap part (3), to which the tensioning band (11) is fastened with a tensioning device. 3. Ski boot according to claim 2, characterized in that the shin-side shaft part (5) on the cap part (3) about a horizontal axis of rotation (8) is pivotally attached. 4. Ski boot according to claim 2 or 3, characterized in that the shin-side shaft part (5) with an extension part (13) extends partially over the instep. 5. Ski boot according to claim 1, characterized in that the support body (17) is a shell part in which the instep-side part is angled towards the shin-side part. Ski boot according to claim 5, characterized in that the supporting body reinforcements (18) which improve the stiffness of the shell part, e.g. Ribs, beads, wall thickening or the like. Ski boot according to one of claims 2 to 4, characterized in that the shin-side shaft part (5) has an adjusting device (14), e.g. has an adjusting screw for adjusting the pressing pressure exerted by the supporting body (17). 8. Ski boot according to one of claims 1 to 7, characterized in that the shaft (4) a pivotable calf-side shaft part (6) separate from the shaft with a reinforcement (16) arranged in the region of its heel end, e.g. Wall reinforcements, beads or ribs, which is held by the tensioning band (11) on the shaft (4).

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