EP0935489A1 - Device for modifying the lateral bending of a ski boot - Google Patents

Abstract

PCT No. PCT/EP97/05970 Sec. 371 Date Apr. 27, 1999 Sec. 102(e) Date Apr. 27, 1999 PCT Filed Oct. 29, 1997 PCT Pub. No. WO98/18528 PCT Pub. Date May 7, 1998An adjusting device for adjusting the angle between a ski boot and a sliding surface of an associated ski. The adjusting device operates as a function of parameters correlated with turning of the associated ski by a skier causing parameter-dependent pivoting of the ski boot relative to the sliding surface of the ski. During a turn, the sliding surface of the ski is inclined to an angle greater than the boot giving the skier better ski edge penetration.

Description

 Device for changing the lateral inclination of a ski boot on a ski

The invention relates to a device for adjusting an angle in the lateral direction between the ski boot or leg of the skier and the tread of an associated ski.

In modern ski boots, the shank can often be swiveled relative to the sole of the shoe about a longitudinal axis of the shoe. A corresponding setting - also known as a canting setting - allows anatomical peculiarities of the skier, such as O- or X-legs are compensated, such that the treads of the skis lie in a common plane or in mutually parallel planes with comfortable posture. This makes it easier for the skier to avoid undesired tilting of the skis.

In the case of a ski known from DE 26 03 676 A1, a base plate is arranged between the ski boot and the ski, the upper side of the shoe on the shoe side being arranged such that it can be pivoted about a longitudinal axis of the ski relative to the lower side of the ski, this pivoting adjustment being made by longitudinal adjustment of wedge elements between the upper and lower side of the base plate he follows. A canting setting is also possible with this.

Regardless of the respective canting setting when cornering, the angle with which the inside edges of the curve

Reach into the ground, determined by the angle,

CONFIRMATION COPY with which the skier bends his legs towards the inside of the curve compared to normal straight-ahead driving.

The object of the invention is to show new possibilities for controlling the tilting of the skis.

This object is achieved according to the invention in that an adjusting device, which operates as a function of parameters correlated with cornering, causes a parameter-dependent pivoting of the ski boot or the boot shaft relative to the tread of the ski about a longitudinal axis of the ski and / or a parameter-dependent actuating force which causes the boot or tries to pivot its shaft in the sideways direction relative to the tread of the ski, in such a way that at least one predetermined ski when cornering compared to the sideways inclination of the

Shoe or leg increased tilt and / or increased edge pressure is performed.

In this context, it is provided in particular that when the skier or his legs bends when cornering - at least when the skier or his legs are inclined towards the inside of the curve - the adjustment device controls a sideways tilting of the ski shoe or his shaft relative to the associated ski, in such a way that the vertical axis of the tread of the given ski, in particular of the ski on the outside of the curve, is more inclined towards the inside of the curve than the vertical axis of the associated ski boot or its shaft.

The invention is based on the general idea of parameters which are characteristic of cornering, in particular re the deflection of the skis that occurs when cornering, the longitudinal ends of which are bent in the direction of the ski vertical axis when cornering relative to the central region of the ski, for controlling a sideways pivoting of the ski boot or its shaft or for controlling a corresponding actuating force in order to engage the edges or pressure to raise at least one ski when cornering.

In today's driving technique, the ski on the outside of the curve is particularly stressed when cornering, so that its edge engagement when cornering is of greater importance. Accordingly, it is expedient to design the adjustment device so that the increased edge engagement or edge pressure occurs in each case on the ski on the outside of the curve. In principle, however, it is also possible to effect a swivel adjustment or positioning force for increased edge engagement or edge pressure in the ski on the inside of the curve. The technology according to the invention is therefore in principle also suitable for new or future driving styles.

If the changes in the angle between the tread and the upper and the effective forces between the upper and the front of the right and left skis are opposite to each other, the right and left skis only need to be swapped with each other if, instead of the outer ski on the inside of the curve when cornering increased edge engagement or edge pressure is desired.

