DE3726904A1 - Boot, in particular ski boot - Google Patents

Abstract

A spring arrangement (1) for shell parts (7, 13) of a shoe, which are movable in an articulated manner in relation to one another in the forward lean direction, has, completely surrounded in a housing (20), two groups of compression springs made of a closed-cell polyurethane elastomer (PUR) which have a very progressive spring characteristic line by virtue of the fact that only one group of springs is effective on a first part path and a second group can be connected on a second part path. The path-dependent response of both groups of springs can be adjusted separately and moreover all springs are designed as damped springs as a result of their material properties. As a result, an adjustable forward-lean springing, the hardness of which can be varied in a path-dependent manner, is possible for the boot shaft (5). <IMAGE>

Description

The invention relates to a boot, in particular one Ski boots, with a boot coat that is at least two against the force of a spring arrangement Spring device from a starting position to an end position shell parts that can be moved in a joint-like manner, for example has an instep part and a shaft part, each of the two shell parts for the spring arrangement a spring abutment is assigned and this spring abutment via a spring travel in a deflection and a reset direction can be moved against each other.

For special footwear, especially for boots Footwear for sporting purposes occasionally exists Need to counteract individual areas of footwear in this way to provide each other with mobility, that despite boot-like ge  secure mounting of the foot and its associated mobility due to the limited mobility of the shoe parts is preserved over a predetermined path. With the In this way, spring device becomes mutual Movement of the two shell parts an increasing resistance opposite to associated by soft cushioning of the To avoid foot section overloads that are too severe Injuries such as broken bones can result. In the event of a ski boot, for example, is conveniently the Shank and heel and calf area comprehensive shaft embrace the upper part from the initial position opposite the foot the, designed as a relatively rigid shell and the Sole of the lower part of the shaft can be swiveled forward stored, between these shaft parts on the Back of the shoe, on the side of the shoe or in front of the upper Part of the spring lying on the top of the lower part of the shaft device attacks. Inside the through the moveable Shaft parts formed outer entire shoe shell can be a soft, padded liner. The be Written mobility of the shoe is used in this case especially maintaining the jump flexion joint of the foot, as in Alpine skiing to take a suitable presentation of the skier is required is.

DE-PS 21 28 769, for example, is a ski boot became known in which a front shell and a rear closure that can be opened to enter the boot shell together against the lower part of the shaft against the Force can be pivoted by a helical compression spring, the one has essentially linear rising spring characteristic. This is the loose mobility of the foot or Ankle in the first part of the travel due to too high Limited spring forces and in the end of the travel  these spring forces are so low that a limitation of the Path is done by stop, resulting in an abrupt, dangerous load on the foot. Similar relationship nisse also arise in other known training courses according to EP-A-1 72 156.

With the forward movement of the upper part of the shaft, one can lateral movement can be combined. This is e.g. after EP-A-1 17 430 through the arrangement of two different hard, springs lying next to each other are reached, but just if there are linearly increasing spring characteristics. As End stops can be pre-buffered in this training be seen, but which has practically no influence on the have abrupt, dangerous peak loads on the foot, but are at most suitable for damage to avoid the shoe.

Even with the boot according to EP-A-0 73 433 there are two screws compression springs provided on the back of the boot, see above that the disadvantages mentioned also arise here. Are, as in EP-A-2 17 423 instead of helical compression springs Spring elements made of rubber or the like. provided so result spring that rises essentially in a straight line characteristics, which is why an adjustable for the path limitation Stop is provided.

The invention has for its object a boot or to create a shoe of the type mentioned, which in a can be trained in such a way that the against each other the moving shell parts towards the end of the travel limited freedom of movement in their mutual mobility can still be in a first part of the spring only a relatively low resistance to movement are thrown.  

