SE1450121A1 - Ski binding and sole for a ski boot - Google Patents

Abstract

The invention relates to a ski boot sole (12) and a ski binding (30). The sole consists of a toe part (TP), a metatarsal part (MP) adjacent to the toe part and a rear part (RP) extending from the metatarsal part (MP) to a rear end (R) of the ski boot sole (12) and a front part ( FP) extending from the toe part (TP) to the front part (F) of the ski boot sole. The front part (FP) consists of a ski binding bracket (20) consisting of an extension (15) which is locked in a groove (32) to ensure that forces are absorbed in the binding. The binding (30) consists of a base plate (31), a positioning channel (22), a groove (32) in the side walls of the ski binding and it has a friction pattern (29) and 16) where at least two side walls (33) are arranged on each side of the longitudinal center axis (1) of the binding (30). A locking mechanism (35) is attached to the base plate (31). A ski boot bracket (40) consists of a clamping bar (27) and a clamping arm (41) with a hinge connection to the base plate (31). The clamping arm (41) which is suspended in the base plate (31) has a point of rotation arranged immediately above the base plate. At this point of rotation, the lever arm (26) is arranged which is connected to a point of rotation in the locking plate (25). The locking plate (25) is in turn attached to a point of rotation on the base plate (31). When closing the binding (30), the locking plate (25) will transmit force via the lever principle and clamp down the clamping arm. (41) against the extension (15)

Description

10 15 20 25 30 2 The movement described above during the last part of the kick-off is not possible with said ski boot sole and ski binding. As shown in FIG. 1c and 1d, there is too little flexibility in the front of the sole to do it is possible to achieve a running type movement in the anterior part of the metatarsal the area and the entire toe area during the execution of the kick-off. Consequently, during the initial phase of the execution of the kick-off, the ski boot will begin to rotate about the axis 2, as illustrated in Figure 1c. From that time and to the completion of the kick-off, as illustrated in Fig. 1d, the ski the boot to be lifted from the ski due to its rotation around the shaft 2, and thereby losing its contact and force against the ski and the surface, which means that it the resulting force points upward relative to the ski.

Furthermore, with the help of the ski's built - in span, the ski's mounting bracket is lifted. party up from the snow, ie. the attachment in this critical part of the free kick disappears.

This means that the last and important part of the kick-off, which could have contributed with increased acceleration and increased stride length with the help of the large ones the muscle groups of the calf, thigh, and gluteal muscles, cannot be utilized. IN shortness, the kick-off becomes less effective because the movement is not completed, as is natural when walking and running.

The term "to complete the movement" is widely used in sports. It is all- meant to understand that in order to achieve the best possible effect of a movement, it must completed in a natural way and not interrupted prematurely. Well-known examples are running and walking, golf, tennis, throwing, shot put, kicking a football, etc.

The above description of a truncated kick in today's cross-country skiing skiing sports indicate that it is a contributing factor to it steadily increasing the use of the arms in cross-country skiing and long-distance skiing competitions today are often won by competitors who do not perform a single kick, despite the fact that arm strength normally accounts for only about 20% of the total bone strength. For the average skier who is not wealthy or willing to develop extreme arm strength, this type of extensive use of the arms not an option.

AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 3 The object of the invention is to provide a ski binding and a associated sole for a ski boot which offers the skier the opportunity to one longer and more powerful kick-off. This will result in a more efficient technology, higher speed and a longer sliding and resting phase per step during skiing and skating on skis. This results in a more efficient use of the larger muscle groups, where the calf muscles also come into play.

The object of the invention is further to provide a sole for one ski boot which gives the skier good control over the skis in all conditions countries, especially downhill.

A further object of the invention is to provide a low file binding and a sole system. Yet another object of the invention is that the fastening device of the bond does not should touch the side walls of the ski track as it has a braking effect.

In a similar manner, it is an object of the invention to provide a ski boot sole and a ski binding which provide a robust and reliable connection between the ski binding and the ski boot sole.

It is also an object of the invention to reduce the weight of the ski the boot and the ski binding.

