EP0419922B1 - Ski boot - Google Patents

Abstract

On the heel part (26) of the ski boot, guide openings (46) for the tensioning cables (56, 56') are provided above the articulation (24). On lateral rear end regions, the tongue part (28) has guide eyelets (40) and, between these guide eyelets (40) and the longitudinal central plane of the boot, passages (42, 44). The tensioning cables (56, 56') starting from the tensioning device (52) run in a diametrically opposed manner from the guide openings (46) to the guide eyelets (40) and under the tongue part (28) to the associated passages (42, 44). Between the passages (42, 44), the tensioning cables (56, 56') are guided over the tongue part (28). Their ends on this side are fixed at fastening points (60, 60'), covered by the tongue part (28), on the shell part (14). The tensioning cables (56, 56') form a guide for the tongue part (28) so that the ski boot can be closed simply by tightening the tensioning cables (56, 56') by means of the tensioning device (52). <IMAGE>

Description

The present invention relates to a ski boot according to the preamble of claim 1.

Such a ski boot is known for example from US-A-4,281,468 (& WO-A-81/00505). This has a shell part provided with a sole, which encloses the entire foot area and which has lateral, tongue-shaped tabs projecting in the leg area toward the top. The shell part is cut out in the instep area and is covered in a saddle shape in the instep and shin area by a tongue part, which is fastened to the shell part by means of a rivet in the toe area in the middle of the shoe longitudinally. The tongue part is swung forward to get in and out of the ski boot. A heel piece is articulated to the lateral tabs above the ankle. This encompasses the leg in the area between the ankle and the calf and can be pivoted from a rest position, which corresponds to the usual driving position, in the direction towards the front when the lower leg is bent forward. The tongue part is wave-shaped, and the sections of three tension cable loops run over it in the wave troughs. A first tension cable loop is fixed on the inside of the ski boot on the outside of the shell part, runs in the instep area over the tongue part and can be attached to a tension lever fixed on the outside of the ski shoe. A second tension cable loop runs in the transition area between the instep and shinbone over the tongue part, with the tension cable loop on the inside of the ski boot is fixed to the shell part in the area of the ankle and the corresponding tensioning lever on the outside of the ski boot is also located in the area of the ankle. The third tension cable loop encompasses the tongue and heel part in the area of the shin, the tensioning lever in question being attached to the heel part on the outside of the ski boot. By tightening the tensioning cable loops, the shell part is adapted to the foot and lower leg area of the skier, so that no further fixable and lockable holding elements inside the ski boot are necessary. This well-known ski boot gives the driver a very good grip, but opening and closing the ski boot and setting the correct tension of the tension cable loops is time-consuming. Since the shell part of the known ski boot is adapted to the anatomy of the foot, large clamping forces are necessary, which makes it difficult to pivot the clamping levers.

Furthermore, a rear entry ski boot is known from EP-A 0 053 340. This has a shell part covering the foot in the toe and instep area with tabs projecting laterally towards the top. In the instep area, the shell part is cut out and in the instep and shin area is covered by a tongue part in a saddle shape. The tongue part is connected to the shell part in the region of its tip by means of a fastening element. In the area of the heel, a heel part is articulated on the shell part by means of swivel joints, which can be pivoted backwards from a rest position to open the ski boot about the swivel joint. In order to close the ski boot, the heel section is swiveled forward and by means of clamped to the upper end region of the tongue part. A steel band is attached to the tongue part at its lateral end areas in the transition between the instep and shin area, which runs in the direction towards the heel to the relevant pivot joint of the heel part. The steel strip is connected at its rear end to a cable which runs around a deflection to a locking device provided on the heel part. When the ski boot is closed by swiveling the heel part forward, the cable is thus tensioned, which results in the tongue part being pulled back in the direction of the heel in order to provide the skier with a good grip. When the heel part is folded back to open the ski boot, the tongue part is released towards the front. In this known ski boot, the shell and tongue part are adapted to the anatomy of the foot of the driver in a user-friendly manner, but this principle is not suitable for front entry ski boots.