This task is described with a boot of the beginning benen type according to the invention solved in that the spring arrangement in the direction of deflection essentially over the entire th travel has a progressive spring characteristic and that the shaft parts for movement a damping device assigned. The spring characteristic is in the fiction moderate training in the first part of the travel essential flatter than in the last part, so that towards the end of the spring a noticeable steep, but continuous or steady increase in resistance to movement takes place through the in contrast to a, possibly also buffered, stroke limit a much gentler load on the foot is guaranteed. Already through the damping device, the according to the invention also for himself when providing a different than the characteristic curve described, namely at approximately rectilinear spring characteristic can be used a much gentler load on the foot, because the restoring forces of the spring device are lower than that Resistance to the deflection forces are and because alternating damping between deflection and reset movements can be done.

Instead of the training described or in addition to this a particularly advantageous result according to the invention Design of a boot of the above or a similar kind in that at least one spring is provided, the chambers, in particular a variety smallest chambers of less than a millimeter Wide with a compressible gas filling, which with a very compact space-saving training a very good constant spring curve and at the same time without the need a separate damping device an advantageous damper fung can be achieved. The spring preferably consists of based on a cellular polyurethane elastomer (PUR)  a polyester alcohol and naphthylene diisocyanate (NDI), the has a very advantageous volume compressibility. This spring material can be due to its cell structure compress until all cells have practically disappeared and a homogeneous elastic structure is achieved, whereby this spring material in one of dimensionally stable walls completely enclosed spring receiving space can be, since it is only relative to a pressure load small cross-sectional expansion tends. Such a feather material, such as that under the trademark Cellasto is known to have high tensile strength and elongation at break also have excellent notch toughness, high abrasion resistance, good resistance to oil, grease, Gasoline, ozone and aging and most of all it has volume compressibility, high shock elasticity and resilience force. Furthermore, the cell walls of such a material tend not for gluing, also after a long comm full resilience occurs, i.e. that the material only has an extremely low pressure has residual formation. According to the spring arrangement tion designed so that the spring characteristic essentially is independent of temperature, so that with temperature changes there is no need to readjust the spring characteristic; this property is also due to the material mentioned guaranteed.

It is conceivable to spring from a semi-finished product, namely for example by cutting out of a block or by To produce separation from a strand, whereby in in this case, open cells appear on the cut surfaces. If the ingress of moisture or Water is not fully reached through housing protection should be closed by suitable sealing. However, these effects can be done in a particularly simple manner  can be achieved if the spring as a molded part in the manner of a Integral foam material is manufactured such that at least their peripheral surfaces and in particular one or both End faces through the cell-free compressed outer skin of the Molding is sealed closed.

An approximately continuously progressive spring characteristic can, if necessary also without damping device, of the wide ren can be achieved according to the invention in that the Travel successively connected springs provided are the one after the other conveniently from a bias free state take effect, so that very soft Result in transitions. The spring characteristics of each, according to mutually effective springs can be the same or be different in particular in such a way that the in Steering direction each subsequently effective spring spring characteristic curve rising more steeply than that previously has effective spring.

It is conceivable to have the spring or springs between two Arrange spring abutments that are fixed in the direction of deflection standing on one side and on the other side Shell part are held so that always with respect to the Deflection path the same spring forces are effective. After one another proposal according to the invention are these spring forces However, te adjustable, for which purpose at least one Spring abutments in the direction of deflection and return arranged adjustable relative to the associated shell part is. An even better setting option arises if the spring abutment for the successively effective springs can be adjusted independently can, because then that point of the deflection path changes on which the following will become effective Spring is switched on. In this respect, the first part of the  Deflection path independent with regard to its spring characteristic adjusted from the last or second part of this deflection path bar.

The or the spring bearing or the like via notches. in two or more positions can be adjusted gradually, however there are particularly fine adjustment options if for this threaded or adjusting spindle for stepless adjustment tion are provided instead of side by side or each other conveniently arranged opposite one another coaxially are so that all spring abutments from the same side can attack the feathers.

So that the spring or springs against dirt, moisture and damage are housed as protected as possible can, they are expedient in a substantially full constantly closed housing arranged by a bellows-like housing be formed or telescopic ver can slidably engage in a bearing housing, which it closes its open end and, if necessary, the adjustable bears spring abutment.

These and other features of preferred further developments of the inventions go not only from the claims but also from the Description and drawings, the individual Characteristics each individually or in groups in the form of sub-combinations in one embodiment of the invention development and in other areas represent both executable and protectable versions for which protection is claimed here.