The adjusting device can advantageously be arranged between the ski and ski binding and, for example, the

Take over the function of a spacer or base plate on which the ski boot is supported at a vertical distance from the top of the ski and is held by a ski binding when skiing, which in turn can be mounted on the spacer or base plate.

However, it is also possible and advantageous to arrange the adjusting device as part of the ski or to combine it with the shoe. In the former case, for example, the top of the ski in the area of the ski bindings or the ski boot can be inclined relative to the ski tread about a longitudinal axis of the ski, depending on the parameters. In the other case, the shaft of the ski boot can be swiveled sideways relative to the shoe sole, depending on the parameters.

Otherwise, with regard to preferred features of the invention, reference is made to the claims and the following explanation of the drawing, on the basis of which the function of the invention and particularly preferred embodiments are described in more detail.

It shows

1 is a plan view of a pair of skis,

2 shows a ski in a side view, the state of normal straight-line driving on a flat slope being shown,

3 shows a sectional view corresponding to the sectional line III-III in FIG. 2, FIG. 4 shows a side view of the ski in a bent state which is characteristic of cornering, FIG. 5 shows a sectional view corresponding to the sectional line VV in FIG. 4, Fig. 6 is a side view corresponding to FIG. 4

Skis when cornering, this ski having a comparatively rigid ski center area, Fig. 7 is a sectional view corresponding to the section line VII-VII in Fig. 2 with constructive details, the state of normal straight travel is shown, Fig. 8 is a sectional view of the corresponding section line

VIII-VIII in FIG. 2 with constructive details, again showing the state of normal straight-ahead driving, FIG. 9 a sectional view corresponding to FIG. 7 when cornering, FIG. 10 a sectional view corresponding to FIG. 8 when cornering,

11 shows a side view of a further adjusting device, the top side of the adjusting device in FIG. 11 being at the bottom, FIG. 12 shows a view of the underside of the adjusting device, FIG. 13 shows a further side view of the adjusting device, the side opposite the view of FIG. 11 is shown and the top of the adjusting device is at the top, FIG. 14 is a sectional view of the aforementioned adjusting device according to the section lines XIV-XIV in FIG. 13,

15 shows a sectional view of the adjustment device according to the section line XV-XV in FIG. 13, FIG. 16 shows the side view of a ski with a schematically illustrated further adjusting device, FIG. 17 shows an illustration of another modified embodiment corresponding to FIG. 16, 18 shows a further modified embodiment,

19 shows a side view of a ski with a hydraulically controlled adjusting device,

20 shows a schematic cross section of a conventional ski in a tilted position,

21 shows a corresponding cross section in a ski with equipment according to the invention and

22 shows a cross section during normal straight travel of a ski equipped according to the invention.

1 shows a pair of skis 100 in a top view, the forward direction of travel being indicated by arrow P.

Three support zones 101, 102 and 103 are provided on each ski, the support zones 101 and 103 being spaced apart from each other on the inside of the ski in the longitudinal direction of the ski, while the support zone 102 is located on the outside of the ski and is offset in relation to the two longitudinal zones 101 and 103 in the longitudinal direction of the ski .

A base plate 105, which is designed as a standing area for a ski boot 104 only shown in dashed lines in FIG. 2, may now be arranged on each ski 100, which also forms the basis for ski binding units 120 shown in dashed lines in FIG. 2, with which the ski boot when skiing of the respective base plate 105 is held.

Each base plate 105 is now on the associated ski 100 in

Area of the support zones 101 to 103 held by support elements 106 on the ski 100, so that the top of the base plate

105 a greater or lesser distance from the top of the respective ski 100. The support elements 106 are arranged relative to the base plate 105 and / or relative to the respective ski 100 with a certain mobility or flexibility, such that in the region of the support zones 101 and 103 relative movements between the base plate 5 and ski 100 in the longitudinal direction of the ski and in the region of the support zone 102 in the ski direction are possible.