These objects are achieved with a sole for a ski boot in accordance with know 1, a ski binding according to claim 9, and a system according to claim 16. Further embodiments of the invention are set forth in the dependent claims the requirements.

SUMMARY The present invention provides a ski boot sole that is similar flexible like the sole of a jogging shoe in the longitudinal direction at the toe area and tatarsal area of the sole, while at the same time giving the sole a sufficient stability in torsional and transverse joints to give the skier good control over the skis in all conditions and especially downhill.

The present invention also provides a fastener for the binding which is preferably arranged in front of the toes and steadily tensioned. AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 4 down the sole down towards the ski, with the result that the foot is always pressed against the surface throughout the execution of the kick-off sequence.

The bond preferably does not extend on the outside of the side of the boot. dead parts which would result in the binding gripping the sole on the side toes, whereby the bond would have become too wide and consequently touched the side walls of the year and provided a braking effect.

Furthermore, a low profile bond and a sole system will result in better control of the skis and in generally better balance, as the foot therein by being moved closer to the ski.

Sole for a ski boot The invention comprises a fiber sole as illustrated in Figure 3, with a transverse extension in the front of the tip of the fiber sole. Extension may be between 200% and 800% thicker than the sole described and it protrudes on each side of the front of the sole. The fibrous sole determines essentially the mechanical properties of the ski boot. The fibrous sole covers the boot full length and is the supporting element of the boot, to which the upper part of the boot is attached or glued. Therefore, when reading this document, it should be understood that when the sole of the ski boot is mentioned, this refers to the fiber sole of the ski boot. The ski boot has also a tread sole, but this is thin and will be so soft that it will not contribute to any significant extent to the ski boot mechanical characteristics. The outsole should therefore be considered as a supplement to the the boot sole of the present invention.

The front of the sole has a complementary shape in relation to the binding the control channel 22, Fig. 4. The fibrous sole fits directly into the attachment order, and the sole of the fiber therefore determines the mechanical connection between lan ski boot and binding.

The invention utilizes a property of oriented fiber layers. In a oriented fiber layer, all the fibers are in one direction and the elasticity the module is generally twice as large along the fibers compared to AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 5 across the fibers. In combination with a variation of the number of layers in the sole different zones, this can be used in the construction of the ski boot sole where desired the modulus of elasticity is modeled in the different zones of the sole both in the longitudinal direction (x-direction) and in the transverse direction (y-direction) illustrated in Fig. 3.

The fibrous sole can also be constructed with a layer of braided fibers, or constructed as a combination thereof. The fibers are in a braided fiber layer braided at an angle of, for example, 15, 45 or 90 degrees relative to each other.

Layers of braided fibers have slightly stiffer properties than oriented fibers.

The fibrous sole is relatively flexible in the longitudinal direction of the sole, from the toe pad (English of ball of the toe) up to the part in front of the toes, while it is countrywise stiff from the heel to the ball of the toe.

At the same time, the sole is relatively stiff in terms of torsion. These relative more is defined in greater detail in the section "Embodiments of the Invention".

A relatively thin and flat wear layer of rubber or synthetic material without guide channels glued to the underside of the fiber layer, Fig. 10.

The invention provides a reduction in the weight of the sole of between 65 % and 80% measured in relation to today's known ski soles, fig. 1. For a complete ski boot, the use of the fiber sole for classic cross-country skiing to give a weight reduction of between 25% and 50% compared to today famous boots.

Ski binding The invention relates to a ski binding with a fastening device which is arranged in its entirety in front of the toes. The bond has a control channel that has a complementary shape relative to the anterior portion of the fibrous sole. The power channel 22, which is dashed in fig. 4a, has a front wall and two side walls which may be arranged conically or parallel to each other, or they may have another geometric shape that prevents the boot from moving forward or forward side. In the front part of the side walls of the control channel, transverse ones have been made AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 6 groove to receive the sole extension end pieces. These prevent the boot to move backwards in relation to the binding.

A clamping rule in the construction of the binding falls down when the binding closes and clamps on the back edge of the boot tip extension along the entire length of the extension, the sole being attached to the guide channel of the binding.

