DE2730550A1 - Ski boot of rubber or plastics - has shaft strips of varying elasticity giving progressive increase of resistance under forward pressure of lower leg - Google Patents

Abstract

The outer part of the shoe shaft is made of one piece in synthetic or rubber (24, 25). The lower leg is supported on its sides in direction of the toe point by a progressively increasing resistance as the leg leans forward from the knee down at an increasing angle. The shaft (24) and sole have a minimum of three different elasticities in differing shaft-parts lying along side each other (35). At least one of them has side structure which is elastically adaptable and corrugated, especially at the level of the ankle bone. Another part of the shaft is elastic to a lesser degree positioned in the direction of upper edge of the boot (80). A static side strengthening reaches from the sole to above the ankle bone, supporting the lower leg in the shaft of the boot and supplying it with the necessary progressively increasing resistance as the leg leans forward.

Description

Ski boot

The invention has a ski boot according to patent ... (patent application P 2 711 506.6), which consists predominantly of plastic and / or rubber, is the subject matter. It consists of a sole and a laterally rigid shaft connected to it, the gives the lower leg in the shoe the opportunity to move forward in the direction of skiing Bend the toe of the shoe against increasing resistance so that the lower leg in the shoe opposite the tread of the ski boot sole essentially by elastic Deformation of the shaft material in continuous use towards the front of the shoe and back by at least 150, taking into account an angular position given by the shaft for the lower leg and a maximum of 450 in relation to the sole of the foot in the shoe is and transversely to it in the direction of the surface of the outer contour of the shaft in inner side essentially Can be angled by no more than 40 due to elastic deformation of the shaft material is.

The cited main application provides the task of a limited mobility Bending movement of a lower leg in ski boots and solves them Task by appropriate arrangement of materials with relatively large elastic Stretch range, which increases the resistance to bending in the ski boot Oppose the lower leg.

The additional registration also provides the task of bending of a lower leg in the ski boot towards the tip of the boot against at least one of Parts of the shaft material formed or caused resistance when limited to oppose a progressively increasing resistance to his angling path and to support the lower leg laterally.

For this purpose, solutions are offered with essentially shaft materials, which in long-term use is essentially stressed in its elastic deformation range will.

These solutions continue with the following, through the task resulting solutions apart, such as 1. good, permanently dimensionally stable fixation of the foot in the shoe during the skiing season. This is necessary for the one on the foot in particular The lower leg bends on the ankle joint to create a solid base for bending procure.

2. non-positive connection between the upper part of the shaft and the lower leg, around the kinetic energy of the lower leg without loss of energy on the upper part of the shaft transferred to.

3. Energy transfer from the upper part of the shaft to the ski boot sole.

4. Progressive resistance with angle limitation against one bending the lower leg in the shoe, so that the resistance is almost progressive until the resistance that forms the deflection limit has risen.

5. Lateral stiffness of the ski boot to achieve good ski edge guidance.

6. If possible, return the from the angled lower leg to the upper part of the shaft given energy when the lower leg is bent back in the shoe.

A corresponding, listed problem-solving combination of characteristics, its definition and technical effect is described as follows: a) One-piece Lower leg and foot contour analogous outer shoe upper with sole and at least three different elasticities or hardnesses in different, adjacent ones Shaft areas, with at least one elastic, collapsible with wave-like Wall structure provided area essentially at the level of the shaft knuckle area is arranged and a less elastic shaft area above it in the direction of the shoe end edge, b) at least from the sole to over the ankle areas of the upper, as the shaft material, the shaft arranged on the right and left in its ankle areas, Static reinforcement on the side that covers the lower leg in the upper part of the shoe supports it laterally and gives it a progressive angle when it bends forward towards the tip of the shoe Opposes resistance.

Definitions Under a one-piece upper is an outer upper from one piece without an inner shoe to be understood, that from one piece including consists of the shoe sole or which is firmly joined together from several parts, that is has no parts that can mechanically move against each other with the exception of the overlaps and shaft fold zones that form the shaft closure.