2, each ski 100 according to FIG. 2 has a flat or unbent state, so that the base plate 105 according to FIGS. 1 and 3 assumes a position parallel to the plane of the underside or tread of the ski 100 when the Support elements 106, as shown, support the upper side of the base plate 5 at identical distances from the underside of the ski.

When cornering, the skier will shift his or her center of gravity more or less strongly towards the inside of the curve, with the result that the skis 100 are tilted more or less so that the respective ski axes tilt more or less markedly towards the inside of the curve. At the same time, the ski 100 will flex as shown in FIG. the longitudinal ends of the ski 100 are bent upward relative to the central region of the ski 100.

This is equivalent to the fact that the support zones 101 to 103 or the zones corresponding to these support zones 101 to 103 lie on the underside or running surface of the ski 100 on a plane curved in the longitudinal direction of the ski, ie with respect to the underside or running surface of the ski 100 na- he support zone 102 is tangentially contacting plane T, the support zone 102 is lower than the support zones 101 and 103.

The result of this is that the base plate 105, according to FIGS. 4 and 5, tilts sideways in relation to the longitudinal axis of the ski.

If the support zones 101 to 103 are arranged in a pair of skis according to FIG. 1, the result is that the vertical axis of the ski on the outside of the curve is inclined more towards the inside of the curve than the vertical axis of the base plate 105, the inclination of which is due to the sideways inclination of the skier's legs is specified. As a result, in the case of the ski on the outside of the curve, a significantly increased engagement of the inside of the longitudinal edge of the ski on the outside of the curve is achieved in comparison to the sideways inclination of the skier's respective leg, because the tilt of this ski directed towards the inside of the curve can measure the degree of inclination of the leg towards the inside of the curve of the skier.

In the example of FIGS. 1 to 5, a reduction in the tilting will occur in the ski 100 on the inside of the curve. However, this is of very minor importance, since with today's skiing technique when cornering, the ski on the outside of the curve is significantly more heavily loaded than the ski on the inside of the curve, and accordingly the cornering depends crucially on the edge engagement of the ski on the outside of the curve.

However, if a new skiing technique should be created in which cornering and the tilting of the ski on the inside of the curve were crucial, the skier in FIG. 1 would only have to swap the right and left skis 100 with one another in order to bring about an increased edge engagement of the ski on the inside of the curve.

The invention is not limited to skis 100 with a flexible central region. If a ski 100 according to FIG. 6 has a largely rigid central region and only flexible ski ends, there is the possibility of providing support elements 106 with a controllable height and, for example, the height of the support elements in the region of the support zones 101 and 103 or the height of the support element 106 in the region of the To control support zone 102 depending on the bending stroke of the front and / or rear end of the ski. Corresponding constructions are explained below. In the example in FIG. 6, the height controllability of the support elements 106 in the region of the support zones 101 and 103 is only indicated by double arrows Δh.

According to FIGS. 1 to 6, it is provided in each case to use typical bends of the ski 100 when cornering in order to control a parameter-dependent lateral inclination of the tread of the ski 100 that deviates from the sideways inclination of the respective leg of the skier.

In principle, it is also possible to use other parameters indicating cornering. For example, the lateral acceleration of the ski occurring when cornering could be registered by means of a corresponding sensor and converted into a tilting of the ski which is changed relative to the leg of the skier by means of active setting elements. To do this would have to energy storage associated with the respective control elements are carried.

Otherwise, the base plate 105 which can be separated from the ski 100 in FIGS. 1 to 6 can also be integrated into the ski 100 in such a way that the base plate 105 forms part of the upper side of the ski.

In addition, there is the possibility of an arrangement on the shoe side such that the inclination of the underside of the sole relative to the shaft of the ski shoe changes as a function of parameters typical of cornering.