Execution examples of the invention are shown in the drawings and are explained in more detail below. There are shown in Fig. 1, an inventive boots in Perspecti vischer view,

Fig. 2, the spring means of the boot of FIG. 1 in the approximately horizontal longitudinal section;

Fig. 3 is a substantially vertical longitudinal section through the spring device according to Fig. 2,

Fig. 4, the spring housing of the spring assembly shown in FIGS. 2 and 3 in a perspective view;

Fig. 5, the spring housing in Fig. 3 in view from the left,

Fig. 6 is a section along the line VI / VI in Fig. 3 only by the bearing housing,

Fig. 7 is a section along the line VII / VII housing in Fig. 3, also merely by Lagerge,

Fig. 8 of the adjustable spring abutment in view,

Fig. 9 shows another embodiment of a Stie rock in side view

Fig. 10 is a detail of FIG. 9 in an enlarged and partially cut representation.

As shown in FIG. 1, a shoe spring device 1 according to the invention is provided, for example, for a boot 2 to be used as a skiing shoe, which has a sole 3 designed for rigid positioning in a ski binding on the underside of a foot shell 4 comprising one foot and one from the foot shell 4 upwards, as well as expediently upwards increasingly less stiff shaft 5 with an inner height of about 20 to 30 cm in such a way that this shaft 5 protrudes above the sole of the foot of the ankle upwards at least about this. Instead of a one-piece design, the shaft 5 in the illustrated embodiment consists of a rear and a front shell part, which was in use to be secured against each other by a clasp 8 so that they are almost immovably connected. The rear shell part forms the entry in the boot 2 is a an immediately above the sole 3 lying joint 9 fold-down back approximately half-shell-shaped heel flap 6, which up to the level of the upper end of the shaft 5 or of the front shell portion 7 and down about extends to heel height, but the heel area of the foot is directly supported in the foot shell 4 at a certain height. The front shaft-shell part 7 is also designed approximately as a half-shell and can be pivoted forward from the upright starting position by at least approximately 45 ° with respect to the foot shell 4 with a joint 10 lying directly above the sole 3 . A lower front tongue of the front shell part 7 engages over the top of the foot shell 4 in any position.

The joints 9 , 10 can lie in a common joint axis or on both sides of the boot 2 are each formed by joint joints, but according to FIG. 1 are arranged one behind the other in the longitudinal direction of the shoe that they are at approximately the same height. The hinge axis 11 of the joints 9 lies behind the hinge axis 12 of the joints 10 and, like this, parallel to the standing plane of the boot 2 and approximately at right angles to its longitudinal direction. Due to the ne training described, the two shell parts of the shaft 5 perform slight relative movements during pivoting movements, the heel flap 6 movably engaging with its lateral legs between the legs of the front shell part 7 . The shell parts of the shaft 5 have bearing cheeks around the side of the foot shell 4 for receiving the joints 9 , 10 .

The top of the foot shell forms a substantially rigid position with respect to the sole 3 and integrally formed with the foot shell 4 instep shell part 13 , which is spaced behind the toe or in the shaft area in the manner described in front of the front shell part 7 or from between the bearing cheek protruding tongue is overlapped. The elongate flat spring device 1 is supported on this tongue with one end in a joint 14 . The other end of the spring device 1 is mounted in a joint 15 on a bearing projection, which is provided on the top of the instep shell part 13 immediately after the tip of the foot shell 4 . The mutually parallel hinge axes 16 , 17 are also parallel to the standing plane of the boot 2 and perpendicular to the longitudinal direction of the boot and thus parallel to the hinge axes 11 , 12 , but higher than this, the front hinge axis 17 corresponding to the inclination of the top of the Instep shell part 13 is lower than the hinge axis 16 that the common axial plane of these two hinge axes 16 , 17 is approximately parallel to this upper side.