DE-A-2 341 658 discloses a ski boot, on the tongue part of which a rope is guided, which can be placed over hooks arranged on both sides of the entry opening on the shell part and tensioned by means of a tensioning device arranged on the tongue part.

It is therefore an object of the present invention to provide a generic ski boot which, while maintaining the good adaptation of the ski boot shell to the foot of the driver, ensures easier operation for closing or opening the ski boot.

This object is achieved by the features of the characterizing part of claim 1.

Due to the articulation of the heel part in the area of the heel bone on the shell part and the course of the tensioning element from one on the heel part above its articulation to the Only a single tensioning element is necessary for the guide part provided for a guide element on the tongue part, on the lateral end regions of the transition between the instep and shin region. The cable-shaped tensioning element forms a compulsory guide for the tongue when the ski boot is closed, because the tensioning element running to the guide elements pulls the tongue part more firmly against the guide on the heel part, the more the tensioning element is tightened by means of the tensioning device. For closing the ski boot, only the tensioning of the tensioning element by means of the tensioning device is necessary. The tongue part is automatically pulled into the correct position. Because the tensioning element is guided on the heel part above its articulation on the shell part, the tongue part is pulled against the heel part in the longitudinal direction of the shoe when the ski boot is closed, which also gives the driver a secure hold in the area of the shin.

Further preferred forms of training of the ski boot according to the invention are specified in the dependent claims.

Figuren 1 und 2

in perspektivischer Darstellung, einen geöffneten bzw. geschlossenen Skischuh,

Figuren 3 bis 5

in Schnitt eine Spannvorrichtung,

Figur 6

eine Kulissenführung für das Betätigungselement der Spannvorrichtung, und

Figur 7

einen Teil einer weiteren Ausbildungsform der Spannvorrichtung.

The present invention will now be described with reference to an embodiment shown in the drawing. It shows purely schematically:

Figures 1 and 2

in perspective, an open or closed ski boot,

Figures 3 to 5

a clamping device in section,

Figure 6

a link guide for the actuating element of the clamping device, and

Figure 7

part of a further embodiment of the clamping device.

The plastic shell 10 of the ski boot shown in FIGS. 1 and 2 has a shell part 14 provided with a sole 12. This encompasses the skier's foot in the toe and instep area 16 and in the lower heel area 18 and has two lateral tabs 20 protruding towards the top in the ankle area. On its front side, a cutout 22 is provided on the shell part 14 in the area of the instep.

In the area of the heel bone, a heel part 26 is fastened to the shell part 14 by means of a joint 24. This covers the lower rear leg area between the lower heel area and the calf and laterally overlaps the upwardly projecting tabs 20 of the shell part 14. The heel part 26 is defined by an axis defined by the joint 24, parallel to the sole 12 and perpendicular to the longitudinal center plane of the shoe in the rest position shown in the figures when the lower leg is bent forward in the direction toward the front. The rest position of the heel part 26 corresponds to the normal posture of the lower leg when driving.

The shell 10 further has a tongue part 28 covering the instep and shin region 16 with a section 28a covering the instep region and a lower part Section 28b covering the shin region. The tongue part 28 is wave-shaped in section 28a and in the transition area between the two sections 28a and 28b, the wave valleys 30 and wave crests 30 'running from one side of the ski boot to the other. The tongue part 28 overlaps the heel part 26 at its rear end regions.