In the embodiment of FIGS. 7 to 10, a stable strip 7, preferably made of metal and in particular aluminum, is fastened on the ski below the front and rear ends of the base plate 105 by means of screws 8. In the area of the support zones 101 and 103, the strip 7 is each provided with a guide 9 parallel to the longitudinal direction of the ski, which guides the head of a ball screw 10 screwed into the base plate so that it can be displaced in the longitudinal direction of the ski and holds it positively in the vertical and transverse direction. This ball head screw 10 in each case forms one of the support elements 106 of the base plate 105 on the support zones 101 and 103 (cf. also FIG. 1).

On the side of the ski 100 opposite the guide 9, a pin 11 is held in the bar 7, which protrudes upward from the bar 7 and forms a stop 12 with its free end, which approaches the neighboring one Area of the underside of the base plate 105 bounded to the top of the ski 100.

A flexible elastomer part 13 is plugged onto the free end of the pin 11 by means of a bore arranged in it. Instead of the elastomer parts 13, other spring elements, e.g. made of metal.

8, a further strip 7 is fastened on the ski 100 in the region of the support zone 102, again by means of screws 8. In the area of the support zone 102, this bar 7 has a guide 14, which runs in the cross-ski direction, for the head of a further ball head screw 10 arranged on the base plate 105, which forms the support element 106 of FIGS. 2 to 5 assigned to the support zone 102.

On the support zone 102 opposite side of the ski 100, a pin 15 is arranged in the bar on which the base plate 105 rests when it assumes its position shown in FIG. 8 without inclination in the transverse direction of the ski 100.

9 and 10 now show the function of the arrangement described with reference to FIGS. 7 and 8 when cornering, it being assumed that the curve center in the example of FIGS. 9 and 10 is in the direction of arrow Z and that in FIGS. Skis 100 shown in FIGS. 9 and 10 form the outer ski with respect to the curve being driven. Due to the bending of the ski 100 which occurs during cornering, the base plate 105 now tilts sideways relative to the ski 100, ie the base plate 105 and the ski 100 form an opening to the curve center in the sectional view of FIGS. 9 and 10 Angle. This is equivalent to the fact that the base plate 105 in FIG. 9 is inclined relative to a transverse axis of the ski 100 by the angle to the outside of the curve.

Since it must be assumed when cornering that the legs of the skier and thus the vertical axis of the base plate 105 are inclined towards the inside of the curve, the inclined position of the base plate 105 relative to the ski 100 inevitably leads to the vertical axis of that shown in FIGS 10 shown skis 100 is more inclined than the skier's legs towards the inside of the curve, with the result that the inside ski longitudinal edge 16 of the ski 100 engages the ground with extremely strong edge engagement.

In the illustrated tilting movement of the base plate 105 relative to the ski, the elastomer parts 13 are pressed down. At the same time, the base plate 105 lifts off from the pin 15.

The longitudinal and transverse guides of the ball heads of the ball head screws 10 in the longitudinal and transverse guides 9 and 14 ensure that the ski 100 can bend relatively freely relative to the base plate 105 in accordance with the respective cornering. Merely by squeezing the elastomer parts 13, a more or less large restoring force is generated between the ski 100 and the base plate 105. At the same time, the elastomer parts 13 have a damping effect on bending vibrations of the ski 100.

In addition, the maximum achievable cross slope of the base plate 105 relative to the ski 100 is limited by the pins 11 in the area of the elastomer parts 13, for example to approximately 5 °. Instead of the ball head screws 10 and the guides 9 and 14, joints, in particular plastic joints, or hinges with corresponding play can also be arranged.

11 to 15 is between skis

(not shown) and shoe (not shown) one after

Type of a spacer plate to be arranged adjusting device 20 is provided. This has a base plate 6, which serves as a base for the shoe and for the assembly of ski binding units, to which side walls 21 and 22 are bent in one piece at right angles. The side wall 21 is generally assigned to the inside of a ski, while the side wall 22 lies on the outside of the respective ski.