The spring device 1 has at the end associated with the shell part 7 a surface lying at a distance between its sides, protruding in the longitudinal direction, which engages like a comb in the tongue of the shell part 7 and is penetrated by a hinge pin. The other end of the spring device 1 forms with two in the longitudinal direction projecting lateral bearing lugs a Lagerga bel, which engages around the bearing projection on both sides and is also penetrated by a hinge pin, the top of the substantially spherical rounded bearing projection essentially continuously or flush in the top of the associated end of the spring device 1 merges, as does the top or front of the tongue of the shell part 7 , essentially continuously or flush into the top of the other end of the spring device 1 and the width of the spring device 1 at this end for one flush lateral transition is substantially the same as the associated width of the tongue of the shell part 7 ; insofar as the thickness of the spring device 1 approximately equal to the thickness of the tongue of the shell part 7 and equal to the height of the front bearing projection, such that the underside of the spring device 1 in the starting position over its entire length was at most with a small gap above the top of the instep -Shell part 13 lies. The spring device 1 is linearly resiliently resilient in the direction of arrow 19 in such a way that it can adapt in length when pivoting the shaft 5 back and forth, the joint axis 16 in the starting position and in a side view in the direction of the toe in front of the joint axis 12 or the hinge axis 11 .

As shown in FIGS. 1 to 8 further show the Außenbegren are tongues of the spring means 1 substantially by an almost completely closed housing 20 is formed to share the sliding of two telescoping housing, namely a rear, further bearing housing 21 and a front spring housing 22 is , whose flat oval outer cross sections are adapted to the inner cross sections of the associated thin-walled end of the bearing housing 21 . The flat sides of the housing 20 are approximately parallel to the upper side of the instep part 13 . The rear hinge part of the spring device 1 is in one piece with the bearing housing 21 and the front hinge part forms in one piece with the spring housing 22 .

The almost constant internal and external cross sections over its length, in particular as plastic injection molded spring housing 22 takes a shorter than its inner length spring assembly 23 fully sunk, the spring assembly 23 from two groups of springs, namely two longer and the same length with each other Springs 24 of a first group and a single gene, in the relaxed state about half as long spring 25 of a second group. At the end 15 of the joint, the spring housing 22 is completely and permanently closed with an inserted or in one piece with its jacket formed base plate, which may have the through opening for the associated hinge pin approximately in its central plane and which forms a spring abutment 26 which is fixed in position relative to the spring housing 22 . For this purpose, the inner surface of the spring abutment 26 is hen hen for all springs 24 , 25 lying in a common plane pressure bearing surface, on which the springs 24 , 25 abut directly adjacent to one another with their associated end faces.

The opposite end faces of the springs 24 , 25, which are offset in the spring longitudinal or movement direction arrow 19 and are also at right angles to this direction arrow 19 and are essentially flat, are assigned two separate spring abutments 27 , 28 located within the spring housing 22 in each position However, the position of the spring housing 22 with the bearing housing 21 in the direction of arrow 19 and of which the spring abutment bearing 27 and / or the spring abutment 28 with an adjusting device 29 can be adjusted approximately in the direction of movement arrow 19 relative to the bearing housing 21 and can be fixed in a self-locking manner . The arrangement is such that a first spring abutment 27 is provided for the springs 24 of the first group and a second spring abutment 28 for the spring 25 of the second group and the respective spring abutment 27 , 28 can be adjusted in an initial position of the spring abutment 26 , in which this spring abutment 27 or 28 does not bear against the associated spring or springs, or is essentially free of prestress. The plate-shaped Federvorsla ger 27 may have an approximately the inner contour of the spring housing 22 corresponding outer contour and thereby be securely guided on the inner surface of the spring housing 22 . The constantly lying between the springs 24 , also plate-shaped spring abutment expediently has an adapted to the inner contour of the associated central region of the Federge housing 2 outer contour such that it is slidably guided at least on two opposite, the flat sides associated inner surfaces of the spring housing 22 , the spring abutment 28 is non-contact with the springs 24 .