At its two front lateral corner areas, the tongue part 28 is pivotably articulated by means of rivets 32 on one tab 34 each. The two tabs 34, only one of which is visible in FIGS. 1 and 2, protrude from the tongue part 28 in the direction towards the front and are guided in corresponding pockets 36 approximately in the longitudinal direction A of the shoe. On their area protruding from the tongue part 28, the tabs 34 have guide slots 38 extending in their longitudinal extent, through which a further rivet 32 'runs. The rivet 32 'is arranged on the shell part 14 in the open end region of the pockets 36. In the shoe longitudinal direction A towards the back until the guide slots 38 on the rivets 32 'extended tabs 34, these are pivotable about the rivets 32', as shown in Figure 1. In this position of the tabs 34, the tongue part 28 is also in its rear end position. On the other hand, the tabs 34 in the longitudinal direction A towards the front are partially or fully inserted into the pockets 36, so that they are guided in the longitudinal direction of the pockets 36 and about the axis defined by the rivets 32 ', approximately parallel to the sole 12 and perpendicular to the longitudinal axis of the shoe no longer pivotable (see Fig. 2). Regardless of the position of the tabs 34, the tongue part 28 is on these but pivotable about the axis defined by the rivets 32 and essentially parallel to the sole 12 and transverse to the longitudinal plane of the shoe.

At the lateral rear corner areas in the transition from section 28a to section 28b, a guide eyelet 40 is each freely rotatably mounted on the tongue part 28. Approximately in the middle between these guide eyes 40 and the longitudinal center plane of the shoe, the tongue 28 has a passage 42 in the transition area between the sections 28a and 28b, these two passages 42 being located in the same trough 30. With regard to these passages 42 in the longitudinal direction A of the shoe toward the front, two further passages 44 are provided in the next wave trough 30.

The heel part 26 has a guide opening 46 on both sides above the joint 24 and viewed in the longitudinal direction A of the shoe, offset towards the rear, from which a schematically indicated guide channel 48 runs into the rear lower end region of the heel part 26 inside the heel part 26. The corresponding openings at this end of the guide channels 48 are designated by 50. Above the openings 50, a tensioning device 52 with a drum-shaped winding element 54 for two tensioning cables 56 and 56 'is provided on the heel part 26. The tensioning device 52 has a toggle-shaped actuating element 58, which can be pivoted back and forth about an axis running in the longitudinal center plane of the shoe and parallel to the heel part 26. This tensioning device 52 is described in detail below. For the understanding of FIGS. 1 and 2, it is sufficient to know that by swiveling the actuating element 58 back and forth in a working swiveling area the tensioning cables 56, 56 'are intermittently wound onto the winding element 54 and the pivoting element 54 for releasing the tensioning cables 56, 56' can be released by pivoting the actuating element 58 counter to the winding direction from the working pivot area.

The tension cable 56 runs from the winding element 54 to the opening 50 and through the corresponding guide channel 48 to the guide opening 46, from this to the relevant guide eye 40 on the tongue part 28 and below the tongue part 28 to the passage 42, from where the tension cable 56 on the outside of the tongue part 28 in Wave valley 30 runs over the instep and shin area to the passage 42 opposite the longitudinal center plane of the shoe. There the tension cable 56 again penetrates the tongue part 28 and runs below it to a fastening point 60 on the shell part 14, where the end of the tension cable 56 on this side is firmly anchored. The other tensioning cable 56 runs opposite from the tensioning device 52 through the corresponding guide channel 48 to the guide opening 46, from this to the guide eyelet 40 and below the tongue part 28 to the passage 44. Between the two passages 44, the tensioning cable 56 'runs parallel to the tensioning cable 56 in the adjacent trough 30 and is attached with its end on this side in a corresponding manner to the attachment point 60 'on the shell part 14. The two attachment points 60, 60 'are located opposite each other with respect to the longitudinal center plane of the shoe and are seen in the longitudinal direction A of the shoe, with respect to the guide openings 46 offset toward the front on the shell part 14. When the tongue part 28 resting on the shell part 14, the fastening points 60, 60 'are covered by this.

As indicated by dashed lines in FIG. 2, the space between the shell 10 and the foot of the wearer is filled in a manner known per se by a soft, padded inner shoe 62.