At the side wall 21 below the front and rear longitudinal end of the base plate 6 flat ribbon-like fastening strips 23 in one piece, which extend parallel to the base plate 6, but have a certain elastic angular mobility relative to the side wall 21, so that they can pivot relative to the base plate 6. Two elongated holes 27 are arranged in each of the fastening strips 23 and extend parallel to the longitudinal axis of the base plate 6.

Between the free ends of the fastening strips and stop flaps 25 formed on the other side wall 22, when the fastening strips 23 assume their position parallel to the base plate 6, there is a greater distance perpendicular to the plane of the base plate 6. On the other side wall 22, a fastening strip 24 is integrally formed approximately in the middle between the fastening strips 23, which is normally aligned parallel to the plane of the base plate 6. This fastening strip 24 is also designed to be flexible or flexibly connected to the side wall 22, so that the fastening strip 24 can pivot relative to the plane of the base plate 6. The free end of the fastening strip 24 lies in its position parallel to the level of the base plate 6 on a stop tab 26 formed on the side wall 21 from below. Otherwise, two round holes 28 are formed in the fastening strip 24.

The adjusting device 20 is fastened to the top of a ski (not shown) by means of screws, not shown, which can be inserted into the elongated holes 27 and the round holes 28 of the fastening strips 23 and 24 through corresponding cutouts 29 in the base plate 6, the fastening strips 23 being due to the elongated holes 27 remain displaceable relative to the ski in the longitudinal direction of the ski. When the adjusting device 20 is mounted on the ski, the connection areas between the fastening strips 23 and the side wall 21 form corresponding supports for the support elements 106 (see FIG. 3) on the support zones 101 and 103 (see FIG. 1), while the connection area between the side wall 22 and the fastening strip 24 corresponds to the support element 106 on the support zone 102.

If the ski now bends when cornering, the base plate 6 is inclined sideways relative to the ski analogously to the base plate 105 in FIG. 5. This sideways inclination is limited by the above-mentioned distance between the stop tabs 25 and the free ends of the fastening strips 23, for example to approximately 5 °.

When the base plate 6 is tilted relative to the ski, the fastening strips 23 and 24 are pivoted relative to the side wall 21 and 22 connected to them, respectively, by bending the respective transition regions. Accordingly, these transition areas must be designed to be able to withstand bending loads or consist of correspondingly resilient material, the entire adjusting device 20 described being able to be produced from such material. Suitable materials are, for example, aluminum sheet or plastics. In principle, however, other spring materials are also suitable.

The space formed between the top of the ski and the base plate 6 can be made of flexible foam material or foam rubber or the like. completed or completed externally.

In the embodiments of FIGS. 7 to 15, the deflection of the ski in the longitudinal central region when cornering is used for parameter-dependent control of the cross slope of the base plate 6 relative to the ski.

16 to 19 now show a schematic representation

Embodiments in which this parameter-dependent control of the cross slope is also possible if the longitudinal central region of the ski is designed to be comparatively rigid is and only the longitudinal ends of the ski are elastically bendable relative to the central region.

In the embodiment shown in FIG. 16, the base plate 105 is held in the region of the support zone 102 (cf. FIG. 1) by means of the support element 106 arranged there at a predetermined distance from the top of the ski, but in such a way that the base plate 105 is relatively can pivot to the ski 100 about a longitudinal axis of the ski.

Support elements with controllable height are provided on the support zones 101 and 103, which in the example of FIG. 16 each consist of a wedge element 108 fastened to the base plate 106 and a counter wedge element 109 which can be displaced in the longitudinal direction of the ski. The counter wedge elements 109 are each connected via a rod 110 to an abutment 111 arranged on the top of the front end or the rear end of the ski 100, so that the counter wedge elements 109 inevitably in the longitudinal direction of the ski with a change in the height of the respective wedge element 108 and the respective Ge - Genkeilelement 109 formed support elements are moved in the longitudinal direction of the ski when the front and rear ski ends are bent relative to the longitudinal central region of the ski 100.