Such a design is to be produced in the various shaft parts efficiently manufactured and connected to one another by welding, gluing or riveting or the shaft is in a mold around a mold core or part by Injection of different types of plastic with different properties manufactured. Shaft material includes material forming the shaft to understand its side reinforcements. The inner contour of the shaft follows essentially the contour of the foot and the lower leg in the shoe, also in each one (0 to 450) Angular position of the lower leg so that it has no significant play between the inner contour of the shaft and the contour of the lower leg and the Foot its bending energy on the shaft via lateral shaft reinforcements the sole and thus transferred to the ski connected to the sole. Between the The inner contour of the socket and the foot / lower leg are largely thermally insulating materials arranged with the same wall thickness.

Among wave-like collapsible shaft wall structure is one to understand shaft wall running periodically above and below a neutral plane. A wave-like shaft wall structure has a larger range of change in length and is defined here as resiliently deformable than resembling a smooth shaft wall Materials.

The technical effect of the combination mentioned is the possibility an economical production of a foot contour-analog shoe, its inner contour about the same wall thickness for relatively uniform over thermal insulation material Pressure on the lower leg and on the foot and its one-piece shaft due to its areas of different elasticity (a) and its side stiffening (b) an angled lower leg in the shoe - without joints, shock absorbers or other mechanical aids -a predetermined angle path with inside support (b) made possible, the one-piece structure of the shaft and the relative large angular deflection of the lower leg in the shoe caused material compression in Height of the ankle areas mainly in the ankle flexion area through folding is eliminated.

The following publications are cited as state of the art: For shaft folds DT-PS 269 873, US-PS 3,535,800, for different shaft hardness ranges DT-OS 1 685 274, for side reinforcement of the shaft DT-PS 1 807 117.

None of the cited documents pursues the complex according to the invention Task, their measures are still suitable to represent a functional ski boot, which transfers the energy of the skier so well to the ski.

To make the foot relatively stable in motion in the shoe as a lysis for the angled one To position the lower leg while keeping the upper instep area soft and also to create an adaptability of the inner shoe to the foot that is possible at any time furthermore the following combination of characteristics has been proposed: a) sole and Shaft sides at the level of the foot sides of the foot in the shoe are relatively stiff, analogous to the contour of the foot and shell-shaped, with arranged on the shaft sides in the shaft knuckle area, Laterally stiff, elastically deformable reinforcements that form an angled lower leg Oppose a progressive resistance in the shoe, b) more cup-shaped Shaft part at least partially overlaps from elastic material, which at least partially forms the rest of the foot contour-shaped shaft, c) detachable molded foam inner shoe, the outer contour of which is essentially identical to the inner contour, at least the rigid one The shell is and its foam is on average no more than in use 30% elastic deform.

The technical effect of the combination a) to c) consists in a relatively, also unaffected by external mechanical and thermal influences in long-term use (a) good positioning and lateral support of the foot through a rigid shell (a) Overlapping elastic layer protecting against abrasion (b), which also adapts to the most varied of instep contours without pressing and thus secures the foot well in the shoe from above; one by approximately the same wall thickness an inner shoe (c) caused pressure distribution and fixation of the inner shoe (c) stored foot, which is thus well fixed in the shoe and thus on the Ankle joint of the foot's rolling lower leg provides a relatively resting base, which allows the skier to relax the muscles of his lower extremities Effect maintains a good stand in the ski boot.

The following publications are cited as state of the art: For overlaps DT-PS 1 685 766 and for a foam inner lining DT-PS 1,685,776.

The two patent specifications neither pursue the inventive task solid fixation of the foot in the shoe as a basis for an angled lower leg The measures of the mentioned publications are still suitable, the aim of this combination to achieve: uniform pressure on all sides, good pressure distribution and thus good Fixation of the foot in the shoe.

The shoe parts can be elastic, overlapping ones of particular advantage Layer and rigid, shell-shaped part connected to one another via tongue and groove be, with undercuts attached in the grooves of the cup-shaped part can be, in which the elastic layer can anchor itself with its springs. This is useful, for example, when the rigid and elastic part is around a mold core splashed or squeezed around. The mold release agent's first on the core The manufactured part then does not have to be removed. Later in the use of the Shoe can have the elastic outer layer, at least of the upper, if it is e.g. is mechanically damaged, it must be replaced with a new one, which is an advantage can be.

According to the main registration is in an elastically stretchable ski boot cuff a limited longitudinally adjustable retaining organ (as an overstretching of the elastic 11 sleeve prevents.