With the tongue part 28 open, as shown in FIG. 1, the ski boot can be climbed into. Now, by simply swinging the actuating element 58 back and forth, the two tension cables 56, 56 'are wound onto the winding element 54, as a result of which the tongue part 28 is pulled towards the sole 14. The tabs 34 pivot about the respective rivet 32 'clockwise until the longitudinal extension of the tabs 34 extends in the direction of the pockets 36. By further tensioning the tensioning cable 56, 56 ', the tongue part 28 is pushed forward in the shoe longitudinal direction A by executing a swiveling movement, whereby the tabs 34 slide deeper into the pockets 36. As a result, the front end region of the section 28a of the tongue part 28 covering the instep is held on the shell part 14 in a precisely defined manner. With a further increase in the tensioning force in the tensioning cables 56, 56 ', the tongue part 28 is brought to rest against the shell part 14, the guide eyes 40 coming to rest in the area of the guide openings 46 in the heel area 18 (see FIG. 2). Because the tongue part 28 is supported freely in the longitudinal direction A of the shoe and can be pivoted by the rivets 32, the tongue part 28 can adapt to the anatomy of the foot or lower leg area of the wearer while deforming the shell part 14. In particular, the guidance of the tensioning cable 56, 56 'in the area of the tongue part 28 and the high tensioning force the tensioning device 52 for an optimal adaptation of the shell 10 to the individual foot shape of the driver by changing the cross-section of the ski boot in the area covered by the tongue part 28. The high tension achieved in the tensioning cables 56, 56 'gives the saddle-shaped tongue part 28 in the area of the guide eyelets 40 a quasi-joint, which serves for a clean guidance of the section 28b covering the lower shin area during the torsional flexing movement of the lower leg. Moreover, with this flex movement, due to the guidance of the tensioning cables 56, 56 'from the heel part 26 to the tongue part 28 above the joints 24, the heel part 26 is pulled forward in a pivoting movement, which also gives the driver a secure hold in the ski boot in this situation. It should be noted that when the ski boot is closed, the tensioning cables 56, 56 'serve as guide strands for the forced closing movement of the tongue part 28.

In order to open the ski boot, the actuating element 58 is moved outside the working swivel area counter to the tensioning direction, as a result of which the winding element 54 is released. As a result, the large tension in the tensioning cables 56, 56 'is immediately reduced and the unwinding of the wound section of the tensioning cables 56, 56' when swiveling the pulling part 28 forward enables. During this forward pivoting of the tongue part 28, the tabs 34 slide in the pockets 36 in the longitudinal direction A of the shoe, since the tongue part 28 bears against the shell part 14 with its front end in the region of the longitudinal center plane of the shoe. As a result, the tongue part 28 is brought into the position shown in FIG. 1.

A tensioning device particularly suitable for the described ski boot, which can apply the necessary high tensioning forces in the tensioning cables 56, 56 'without great effort by the wearer of the ski shoe to the actuating element 58 and nevertheless winding large lengths of the tensioning cables 56, 56' with only allows a few swivel strokes of the actuating element 58 will now be described in more detail below.

The tensioning device 52 shown in FIGS. 3 to 5 has a housing part 64 and a cover 66. The tensioning device 52 lies with the housing part 64 on the heel part 26 of the ski boot and is fastened to it, for example, by means of screws, not shown. FIGS. 3 and 4 show the tensioning device 52 in a section along the longitudinal center plane of the shoe and FIG. 5 shows a view of the tensioning device 52 in the direction of arrow V of FIG. 4, the cover 66 not being shown.

The actuating element 58 designed as a gag sits on the upper end region of a shaft 68, the longitudinal axis 68 'of which intersects the axis of rotation 54' of the winding element 54. The longitudinal axis 68 'extends approximately in the longitudinal center plane of the shoe and parallel to the heel part 26, whereas the axis of rotation 54' is substantially perpendicular to the heel part 26 (see FIGS. 1 and 2).