In the example of FIG. 16, the mutually cooperating inclined surfaces of the wedge elements 108 and counter-wedge elements 109 are each inclined such that the height of the supports formed by the elements 108 and 109 is increased when the ski ends are bent in an upward direction relative to the ski center region. In principle, however, an opposite inclination of the aforementioned inclined surfaces is also conceivable. However, the right and left skis must then be interchanged in FIG. 1 if it is to be ensured that there is an increased tilt of the outer ski when cornering.

The embodiment of FIG. 17 differs from the embodiment of FIG. 16 essentially only in that the rods 110 each connect to the knee joints of toggle lever arrangements 112, through the base plate 105 to the support zones 101 and 103 (cf. FIG. 1) is supported and held against the ski 100. If the toggle lever arrangements 112 assume the positions shown in FIG. 17 during normal straight-ahead driving on a flat slope, the vertical height of the toggle lever arrangements 112 relative to the top of the ski is increased when the ski ends are bent upward relative to the longitudinal central region of the ski 100.

If, on the other hand, the toggle lever arrangements 112 would normally assume their stretched state or the position indicated by dashed lines in FIG. 17, the vertical height of the toggle lever arrangements would decrease with the aforementioned upward bending of the ski ends.

In the embodiment shown in FIG. 18, the end of each rod 110 facing away from the abutment 111 is in each case provided with a sliding block 113 or the like. connected, which on the one hand in a longitudinal slot 114 of a ski-side support part 115 extending in the longitudinal direction of the ski and on the other hand in one oblique link slot 116 of a fixed to the base plate 105 support member 117 is guided. The slotted slots 116 are each inclined such that when the ski ends move upwards relative to the longitudinal central region of the ski 100, the vertical height of the supports formed by the support parts 115 and 117 increases. Such an increase in height also occurs when the oblique link slot 116 is formed in the ski-side support part 115 and the ski-parallel link slot 114 in the support part 117 of the base plate 105.

With opposite inclinations of the oblique link slots 116, the vertical height of the aforementioned supports is reduced when the ski ends bend upwards.

FIG. 19 shows an embodiment in which the base plate 105 is supported on the support zones 101 and 103 (cf. FIG. 1) by piston-cylinder units 118, which are each hydraulically connected to a piston-cylinder unit 119 whose piston is actuated by one of the rods 110. When the ski ends bend upwards relative to the longitudinal central region of the ski 110, the piston-cylinder units 118 are then inevitably expanded, so that the cross slope of the base plate 105 relative to the ski 100 is changed accordingly.

In the embodiments shown in FIGS. 16 to 19, the vertical height of the supports in the region of the support zones 101 and 103 (see FIG. 1) is changed. In principle, it is also possible to adjust the vertical height of this To keep supports constant and to change the vertical height of the support in the region of the support zone 102. For this purpose, the constructions for height-adjustable supports shown schematically above with reference to FIGS. 16 to 19 can be used analogously. With such an arrangement, only a single bar 110 needs to be placed on the front or rear end of the ski 100 since only the vertical height of a single support needs to be changed.

For the rest, the variants shown in FIGS. 16 to 19 can be modified by omitting the height-unchangeable support of the base plate 105 in the region of the support zone 102 (cf. FIG. 1) and replacing it with two height-changeable supports which are on the the longitudinal side of the ski 100 opposite the support zones 101 and 103 can be arranged as largely as possible, in particular in each case approximately opposite the support zones 101 and 103.