According to the invention it is possible to bend the lower leg in the shoe against a progressive resistance exclusively through laterally rigid reinforcements and use a cuff that has little or no elastic stretch features. Thermoplastics are ideal for reasons of price and processing like polyurethane or polyester. They have approximately 500 kgf / cm² tensile strength at 0.8 to 2, at most 3% elastic elongation. An elastic deformation occurs at a load of over approx. 1 to 2.5% tensile strength of the thermoplastics. According to the invention, the thermoplastic shaft above the shaft knuckle areas a sufficient service life, even if it is overstrained by e.g. a fall Skiing, to lend, a band-shaped holding member is proposed; this encloses a lower leg in the shoe and limits its bending.

It is connected to the side reinforcements and is above the shaft ankle areas and prevents overstretching of thermoplastic Shaft material.

The holding member can be made of woven fabric, knitted fabric or a band made of textile or steel. These materials ensure static relief and thus possibly a material saving of the thermoplastic shaft material.

Is made of an elastic shaft part in the area of the height of the lower leg a progressive resistance in the shoe compared to an angled resistance in the shoe Requires the lower leg, a mesh structure can be made in the elastically stretchable material be integrated, the meshes of which contract when elongated and on the elastic shaft material lying between the meshes exert a pressure which ensures that the mentioned elongation is slowed down with the Effect of a progressive elongation resistance caused by the mesh size in the part of the shaft above the ankle area.

The lower leg, which is angled in the direction of the tip of the shoe, slides on the talus roll approx. 3 cm towards the tip of the shoe (see also Figure 5). The shaft material should elastically bridge this change in length. As described above, thermoplastics usually not, so the lower leg is in a thermoplastic ski boot is not held positively in every angular position. The Lower leg due to the construction according to the invention in every angular position in the shoe be supported at least in its lower region, such as by the invention Instep band, which is connected to the upper part of the shoe and designed in such a way that it does this Requirement met. The instep band is on the inside, on the inside of the shoe, on the rear wall of the upper part of the shoe Fixed above the shoe sole and is outside, on the outer shaft wall above the shaft knuckle areas are arranged so as to be adjustable in length and detachable. Its width protrudes towards the gap formed by the skier's ankle in the shoe Lower leg by at least 20 mm and is in its at least the lower tibia im Shoe encompassing area designed to be elastically deformable in long-term use.

This instep band ensures with its elastically deformable areas that the larger the lower leg bend in the shoe, the firmer the foot is pressed into the back of the shoe.

This is crucial because the foot is all the more secure in the The shoe must be fixed, the more the skier kneels. With progressively increasing The shaft resistance to an angled lower leg in the shoe increases Ski tip pressure also progressive with an increase in the angle of the angle of the lower leg. Control forces moving in ski boots can only save energy then for the skier on skis are transmitted when the frictional connection The shaft / foot / lower leg is retained in any case. By inventive The instep band is improved as described.

Another advantage is an at least partially exchangeable arrangement of at least three parts that form the shoe, such as laterally stiff shaft reinforcements, Foam intermediate inner shoe, felt inner shoe, instep band, elastic outer shoe skin. This means that renewal or drying can be carried out when used or due to wetting so that the foot / lower leg are always held evenly in the shoe can.

An economical production of a plastic ski boot that is particularly is suitable for the lower leg that is angled in the shoe with good long-term forest stability Fixing the foot in the shoe is to oppose a progressive resistance characterized in that a plastic outer ski boot is made around a molded part becomes, firstly, relatively harder, at least the shoe sole and the shaft sides at the level of the foot in the shoe forming plastic in this mold part, which is from a Counter-form is covered, injected, poured or pressed, the counter-form is removed is, secondly, another counter-shape with the first-mentioned mold part on which the manufactured shoe part remains, is connected, and elastic plastic is injected or poured into the mold so formed, so that at least partially the hard shoe sole and the mentioned shaft sides overlap and the rest Shoe is at least partially formed and then after curing of the plastic and removal of the mentioned counter-shape of the outer ski boot from the first mentioned mold part is removed.

According to this type of production, a plastic outer ski boot is easy made from two layers of different hardness.

If the mold release agent used to make the first, relative hard shaft part opposite to the second to be applied to the first shaft part elastic shaft part should have an undesirably large separation effect, is proposed according to the method, the first gear before the second injection process Manufactured shoe part, after removal of the counter-form that formed by the counter-form To free the contour surface from the release agent.

Another manufacturing method is to create a mold for manufacturing of a plastic outer ski shoe at the same time or with a temporal overlap with Materials of different hardness or elasticity filled by injection.