The actuating element 58 is connected to the shaft 68 via a clockwise free-wheeling sleeve 70. Moreover, the shaft 68 is counterclockwise active further freewheel sleeve 72 supported on the cover 66. The shaft 68 can thus only be rotated counterclockwise (winding direction). By means of a screw 74 extending in the direction of the longitudinal axis 68 ', the cap-shaped actuating element 58 seated on the upper end of the shaft 68 is connected to the latter in a stroke-resistant manner. The housing part 64 has an extension 76 which projects upward into the region of the actuating element 58 and on which a guide pin 78 which projects in the direction towards the actuating element 58 is fixedly arranged. With its free end region, the guide pin 78 engages in a slot-shaped groove 80 in the actuating element 58. The development of the groove 80 is shown in FIG. 6. The groove 80 has a lower groove part 80a with respect to the longitudinal axis 68 'in the circumferential direction, an adjoining rising groove part 80b and a shorter groove part 80c, which in turn runs in the circumferential direction, which at its end remote from the groove part 80b by a short, downwardly directed latching part 80d is limited. The lower groove part 80a defines a working pivot area B. If the actuating element 58 is pivoted such that the guide pin 78 is located within the working pivot area B, the actuating element 58 together with the shaft 68 is raised to an upper clamping position, as shown in FIG. 3 is. Within the working swivel area B, the actuating element 58 can thus be pivoted without the shaft 68 being lowered in the direction of the longitudinal axis 68 '. If, on the other hand, the actuating element 58 is pivoted clockwise, counter to the winding direction, out of the working pivot area B, the rising groove part B runs along the guide pin 78, which results has that the actuating element 58 is moved together with the shaft 68 in the direction of the longitudinal axis 68 'down. If the actuating element 58 is pivoted clockwise so far that the groove part 80c is located at the guide pin 78, the actuating element 58 together with the shaft 68 is lowered into the lower release position shown in FIGS. 4 and 5 and labeled 58 '. In this context, it should be mentioned that the shaft 68 is guided in the further freewheel sleeve 72 in the direction of the longitudinal axis 68 'and that the actuating element 58 can be freely pivoted clockwise without taking the shaft 68 with it. If the actuating element 58 is pivoted to such an extent that the latching part 80d lies with the guide pin 78, the actuating element 58 is secured against unwanted pivoting in the counterclockwise direction, since the shaft 68 is pushed in the direction by the force of the compression spring 84, which is supported at one end on a shoulder 82 of the shaft 68 is biased towards the top, so that the latching part 80d is held in the guide pin 78.

At the lower end region of the shaft 68, there is a sleeve 86 which is connected to the latter by means of a pin 88 running transversely through the sleeve 86 and the shaft 68, in a rotationally fixed and stroke-resistant manner. The sleeve 86 penetrates an opening 90 in the cover 66. A hat-shaped coupling part 92 with an internal toothing 94 is integrally formed on the sleeve 68 at the upper end. When the shaft 68 is in the clamping position, a corresponding outer toothing 96 of a stationary gear-shaped further coupling part 98 engages in this inner toothing 94, as shown in FIG. 3. When in the release position 58 'located actuator 58 and thus in the direction of the shaft 68 which is displaced downward, the coupling part 92 is extended from the stationary coupling part 98, as is shown in FIGS. 4 and 5.

A bevel gear 100 of a bevel gear transmission 102 and a tubular shaft part 104 are integrally formed on the stationary coupling part 98 on the side opposite the coupling part 92. The shaft 68 thus runs freely rotatable through the coupling part 98, the bevel gear 100 and the shaft part 104. The shaft part 104 penetrates a bore 106 of a pin-shaped, in the direction of the axis of rotation 54 'running bearing part 108 for the winding element 54. At the upper free end region, the Shaft part 104 has a circumferential groove 110, in which a spring ring 112 is arranged. The spring ring 112 is supported in the direction of the longitudinal axis 68 'on the bearing part 108 and holds the bevel gear 100 in meshing engagement with another bevel gear 114 formed on the winding element 54. At the upper end of the shaft part 104, the end remote from the shoulder 82 of the shaft 68 is supported the compression spring 84.