The or all of the springs 24 , 25 have the same cross sections and are expediently formed by cylindrical rod-shaped parts made of an essentially closed-cell elastomer, in particular an integral foam. In adaptation to this cross-sectional shape, the inner contour of the spring housing 22 is essentially formed by one of the number of springs 24 , 25 corresponding number of parallel, bore-like recesses, the central axes of which lie in a common axial plane 31 parallel to the flat sides of the housing 20 , however have a distance from one another which is so small in relation to their cross-sectional width that adjacent bore-like recesses are not separated from one another by intermediate walls, but instead openly connect to one another in accordance with FIG. 5 in cross-section over an arc angle of more than 45 °. As a result, intermediate webs for engagement between adjacent springs 24 , 25 are formed on two mutually opposite inner sides of the spring housing 22 , which are associated with the flat sides, at a distance from one another in such a way that a type of glasses cross section results. The width of the bore-like recesses conditions is slightly larger than the outer width of the relaxed springs 24 , 25 , so that they can expand in compression at least on a first part of the spring travel in cross section and at most on a last part of the spring travel with their peripheral surfaces under pressure on the Inner surfaces of the spring housing 22 abut, the arrangement may be so ge that adjacent springs are also supported with their opposite circumferential zones also directly against each other. The or all of the springs 24 , 25 are thus arranged in a closed space 32 for the compression load.

The spring assembly 23 also forms a Dämpfeinrich device 30 , since the springs 24 , 25 are designed so that they have a damping effect in addition to the spring action.

In the starting position, the spring abutment 28 is at a greater distance from the associated spring 25 lying in the middle between the springs 24 than the spring abutment 27 from its associated springs 24 , to which it can, however, bear essentially without preload in this starting position. The spring abutment 28 is therefore lower in the spring housing 22 than the spring abutment 27 in each position. To adjust the spring abutment 27 , the actuating device 29 has a hollow adjusting spindle 33 with a Außenge thread which engages in an internal thread of the spring abutment 27 , the adjusting spindle 33 being symmetrical with springs 24 , 25 , namely in the central axis of the spring 25 . The spring abutment 28 is also adjustable with an adjusting spindle 34 , which passes through the adjusting spindle 33 coaxially and carries the spring abutment 28 rigidly attached to its end projecting from the adjusting spindle 33 in the spring housing 22 . The adjusting spindles 33 , 34 pass through the corresponding end of the spring housing 22 so as to be displaceable on the mantle-shaped part of the bearing housing 21 , the adjusting spindle 33 being rotatable but axially secured and the adjusting spindle 34 being axially but secured against rotation on the bearing housing 21 .

To adjust the adjusting spindles 33 , 34 are two handles 35 , 36 in the manner of rollers profiled on the periphery vorgese hen, which are arranged axially adjacent to each other in such a manner in the cutouts of the bearing housing 21 that they have at least part of their circumference on the upper side of the bearing housing 21 protrude, which can have a smaller thickness in this area than in the displacement area for the spring housing 22 . The handle 35 rigidly connected to the adjusting spindle 33 is offset relative to the other handle 36 in the direction of the spring housing 22 . The handle 36 is engaged via an internal thread with an outer thread of the adjusting spindle 34 , which at its end facing away from the spring abutment 28 , lying adjacent to the handle 36 , can have an anti-rotation element 37 for guiding in a corresponding recess in the bearing housing 21 . The displacement of the spring housing 22 relative to the bearing housing 21 is greater than the maximum associated deflection of the shaft 5 relative to the foot shell 4 , so that the spring housing 22 can never get to a stop position, but only the spring arrangement 23 is effective to limit the spring travel is. By adjusting the Federvorsla gers 27 is essentially set the angle, while the spring abutment 28 is essentially the hardness of the suspension on the last part of the deflection or spring path to adjust. The adjustment is expediently made so that with a medium setting and with a deflection of the shaft 5 by about 40 ° a resistance torque of about 200 Nm is achieved, while this section modulus at a deflection angle of 30 ° is already below 100 Nm and at a deflection angle of 20 is less than 50 Nm. This can reliably prevent the ankle of the foot from being angled to its end position, the mobility of the ankle being essentially restricted to the forward movement. By changing the axial distance of the spring abutment 28 with respect to the spring 25 can be determined after how long this spring 25 is switched on. In order to shorten the distance between the ends of the housing parts facing away from one another, the adjusting spindle 33 is actuated, thereby screwing it into the spring abutment 27 , while this spring abutment maintains its starting position with respect to the springs 24 , so that the angular position of the shaft 5 is changed. At the same time, however, the spring abutment 28 approaches the spring 25 , so that a steeper spring characteristic curve is also set by setting a larger feed angle. It is also conceivable to close the end of the spring housing 22 associated with the bearing housing 21 with an end wall and to provide a central bore in this end wall for the passage of the adjusting spindles 33 , 34 . As a result, the interior of the housing 20 is not only better protected against contamination by the telescopic bearing and the spring abutment 27 .