This gives the materials different characteristics Joint well connected. The process is also suitable for the production of Stiff design in the lower shaft area and softer design in the upper shaft area.

If a lower leg bends up to about 450 in the shoe, this has as shown in accordance with the invention, structurally an accumulation of foldable shaft material in the upper instep area. Shaft folds that undercut technically, can only be produced with very complicated shapes, so that according to the invention in proposal is brought to produce a plastic outer ski boot in two halves and this to connect with each other approximately in the central longitudinal plane of the ski boot.

The lower leg, which is angled towards the tip of the shoe, tightens the as Reinforcements designed for springs, which when relieved by the lower leg the Give the energy that has been put into them back to the lower leg. To this alternating stress To dampen, it is recommended to at least partially cover the reinforcements with materials to be surrounded with a relatively high shock absorption capacity. Is suitable as a material e.g. polyurethane.

The arrangement or connection of shock absorbing material between or with springs is state of the art, so that about no further Statements are to be made.

For easy-to-use increase or change of resistance an elastically stretchable cuff above the ankle area is an exchangeable, surrounding the lower leg at least in its half inclined towards the toe of the shoe elastic band (z. B. made of rubber) arranged with its ends on the side Reinforcements (9, 41, 50) e.g.

are fastened with snaps.

To regulate a zone-wise stiffening of the shoe upper is provided the upper approximately perpendicular to the sole with thickenings in which Reinforcement inserts can be arranged to be provided. The thickenings in the shaft have recesses into which reinforcement inserts made of spring steel or GRP are inserted or can be pulled out.

FIGS. 1 to 9 describe further details of the invention by way of example.

FIG. 1 shows an ortho sketch of a foot with an angled foot on it lower leg part.

Figure 2 shows a shoe upper reinforcement.

Figure 3 shows two spring travel characteristics.

FIG. 4 shows a cross-sectional drawing in the ski boot ankle area.

Figure 5 shows a reinforcement.

FIG. 6 shows a schematic representation of ski boots in two degrees of deflection.

FIG. 7 shows a section through a foldable wall structure.

FIG. 8 shows a section from a reinforcement part.

FIG. 9 shows a ski boot fastener in the front instep area.

FIG. 1 shows an ortho sketch of a foot 1 on a 70 plane 2 with the lower half of a lower leg 3 with tibia 4 (fibula not shown). If the Lower legs!; Els 3 of 50 in the direction of the toe toe 10 based on a horizontal in shoe sole area 5 by 400, an assumed cr llaut point 6 radially around the tibia pivot point 7 to point Sa. From the half-point distant from the body L2 to the eighth point distant from the body L8, the strength of the tibia 4 decreases and has at L8 the smallest bending moment. By the described ablation of the tibia 4 at 40 ° there is an approx.

50 ° Oige length shortening in the instep bend area between the skin points 6, 6a and 6c. These facts write in the case of a one-piece (hinge-less) Ski boot a lower leg contour analogous to the lower leg 3 in the shoe Frictional socket inner contour in the L2 to L4 area of the tibia 4 in the shoe and a collapsible, elastic, underlying area at the level of the Shaft ankle areas and a shoe shaft height up to at least the aforementioned L2 point.

Line 8 indicates the position of a shoe end edge. Around the shaft area at level L2 to L4, contour of the lower leg in every angular position of the tibia 4 and to keep it laterally stiff due to precise energy transfer from the lower leg 3 on the ski boot, in FIG. 2 there is a laterally stiff shaft reinforcement 9 made of spring steel (t80 x 2 x 6 mm) shown schematically in side view and the one in the direction of the toe of the foot 10 at its upper end 12 opposes a progressive resistance, namely within the scope of their elastic deformability. This resistance arises by zone-wise different moments of resistance of the reinforcement 9, which at their upper end 12 facing the shoe end edge 8 has a plurality of rod-shaped legs 11 has different lengths. The gain 9 can also be made several at their base at their lower end 13 interconnected, elongated, Rod-shaped legs / springs 11 are made. The connection of the springs 11 at their Base 13 is possible by a base part 16, one area 14 of which is sleeve-shaped is formed and the springs 11 are detachable and replaceable fixed. The other area / leg 15 of the base part 16 is not shown here Shoe sole connected in sole area 5. In the upper area 12 of the reinforcement 9 are two longer springs 11c connected to a locking part 17, which is for the outer springs 11a and 11b has run-up surfaces 17a and 17b, which is the moment of resistance of reinforcement 9 when the reinforcement is bent in direction 10. This resistance increase can advantageously be designed structurally so that the lower leg 3 in the shoe practically cannot angle more than 45 ° with respect to the sole of the foot, which is achieved by the Number, length and strength of the rod-shaped springs 11, 11a, 11b, 11c is possible.