The storage part 108 is fastened by means of a screw 116 extending in the direction of the axis of rotation 54 'to the housing part 64 and is supported at the other end in a blind hole-shaped bearing recess 117 in the cover 66. In the central region between the bore 106 and the end of the shaft part 104 facing the housing part 64, the latter has a circumferential bead 118 projecting in the radial direction. The drum-shaped winding element 54 sits freely in the area between the housing part 64 and the bead 118 rotatable on the bearing part 108, this being held stationary in the direction of the axis of rotation 54 'by the housing part 64 and a shoulder 120 in the axial direction on the bead 118 on the winding element 54. The bevel gear 114 is integrally formed on the drum-shaped winding element 54 and projects with respect to the drum-shaped part on the side facing away from the housing part 64.

The winding element 54 has two circumferential winding grooves 122 arranged next to each other in the drum-shaped part, each for a tensioning cable 56 or 56 '. The width of these winding grooves 122 in the axial direction is insignificantly larger than the diameter of the tensioning cables 56, 56 'so that they are guided exactly in the area of the winding element 54 and wedging sections of the tensioning cables 56, 56' against each other is prevented. Furthermore, the winding element 54 has in the region of the winding grooves 122 diametrically opposite radial slots 124, each of which is assigned to a winding groove 122 and has an extension in its inner end region, as seen in the radial direction, in which the ends of the relevant tensioning cables 56, 56 ′ on this side are held in a known manner by means of an end nipple. In the area between the guide openings 46 (see Figures 1 and 2) and the winding grooves 122, the tensioning cables 56, 56 'are guided in tubular guide sleeves 126. These have thickenings 128 in the end region on the clamping device side, by means of which they are held in corresponding recesses in the housing part 64.

FIG. 7 shows a clamping device 52 similar to that shown in FIGS. 3 to 5, but now that Bevel gear 102 itself is designed as a coupling between the shaft 68 and the winding element 54. Since the guidance of the actuating element 58 on the extension 76 of the housing part 64, the coupling between the actuating element 58 and the shaft 68 and the support of the shaft 68 on the cover 66 are identical to those in the clamping device 52 shown in FIGS. 3 to 5, these are Parts no longer shown in FIG. 7. The storage part 108 and the winding element 54 which is freely rotatably mounted thereon are also no longer described for the same reasons. The bevel gear 100 'formed in one piece with the tubular shaft part 104' sits on the shaft 68 and is connected to it by means of a pin 88 'in a rotationally and stroke-resistant manner. The shaft part 104 is freely rotatable in the bore 106 and guided in the direction of the longitudinal axis 68 '. On the bevel gear 100, a compression spring 84 'is supported, which engages around the shaft 68 and is supported at the other end on the cover 66. This compression spring 84 'presses the bevel gear 100 against the bevel gear 114' formed on the winding element 54 '. If the actuating element 58 is in the working swivel area B (see FIGS. 3 to 6), the bevel gear 100 'is in the position shown in FIG. 7, in which it meshes with the bevel gear 114'. If, on the other hand, the actuating element 58 is pivoted in such a way that the groove part 80c is located at the guide pin 78, then the bevel gear 100 'due to the movement of the shaft 68 in the direction of its longitudinal axis 68' against the force of the compression spring 84 'from the engagement with the bevel gear 114 ' solved. With the same choice of material of the bevel gears 100, 114, 100 ', 114' in both shown forms of construction of the tensioning device 52 there are larger tractive forces in the form of construction according to FIGS in the tensioning cable 56, 56 'permissible, since by means of a claw or, as shown in these figures, tooth coupling, larger torques can be disengaged compared to the toothing of the bevel gears 114 without damaging the respective toothing, because in the latter case, a single one each when disengaging Tooth flank must bear the entire torque.