This provides a robust connection between the sole and the binding.

The clamping bar can be lowered from the side across (ie in the y-direction) the ski, as illustrated in the binding variant of FIG. 13, or it can be lowered from the leading edge of the bond along (i.e. in the x-direction) the sheath, as illustrated race in Fig. 4.

The guide edges on the side of the binding are so high that they provide a lateral support for the attachment of the sole at the completion of the kick-off.

The invention gives the bond a weight reduction in the order of from 30% to 60%, compared to today's known solution.

Sole and binding The tolerance for the distance between the binding channel of the bond and the sole tip complementary shape is preferably between 0.01 mm and 3 mm.

The combined construction of the sole and binding of the invention ensures that the foot always presses down on the ski during the entire kick-off phase, and allows thus a more powerful and effective kick-off.

Thus, the invention leads to an expanded use of the larger ones muscle groups in the gluteal, thigh and calf muscles, as is natural when per- the son moves forward in the terrain. This results in a light, relaxed and effortless step for the average skier, where the legs are well developed stretching machine is fully used.

Extensive tests with prototypes based on the invention confirm above with good results.

AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 EMBODIMENTS OF THE INVENTION The scope and nature of the invention will now be described in detail with reference to the accompanying drawings, in which: Fig. 1a illustrates a previously known sole for a ski boot in connection with a ski in the position at the beginning of the kick-off; Fig. 1b is an enlarged view of the front part of Fig. 1a, with the big toe il- illustrated in relation to a ski binding and a ski boot; Fig. 1c illustrates the position of the prior art ski boot sole in relation to to a ski during the initial phase of the kick-off just before it lifts from the ski and begins to rotate about its axis of rotation; Fig. 1d illustrates the last part of a kick with the known one the ski boot sole and a ski; Fig. 2 illustrates a side projection of a ski boot; Fig. 3 illustrates a projection of the sole seen from above; Figs. 4a-c illustrate the ski binding in the open condition; Figs. 5a-c illustrate the ski binding in the closed condition; Fig. 6 illustrates a projection of the ski binding with the boot seen from above; Fig. 7 illustrates a heel friction bearing across the ski; Figs. 8a-8d illustrate the different phases of the ski boot during the execution of a kick in relation to the ski / binding; Fig. 9 illustrates a modulus of elasticity curve in the longitudinal direction (x- direction) for the different zones of the ski boot sole; Fig. 10 illustrates an example of the composition of the number of layers in lan; Fig. 11 illustrates an example of the attachment of an extension in the front the part of the ski sole tip and the woven fabric around it; AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 8 Figs. 13a-13b illustrate an alternative binding for the invention in the open and closed state; Fig. 14 illustrates an alternative ski binding; Figs. 15a-b illustrate an alternative binding in an open respective closed mode; Figures 16a-b illustrate a cross section through Figures 15a and 15b, respectively; Figures 1a-d illustrate an existing solution available on the market. naden.

Figure 2 illustrates a ski boot 10 comprising the upper part 11 of the boot and a ski boot sole. The ski boot sole 12 is assumed to be attached to the ski binding. which is attached to a ski 2 which will be described in detail below. dan. As mentioned above, when reading this document, it should be understood that when the ski boot sole or ski boot sole 12 is mentioned, the ski boot fibersula. The ski boot will preferably also have a outsole 13, but this is thin and will be so soft that it will not contribute to the mechanical properties of the ski boot sole 12 to any significant extent.

The outsole 13 is therefore considered an addition to the ski boot sole.

The ski boot sole 12 is divided into several zones or parts as illustrated in Fig. 2a; a toe part TP below the toe area of the foot, a metatarsal part MP below the the tartar area under the foot, a front part FP and a rear part RP.

The metatarsal area MP borders the toe part TP. The rear area RP extends from the metatarsal area MP to a posterior end R of the ski boot sole The rear portion RP of the boot comprises a boot heel or heel area 14.

The front part FP extends from the toe part TP to the tip F of the ski boot sole The front part FP comprises a ski binding bracket 20 which is attached to a ski binding, which will be described in detail below.