The locking part 17 of the reinforcement 9 is via its rivet hole 17c connected to the upper part of the shaft, not shown here, so that the energy from Lower leg 3 of the skier over the upper part of the shaft and over the reinforcement 9 is transferred to the ski boot sole in the sole area 5.

In FIG. 3, there are two spring travel characteristics of spring legs 18, 19 of the same length, showing a different change in length in the case of radial Loading of its upper end 12 in the direction 10 can be seen. This illustrated Change in length shows the function of a reinforcement 9 with at least two springs 18, 19. 20 in Figure 2 represents a sleeve of the reinforcement 9, which the springs 11 encompasses. It (20) is attached to the upper of the shoe, transversely to the longitudinal direction of the shoe Transverse sides 21, 22 with a curved shape, which increase the bending resistance by increasing the moment of resistance at the lance of the outer springs 11a, 11b, predetermined enlargement. A corresponding Design of the reinforcement parts 11, 20, 17 described above ensures a change of the moment of resistance of the gain 9 and a change in a progressive resistance compared to a lower leg bending in the shoe 3. The reinforcement in figure 2 is made of spring steel, it can also consist of GRP. Reinforcement is advantageous 9 at least partially anatomical foot shape, as shown in Figure 4 is shown. 23 is a molded foam intermediate liner that can be removed from the shoe, the outer contour of which is essentially identical to the inner contour of the rigid, shell-shaped Shaft part 25 is at the level of the foot sides of the foot (not shown here). being Foam preferably has over 50% open cells. This has, among other things, an easier one Water vapor absorption and easier drying and thus greater resistance of the thermal insulation of the foot in the shoe result. The stiff, bowl-shaped one Shoe part 25 consists of ABSG (40% glass fiber content), which makes it relatively stiff and is designed to be permanently dimensionally stable. It is overlapped by more elastic shaft material 24 made of a mixture of PUR / polyester. The reinforcement 9 is L-shaped and their ends 27 overlap here in the shoe sole area 5. For better transmission and distribution of the force contained in the reinforcement 9 to the sole area 5 of the ski boot is a U-shaped reinforcement 40 of two in Figure 5 schematically L-shaped reinforcement members 41 shown, the lower legs 42, in Fastened shoe, overlap in the shoe sole area 5 and with an elongated base part 43, which lies in the area of the shoe center longitudinal plane in the shoe sole area 5 are. Connecting parts 44 such as rivets connect the reinforcement 40 and the base part 43. The reinforcement parts 41, 43, 44, which are shown in Figure 5, can be series can be produced economically and easily integrated into the shoe and connected to it.

FIG. 6 shows a ski boot 100 made of thermoplastic in two angled positions of the upper shaft part 80 with its outer part 30 made of elastic material 24 with 2 mm wall thickness and the rigid shaft part 25, which here belongs to the outer part.

Due to the aforementioned angling, there is a build-up of material in the Flexion of the instep 35 from 94 to 34 mm (by approx. When the lower leg is bent 3 in the shoe towards the tip of the shoe of about 400 instead of that Shaft material 30 in the shaft-Achilles tendon area 36 when the lower leg is angled backwards 3 folded from 122 to 66 mm.

Such changes in length can be made by thermoplastic material with approx. Can not cope with 2% elastic elongation, so that within the framework of the material characteristics of thermoplastic, elastic plastic one constructed, the foot 1 in the shoe 100 non-pressing wrinkling is proposed in the amount of Shaft knuckle areas essentially fan-shaped around the pivot point 7 of the lower leg 3 in the shoe 100, the mentioned fold areas 35/36 at least a 20% change in length enable. A change in length of only 20% is provided if the ski boot is designed for an angle of less than 400 mm or shaft material with a high angle elastic stretching is used.