The operation of the tensioning devices 52 is as follows. When the ski boot is open and the tensioning device 52 is released, the actuating element 58 is pivoted clockwise outside of the working pivot area B, so that the latching part 80d of the groove 80 is located at the guide pin 78. The shaft 68 and the actuating element 58 are lowered into the release position 58 ', as shown in Figures 4 and 5. The coupling between the coupling parts 92 and 98 or between the two bevel gears 100 'and 114' according to Figure 7 is released. The winding element 54 is freely rotatable. To roll up the tensioning cable 56, 56 ', the actuating element 58 is now pivoted counterclockwise (winding direction) from the latching part 80d into the working swivel area B (see FIG. 6). The actuating element 58 moves together with the shaft 68 into the upper clamping position according to FIGS. 3 and 7. The two coupling parts 92, 98 and the two bevel gears 100 ′, 114 ′ come into engagement with one another. By pivoting the actuating element 58 back and forth within the working pivot area B, the shaft 68 is now taken along in the winding direction when the actuating element 58 is rotated counterclockwise. The resulting rotation of the shaft 68 is transmitted to the winding element 54 via the bevel gear 102, whereby the tension cables 56, 56 'are intermittently wound up. The freewheel sleeve 72 prevents rotation of the shaft 68 clockwise and thus also prevents unwinding of the tensioning cables 56, 56 'from the winding element 54. By pivoting the actuating element 58 accordingly, the desired tensile force can now be built up in the tensioning cables 56, 56' . As soon as the desired tensile force in the tensioning cables 56, 56 'has been reached, that is to say as soon as the ski boot according to FIGS. 1 and 2 sits snugly on the foot, the actuating element 58 is left in the respective position.

If the tensioning cables 56, 56 'now have to be loosened, the actuating element 58 is briefly pivoted counterclockwise in the clockwise direction, so that the two coupling parts 92, 98 or bevel gears 100', 114 '(FIG. 7) briefly disengage. Due to the tensile force in the tensioning cables 56, 56 ', these are now partially unwound from the winding element 54. The winding element 54 is blocked again by subsequently pivoting the actuating element 58 back into the working pivot area B. In order to open the ski boot, the actuating element 58 is pivoted apart from the working swivel area B in such a way that the groove part 80c or the latching part 80d comes to rest on the guide pin 78. As a result, the winding element 54 is released in an analogous manner, so that by pivoting the tongue part 28 forward (see FIGS. 1 and 2) the tensioning cables 56, 56 'can now be unwound to the required length from the winding element 54.

In the clamping devices shown in Figures 3 to 7 52 can be accommodated in a small housing part 64 with cover 66 winding elements 54 with a large diameter. The result of this is that large lengths of tensioning cables 56, 56 'can be wound up with a few revolutions of the winding element 54. Nevertheless, due to the constant force-displacement ratios and the ergonomic arrangement of the actuating element 58, large tensile forces in the tensioning cables 56, 56 'can be comfortably achieved. A single actuating element 58 is required for the tensioning and the quick release of the tensioning device 52, which increases the ease of use considerably.

It is also conceivable to wind up the two end sections of the same cable-shaped tensioning element in the two winding grooves. Of course, the tensioning device according to the invention can also be used to actuate foot holding devices provided inside the ski boot.