In the above explanations, it was assumed that bending of the ski or bending of the ski ends lead to a change in the sideways inclination of the base plate 105 or the base plate 6 relative to the ski 100. In principle, however, it is also possible to mount the ski 100 and / or the supports of the base plate 6 or the base plate 105 on the ski 100 and / or elements which, like the abutment 111 and the rods 110, control the transverse inclination of the base plate 6 or the base plate 105 serve to be designed to be resilient in such a way that there is no significant change in the transverse inclination of the base plate 6 or base plate 105 relative to the base plate 105 Ski 100 occurs, however, a longitudinal ski edge increases

Receives ground pressure.

20 and 21 illustrate the effect of the invention:

If, in a conventional ski 100 according to FIG. 20, the footprint 200 for the ski shoe (or its sole plane) is e.g. Is tilted 40 ° in the transverse direction, the ski is tilted by the same angle of 40 °.

With the arrangement according to the invention, on the other hand, with at least one ski 100, in particular the ski on the outside of the curve, it can be achieved that the ski 100 has a higher tilt than e.g. tilting (40 °) of the contact surface 200 (or sole plane), e.g. 45 ° receives. As a result, the shaft of the ski boot has a sideways inclination, as illustrated by line 300, which is less than the sideways inclination assumed by the vertical axis 400 of the ski 100.

During normal straight-ahead driving, the line 300 and the vertical axis 400 can coincide, cf. Fig. 22.

Claims

claims

1. Device for adjusting an angle in the sideways direction between the ski boot or leg of the skier and the tread of an associated ski, characterized in that an adjusting device that works in dependence on parameters correlated with cornering, a parameter-dependent pivoting of the ski boot or the shoe upper causes relative to the tread of the ski (100) about a longitudinal axis of the ski and / or a parameter-dependent actuating force that tries to pivot the boot or its shaft in a sideways direction relative to the tread of the ski, such that at least one predetermined ski when cornering compared to Is sideways inclination of the shoe or leg increased tilt and / or increased edge pressure.

2. Device according to claim 1, characterized in that a deflection of the respective ski which occurs when cornering - at least when the skier or his legs is inclined towards the inside of the curve - controls a sideways tilting of the ski shoe or its shaft relative to the associated ski via the adjusting device, such that the vertical axis of the tread of the given ski, in particular of the ski on the outside of the curve, is more inclined towards the inside of the curve than the vertical axis of the associated ski boot or its shaft.

3. Device according to claim 1 or 2, characterized in that the adjusting device (105, 106; 6, 10, 9, 14; 105, 108 to 119) is arranged on the ski.

4. Device according to claim 3, characterized in that the adjusting device between the ski and ski boot or ski binding is arranged.

5. Device according to one of claims 1 to 4, characterized in that a base or base plate (6, 105) is provided on the ski, which on one longitudinal side of the ski (100) on two support zones (101, 103) spaced apart in the longitudinal direction of the ski. and on the other longitudinal side of the ski at a further support zone (102) offset from the two aforementioned support zones in the longitudinal direction of the ski, so that deflections of the ski in the region of the support zones (101, 102, 103) lead to a cross slope or to a change in the cross slope of the base plate relative to Skiing.

6. Device according to one of claims 1 to 5, characterized in that a stand or base plate (6, 105) is arranged on the ski (100), which is held vertically substantially firmly on one long side of the ski and on the other long side of the ski is supported with vertical height adjustability, the height setting being predetermined by parameters correlated with cornering.

7. Device according to claim 6, characterized in that the height adjustment depending on deflections of the ski (100) or parts of the ski (front end of the ski, rear end of the ski) is controllable.

8. Device according to one of claims 1 to 7, characterized in that between the base or base plate (6, 105) and the ski (100) or parts of the ski spring elements (13) are arranged which the base or base plate in one Push normal position relative to the ski.

9. Device according to one of claims 1 to 8, characterized in that the parameter-dependent pivoting of the ski boot or the shoe upper relative to the tread of the ski (100) is in a range between about 0 ° and 10 °.

10. Device according to claim 9, characterized in that the maximum pivoting is limited to approximately 5 °.