31 shows a foam lining of the shoe 100 in the ear shaft area represents, which has approximately a uniform wall thickness, such as the foam intermediate liner 23

Since the inner contour of the outer shaft 30 with its layer-shaped Parts 25, 24 is designed to be analogous to the contour of the foot, the foot / lower leg is 1/3 in Shoe evenly due to the even foam wall thickness with even Pressure fixed in shoe 100. This ensures optimal power transmission from the foot / lower leg 1/3 guaranteed on the shoe 100.

FIG. 7 shows a shape that promotes the folding of the shaft wall 30 for the shaft areas 35, 36 of the collapsible wall structure in section. the The foldable wall structure consists of approximately perpendicular to the outer and inner contours 37 of the shaft wall 30 standing walls 39, which run parallel to one another and their Ends with approximately flat walls 39 are connected at an angle over 900, which in turn are connected to each other at an angle of over 900. <Figure 8 shows one Section from a Z The walls 38,39 here have 1 millimeter Wall thickness. 14 folding shelves R 6.% millimeters bridge 9.4 millimeters and can be compress to 34 millimeters.> perpendicular to the shoe sole standing part of a reinforcing part 50, which is inserted into the shaft bone on the right and left is attached to the shaft wall, which on its longitudinal sides 51 your to its longitudinal axis 53 columns 52, which determine its moment of resistance in the course of its bending in Increase towards the tip of the shoe 10.

A similar gain is described in DT-OS 2 163 872.2. However, it finds a reinforcement between the shaft ankle areas and the Knee use and is not intended to represent progressive resistance of a shaft upper part designed against an angled lower leg in the shoe.

Figure 9 shows a partial view of a front ski boot with a Closure means 59 for good fixation of the foot 1 in the shoe 100. A foot contour analog Plate 60 presses the foot 1 into the shoe 100, in the cable 62, which is the most rigid Part 25 of the shoe upper are attached to the cable 62 by at least one buckle 61 are shortened and thus plate 60 fixes the foot 1 in the shoe 100, while the Cable 62 at the same time close the elastic shaft overlap 32.

By closure means 59 according to the invention, the foot is from above in Shoe 100 pressure-free and well fixed.

The technical effect of the invention consists in a plastic ski boot with good lateral stiffness, human-anatomical optimally possible and limited Bending of the lower leg in the shoe against a progressive bending resistance. Economic production methods are given and the possibility of Exchange of shoe parts for long-term maintenance and changing the usage properties of the ski boot. L e r s e i t e

Claims (30)