Claims (12)

1. Ski boot with a shell part equipped with a sole, with a heel part mounted on the shell part so as to be forwardly pivotable out of a position of rest about an axis extending essentially parallel to the sole, with a tongue part which is articulated on the shell part in the toe/instep region and which is forwardly pivotable for entry into and exit from the ski boot and covers the shell part in the instep/shin region, and with a clamping device for the releasable clamping of a cable-like clamping element extending over the tongue part, characterized in that the heel part (26) is articulated on the shell part (14) in the region of the heel bone, and the clamping element (56, 56') extends on both sides of the ski boot from a guide (46) located on the heel part (26) above its point of articulation (24) on the shell part (14) to a guide element (40) on the tongue part (28) in the lateral end regions of the latter at the transition between the instep region (28a) and shin region (28b).
2. Ski boot according to Claim 1, characterized in that the tongue part (28) is guided on the shell part (14), in the toe/instep region (16), so as to be displaceable essentially in the longitudinal direction (A) of the boot and is mounted pivotably about an axis extending transversely relative to the longitudinal direction (A) of the boot and approximately parallel to the sole.
3. Ski boot according to Claim 2, characterized in that the tongue part (28) is mounted pivotably, in each of its two lateral front end regions, on a strap (34) guided on the shell part (14), with its longitudinal extension extending essentially in the longitudinal direction (A) of the boot, so as to be displaceable approximately in the longitudinal direction (A) of the boot.
4. Ski boot according to Claim 3, characterized in that, when the tongue part (28) is in a rear end position, the straps (34) are pivotable about an axis extending transversely relative to the longitudinal direction (A) of the boot and essentially parallel to the sole (12).
5. Ski boot according to one of Claims 1 to 4, characterized in that the clamping device (52) is provided on the heel part (26), and the clamping element (56, 56') emerges from the heel part (26) at the guides (46).
6. Ski boot according to one of Claims 1 to 5, characterized in that passages (42, 44) for the clamping element (56, 56') are provided in the tongue part (28), preferably approximately centrally, on both sides between the guide elements (40) and the longitudinal mid-plane of the boot, and the clamping element (56, 56') extends from the guide elements (40) as far as the corresponding passages (42, 44) under the tongue part (28) and, between the passages (42, 44), over this.
7. Ski boot according to one of Claims 1 to 5, characterized in that the clamping element has two clamping members (56, 56') which are connected operatively to a common clamping device (52) and which each extend on one side of the ski boot from the guide (46) to the guide element (49) and at least partially over the tongue part (28) onto the other side of the ski boot to a fastening point (60, 60') provided on the shell part (14).
8. Ski boot according to Claim 7, characterized in that the fastening points (60, 60') are offset relative to the guides (46) towards the boot tip in the longitudinal direction (A) of the boot and, when the tongue part (28) bears on the shell part (14), are preferably covered by these.
9. Ski boot according to Claim 7 or 8, characterized in that passages (42, 44) for each clamping member (56, 56') are provided in the tongue part (28), preferably approximately centrally, on both sides between the guide elements (40) and the longitudinal mid-plane of the boot, and these clamping members (56, 56') extend from the guide elements (40) as far as the corresponding passages (42, 44) under the tongue part (28) and, between the passages (42, 44), over this.
10. Ski boot according to Claim 9, characterized in that passages (42, 44) provided on each side for the clamping members (56, 56') are offset relative to one another in the longitudinal direction (A) of the boot, and in the region between the passages (42, 44) the clamping members (56, 56') are spaced from one another in the longitudinal direction (A) of the boot and extend essentially parallel to one another.
11. Ski boot according to one of Claims 1 to 10, characterized in that the tongue part (28) is of wave-shaped design in the region of the clamping element (56, 56'), and the clamping element or each clamping member (56, 56') extends in a wave trough (30).
12. Ski boot according to one of Claims 1 to 11, characterized in that the clamping device (52) has a rotatably mounted winding-up element (54) for the winding up and unwinding of the clamping element (56, 56'), a transmission member (68) supported by means of a freewheel (72) acting in the winding-up direction an actuating element (58) pivotable by hand in both directions and connected via a counteracting further freewheel (70) to the transmission member (68), and a coupling (92, 98) actuable from outside the clamping device (52) and for the releasable connection of the transmission member (68) to the winding-up element (54).

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