In FIGS. 9 and 10, the same reference numerals are used for corresponding parts in the other figures, but in FIG. 9 with the index "a" and in FIG. 10 with the index "b" .

The spring means 1 a of FIG. 9, as in particular one-piece housing in substantially only the spring housing 22 a, whereby the handle is a free between this housing and the joint 14 a located 35. The inner joint part of this joint 14 a can be formed directly by the, for example, spherical or partially spherical handle 36 a , which lies in a corresponding joint shell of a bearing body 21 a fastened to the front shaft part 10 a .

In the embodiment of Fig. 10 in contrast, both handles 35 form b, 36 b of the inner, approximately kugelförmi gen joint part of the joint 14 b, the two handles 35 b, 36 b are each approximately hemispherical shaped.

Claims (20)

1. Boots, in particular ski boots, with a Stiefelman tel, the at least two against the force of a, a spring arrangement ( 23 ) having spring means ( 1 ) from a starting position to an end position against each other articulated shell parts ( 7 , 13 ), for example a shaft - Shell part ( 7 ) and an instep shell part ( 13 ), each of the two shell parts ( 7 , 13 ) being assigned a spring abutment ( 27 , 28 ; 26 ) for the spring arrangement ( 23 ) and these spring abutments ( 27 , 28 ; 26 ) can be moved relative to one another via a spring travel in a deflection and a return direction (arrow 19), characterized in that the spring arrangement ( 23 ) has a progressive spring characteristic over the entire spring travel in the deflection direction and that the shell parts ( 7 , 13 ) for the movement a damping device ( 30 ) is assigned. 2. Boot according to claim 1, characterized in that successively connected springs ( 24 , 25 ) are provided over the spring travel, preferably at least two groups of springs ( 24 or 25 ) are provided and each group has one or more springs ( 24 , 25 ). 3. Boots according to claim 1 or 2, characterized in that the spring characteristic increases substantially continuously progressively and that preferably at least one spring ( 24 ) at the beginning of the spring travel or when connected at the beginning of the associated partial travel is free of tension. 4. Boot according to one of the preceding claims, characterized in that at least one spring ( 24 , 25 ) of the spring arrangement ( 23 ) is formed as a compression spring from a pressure-elastic material and is preferably rod-shaped, with in particular all springs having essentially the same cross-sections. 5. Boot according to one of the preceding claims, characterized in that at least two, in particular all springs ( 24 , 25 ) of the spring arrangement ( 23 ) are immediately adjacent to one another, preferably essentially in a common axial plane ( 31 ). 6. Boot according to one of the preceding claims, characterized in that at least one spring ( 24 , 25 ), in particular all springs are arranged in a substantially closed space ( 32 ), which is preferably substantially close to the outer contour of the associated relaxed Adapted spring ( 24 , 25 ) and in particular in the case of adjacent springs ( 24 , 25 ) in the region of their mutually facing sides is mutually un indirectly limited by these springs ( 25 , 24 ). 7. Boot according to one of the preceding claims, characterized in that the spring characteristic of a second group to be connected from at least one spring ( 25 ) rises steeper than that of a first group of springs ( 24 ), preferably a spring ( 25 ) of the second Group is shorter than at least one spring ( 24 ) of the first group and lies in particular between two springs ( 24 ) of the first group of the same length. 8. Boot according to one of the preceding claims, characterized in that the damping device ( 30 ) associated with the spring arrangement ( 23 ), preferably formed by this, in particular substantially all springs ( 24 , 25 ) of the spring arrangement ( 23 ) as damped Springs are formed. 9. Boots, in particular according to one of the preceding claims, characterized in that at least one between hinged shell parts ( 7 , 13 ) of the boot ( 2 ) effective spring ( 24 , 25 ) of the Federein direction ( 1 ), in particular all springs of the spring arrangement Have ( 23 ) chambers with a compressible gas filling, are preferably formed by an essentially cellular plastic. 