Claims 1 ski boot, mainly made of plastic and / or rubber according to patent ... (patent application P 2 711 506.6) from sole and associated Laterally stiff shaft, which allows the lower leg to be placed in the shoe while skiing to bend forward towards the tip of the shoe against increasing resistance, so that the lower leg in the shoe opposite the tread of the ski boot sole in the essentially due to elastic deformation of the shaft material in long-term use at the front towards the tip of the shoe and back by at least 150, taking into account one angular position given by the shaft for the lower leg and at most 450 opposite one another the sole of the foot in the shoe can be angled and across it in the direction of the surface of the The outer contour of the inside of the shaft is essentially due to the elastic deformation of the Shaft material is not angled by more than 40, characterized in that at least the outer part of a shoe upper (24, 25) is formed in one piece is that a lower leg (3) is supported laterally in the shoe (100) and in the direction Shoe tip (10) against at least one of parts (9, 41, 50) of the upper material formed, progressively increasing resistance can bend, the shaft material (24, 25, 9, 41, 50) is designed and arranged so that it can be used continuously in is essentially stressed in its elastic deformation range. 2 Ski boots, mainly made of plastic and / or rubber according to patent ... (patent application P 2 711 506.6) made of sole and associated lateral stiffness Shaft that gives the lower leg in the shoe the ability to give way when skiing angled forward towards the tip of the shoe against increasing resistance, like this that the lower leg in the shoe is essentially opposite the tread of the ski boot sole by elastic Deformation of the shaft material in long-term use to the front in the tip of the shoe and back by at least 150, taking into account an angular position given by the shaft for the lower leg and at most 450 can be angled in relation to the sole of the foot in the shoe and cruer towards it The surface of the outer contour of the inside of the shaft is essentially due to elastic deformation of the shaft material cannot be bent by more than 40, characterized in that its characteristics consist of the following combination: a) one-piece lower leg and shoe upper (24, 25) analogous to the foot contour with a sole, with at least three different ones Elasticity or hardness in different, adjacent shaft areas (24, 25, 35/36, 80), with at least one elastically deformable, wave-like, area (35, 36) provided with a collapsible wall structure essentially at the height of the shaft knuckle area and a less elastic shaft area (80) above is arranged in the direction of the shoe end edge, b) at least from the sole to above the ankle areas of the shaft reaching more than the shaft material in its Ankle areas each have a static reinforcement on the side (9, 41, 50) is arranged, which supports the lower leg (3) laterally in the shoe upper and him when it is angled forward towards the tip of the shoe (10) a progressive one Opposes resistance. 3 ski boot according to claims 1 and / or 2, characterized in that that its characteristics consist of the following combination a) sole and shaft sides, those at the level of the sides of the foot in the shoe are relatively stiff, analogous to the contour of the foot and are shell-shaped with arranged on the shaft sides in the ankle area, laterally rigid, elastically deformable reinforcements (9, 41, 50), b) partial overlap of the shell-shaped shoe part (I5) by elastic material (24), which at least partially forms the rest of the foot contour-shaped shaft, c) detachable molded foam inner shoe (23), the outer contour of which is essentially is identical to the inner contour of at least the rigid shell (5) and its foam does not deform elastically by more than 30% on average in use. 4 ski boot according to claim 3, characterized in that a connection of the stiff, cup-shaped shoe part (25) with the overlapping part made of elastic Material (24) is made via tongue and groove connections by inserting in the stiff shoe part (25) Grooves or undercuts and springs are arranged in the elastic part (24), which fill the grooves true to the contour. 5 ski boot according to claim 2, characterized in that the collapsible Wall structure (35, 36) essentially at the level of the shaft knuckle area, essentially fan-shaped around the pivot point of the lower leg (7) in the shoe by at least 20% shortening its original length or collapsing at least 20% lengthwise is. 6 ski boot according to claims 2 and 5, characterized in that the collapsible wall structure made approximately perpendicular to the outer and inner contour (37) of the shaft wall (30) consists of standing walls (38) which are parallel to one another are arranged and at their ends with approximately flat walls (39) at an angle over 900 are connected to each other and these.approximately flat walls (39) in turn in are connected to each other at an angle via SOO. 7 ski boot according to claim 1, 2 or one or more of the preceding Claims, characterized in that laterally stiff sides on the shaft sides Reinforcements (9, 41, 50) under 1al £ of the shaft knuckle areas with the shaft and connected to it in the upper part (80) of the upper, which are parallel to the longitudinal plane of the shoe zonenweisc have different moments of resistance. 8 ski boot according to claim 7, characterized in that the zonal different resistance moments of the reinforcements are formed by at least several resilient legs (11) of different lengths in their upper, the shoe end edge facing areas (8). 9 ski boot according to claims 7 and / or S, characterized in that that the reinforcements (9) from several, at their lower ends (13) together connected rod-shaped, parallel springs (11) are made. 10 ski boot according to claims 7 to 9, characterized in that that the reinforcements (9) from several, at their lower ends (13) together connected, rod-shaped, parallel springs (11) are made. 11 ski boot according to claim 10, characterized in that the rod-shaped Springs (11) are arranged interchangeably. 12 ski boot according to claims 7 to 11, characterized in that that the reinforcements (9, 41, 50) are made of GRP or spring steel. 13 ski boot according to claims 7 to 12, characterized in that that at least one of the springs (11c) of the reinforcement part (9) at its upper end (12) has a locking device (17) intended for at least one other spring (alb), which covers the other spring (1 1 c) with a distance that the Bending resistance when the lower leg reaches a predetermined deflection path (3) in the shoe, taking into account the bending moment of the lower leg (3) the release force of the ski binding is increased. 14 ski boot according to claims 7 to 13, characterized in that that its reinforcing springs (11) are surrounded by a sleeve (20) whose short Transverse sides (21, 22) have a curved shape transversely to the longitudinal direction of the shoe, when the outside rod-shaped springs (11) are in contact with the curved ones Transverse sides (21, 22) increase the bending resistance in a predetermined manner. 15 ski boot according to claims 7 to 14, characterized in that that the reinforcement parts (9, 41, 50) at least partially have an anatomical shape exhibit. 16 ski boot according to claim 7, characterized in that a reinforcement part (50) on at least one of its longitudinal sides (51) transversely to its vertical longitudinal axis (53) gaps (52) that show its section modulus in the course of its bending towards the tip of the shoe (10) e'rhöh 17 ski boot according to claims 7 to 16, characterized characterized in that the reinforcements (9, 41, 50) are at least partially made of materials are surrounded with a relatively high shock absorption capacity, the restoring force of the brake relieved reinforcements (9, 41, 50). 18 ski boot according to one or more of the preceding claims, characterized in that in an elastically stretchable sleeve of an upper part of the shaft at least one elongated mesh structure above the ankle areas of the shaft is integrated in the shaft material, which angled towards the tip of the shoe in the shoe Lower leg opposes progressive resistance. 19 ski boot according to claim 18, characterized in that around one elastically stretchable cuff of a shaft upper part (80) above the ankle areas an exchangeable one, the lower leg at least inclined towards the tip of the shoe Half surrounding elastic band is arranged with its ends on the side Reinforcements (9, 41, 50) are attached, which reduce the resistance of the cuff (80) compared to a lower leg (3) that bends in the shoe. 20 ski boot according to one or more of the preceding claims, characterized in that its shaft extends approximately perpendicular to the sole Has thickenings in which reinforcement inserts are arranged. 21 Ski boot according to claim 3, with at least one closure means (59), characterized in that there is a plate analogous to the instep on the front shoe (60) is arranged with at least one locking buckle (61), the cable (62) Fixed in length adjustable, which is connected to the stiff, shell-shaped shoe part and the overlap (32) closing the front shoe is covered in a closing manner. 22 ski boot according to one or more of the preceding claims with an instep band on the inside of the shoe on the back of the upper wall is fixed above the shoe sole and the outside on the outer shaft wall above the shaft bone is adjustable in length and detachably arranged and its Spread the gap formed by the skier's ankle in the direction of the shoe The lower leg protrudes by at least 20 mm, characterized in that it is at least in his, the lower tibia (4) in the shoe (100) encompassing area in continuous use is designed to be elastically deformable. 23 ski boot according to claim 1, characterized in that its lateral Reinforcements (9, 41, 50) below and above the ankle areas with the shaft wall are connected so that the reinforcements (9, 41, 50) the approximately calibrated way describe like the angled lower leg (3) enclosed by the upper part (80) in the shoe (100). 24 ski boot according to one or more of the preceding claims, characterized in that the shaft upper part (80) at least above the shaft knuckle regions consists of a thermoplastic and one that encloses the lower leg (3) in the shoe (100), it is arranged in its bend limiting band-shaped holding member that with side reinforcements (9, 41, 50) is connected. 25 ski boot according to one or more of the preceding claims with a U-shaped reinforcement, characterized in that a U-shaped Reinforcement part (40) with mutually aligned legs (42) of two L-shaped Reinforcement parts (41) are formed, which with a base part (43) in the shoe sole area (5) are connected, which is approximately parallel to the central longitudinal axis of the shoe (100) runs. 26 ski boot according to one or more of the preceding claims, characterized in that it consists of at least three mutually detachable shoe parts, the together form a ski boot, consists of an outer shoe, a foam intermediate shoe and a felt liner. 27 Process for the production of a plastic outer ski boot according to Claim 2, characterized in that a plastic outer ski boot around a molded part is made by 1. relatively harder, at least the shoe sole and the shaft sides at the level of the foot in the shoe forming plastic in this molded part, the is covered by a counter-form, is injected, poured or pressed, the counter-form is removed, 2. another counter-shape with the first-mentioned mold part on which the manufactured shoe part remains, is connected and elastic plastic is injected or poured into the mold so formed, so that at least partially the hard shoe sole and the aforementioned shaft sides overlap and the rest of the shoe is at least partially formed and then after demoldable hardening of the Plastic and removal of the opposite shape of the outer ski boot from the first mentioned Mold part is taken. 28 The method according to claim 27, characterized in that before second injection process the shoe part produced in the first gear after removal of the counter-mold the contour surface formed by the counter-mold from the mold release agent is released. 29 The method according to claims 27 and 28, characterized in that that in one form at the same time or with a temporal overlap oil materials of different Hardness or elasticity are injected. 30 The method according to claims 27 to 29, characterized in that that a plastic outer ski boot is made in two halves and this approximately be connected to one another in the central longitudinal plane of the ski boot.