10. Boot according to one of the preceding claims, characterized in that at least one spring ( 24 , 25 ), in particular all springs of the spring arrangement ( 23 ) are formed by an essentially closed-cell elastomer, in particular by a molded part made of an integral foam plastic. 11. Boot according to one of the preceding claims, characterized in that at least one spring ( 24 , 25 ), in particular all springs of the spring arrangement ( 23 ) are substantially cylindrical and preferably provided on the circumference and / or on the end faces with a liquid-tight closed surface are. 12. Boot according to one of the preceding claims, characterized in that at least one spring abutment ( 27 , 28 ) is adjustable in the direction of the spring travel, wherein separate spring abutments ( 27 or 28 ) are preferably provided for separate groups of springs ( 24 or 25 ) are, which are arranged separately against each other and with respect to the associated springs ( 24 , 25 ) adjustable. 13. Boot according to one of the preceding claims, characterized in that at least one spring abutment ( 27 , 28 ) via an adjusting spindle ( 33 , 34 ) is adjustable and that preferably the adjusting spindles ( 33 , 34 ) separate first and second spring abutments ( 27 , 28th ) directly adjacent to each other, especially coaxially. 14. Boot according to claim 13, characterized in that a second adjusting spindle ( 34 ) for a central, in particular special to be switched second group of at least one spring ( 25 ) within the other, first adjusting spindle ( 33 ) and that preferably the first Spring abutment ( 27 ) relative to the first adjusting spindle ( 33 ) and the second, rigidly connected to the second spring abutment ger ( 28 ) connected adjusting spindle ( 34 ) is adjustable relative to an associated actuating handle ( 36 ). 15. Boot according to one of the preceding claims, characterized in that tool-free actuation actuation handle ( 35 , 36 ) for the spring abutment ( 27 , 28 ) immediately adjacent to one another, in particular approximately parallel to the spring travel one behind the other and preferably substantially the same are trained. 16. Boot according to one of the preceding claims, characterized in that at least one spring ( 24 , 25 ), in particular all springs are arranged in a spring housing ( 22 ) consisting of at least one housing part, which in particular with a closed bottom wall is fixed relative to it Forms spring abutment ( 26 ) and is essentially closed on the opposite side of the housing by at least one spring abutment ( 27 , 28 ) that is movable relative to the spring housing ( 22 ). 17. Boot according to one of the preceding claims, characterized in that at least one relative to at least one spring ( 24 , 25 ) of the spring arrangement ( 23 ) movable spring abutment ( 27 , 28 ) is arranged on a bearing housing ( 21 ) consisting of at least one housing part and that preferably the bearing housing ( 21 ) and the spring housing ( 22 ) telescopically slide into one another, in particular the spring housing ( 22 ) being encompassed by the bearing housing ( 21 ). 18. Boots according to claim 17, characterized in that the bearing housing ( 21 ) adjacent to a displacement area for the spring housing ( 22 ) has at least one actuation handle ( 35 , 36 ) for the respective spring abutment ( 27 , 28 ) and that the handle ( 35 , 36 ) is preferably inserted in the manner of a turntable in a section of the bearing housing ( 21 ) and with part of its circumference is above the top thereof. 19. Boot according to one of the preceding claims, characterized in that the spring device ( 1 ) via Ge joints ( 14 , 15 ) with the two associated shell parts ( 7 , 13 ) is connected and preferably as a flat body approximately over its entire length immediately adjacent to Outside surface of at least one of the two shell parts ( 13 ). 20. Boot according to one of the preceding claims, characterized in that an automatic setting of a steeper spring characteristic is provided with a setting of a larger angle of inclination, wherein preferably the second spring abutment ( 28 ) at Ver position of the first spring abutment ( 27 ) relative to the associated Spring ( 25 ) is taken.