Fig. 3 shows that the ski binding bracket comprises a platform-shaped sole tip 21 with a transverse extent 15 (y-direction). The ski binding bracket 20 protrudes forward on the front of the upper part 11 of the boot and has a width of W20 which is less than the width of a ski trail. The width of a ski trail is nor- AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 9 malt from 60 mm to 80 mm. In the invention, the width of the ski binding is less than the width of a ski track, thereby preventing the ski the binding bracket 20 from coming into contact with the side surfaces of the ski track.

The ski binding bracket 20 includes a transverse extension which is is made of metal, carbon fiber, plastic, polycarbonate, POM, PEM, PET, aluminum minium or composite material. The purpose of the extension is to set the position and holding the flattened sole tip 21 of the ski boot sole securely in exactly the right direction the position with respect to the ski binding in a simple manner. In addition, so The extension 15 provides support and stability to the sole when attached to the ski. the bond. The extension 15 is preferably arranged in the front edge of the sole 12 and are preferably centered relative to the ski sole 12.

The extension 15 may, for example, be in the form of a transverse element mounted in relation to the front part FP of the ski boot sole 30 and which protrudes a little from the sides of the front part of the ski boot sole 12 FP. The length on the extension 15 may, for example, be between 5 mm and 80 mm preferably between 20 mm and 60 mm. The diameter of the extension 15 on the outside of the platformed sole tip 21 may, for example, be between 1 mm and 10 mm, preferably between 1 mm and 4 mm. The thickness of the extension in the ski boot sole between the side walls of the guide channel can, for example, be between 1 mm and 16 mm, preferably between 2 mm and 8 mm.

The extension 15 and the flat sole tip 21 will provide the sole with stability when fixed in the ski binding, in particular with respect to backward movement and lateral movement of the sole relative to the ski binding one. In an alternative embodiment, the flat sole tip 21 may have one an oval hole arranged on or near the sole 12 longitudinal central axis 1.

The sole 12 comprises a material in which the longitudinal elasticity of the x-direction, the transverse elasticity in the y-direction and the torsional rigidity in the sole 12 is determined by the properties of the fiber layer 12. The decisive factor tower for the stiffness and / or flexibility of the sole 12 in the x-direction and the y-direction determined by the number of fiber layers in the sole 12 construction, together with the fiber the orientation of the soles in the different parts / zones of the sole. The geometric shape of the ski boot sole AH p4503se00 2014-01-27 pans se över.doc 14-02-05 ver. 182 10 15 20 25 30 10 shape in the different zones of the ski boot sole is also a decisive factor for bending. similarity and rigidity.

In general, for fibers, the E-modulus along the fibers is double as large as it across the fibers.

The outer sole of the ski boot is preferably designed without rafters and preferably comprises a thin wear layer of rubber or the like, with an elastic modulus of stability between 10 MPa and 200 MPa.

A typical range of values for the E-module for different fibers is: Carbon composite, oriented and woven prepreg 45 degrees with elasticity module between 20 GPa and 190 GPa and fiberglass between 60 GPa and 80 GPa.

The sole layer 12 of the sole can be adapted to fit the shape and fit of the foot. the weight of the inverter.

In the invention, fiber layer 12 is a composite material comprising carbon fiber layers, for example oriented carbon fiber or curved carbon fiber of prepreg type where the layers are arranged on top of each other and gluing or fixed with a resin, such as epoxy. Typical suppliers of oriented coal fiber bearings and carbon fiber prepreg are: Zoltek (httpïilvtfvvvifzoitekxzomi) and Hexcel (http: // wwwhexcelxïoml).

As an alternative, the fiber layer 12 may comprise glass fibers, for example oriented glass fibers or in combination of carbon fibers and glass fibers, or turf fibers and various types of artificial fibers.

In the present invention, the rear portion RP is rigid in the longitudinal direction (x-direction) and the transverse direction (y-direction) and also torsionally rigid in longitudinal direction (around the x-axis). The front part FP is flexible / soft in the longitudinal direction. rigid in the transverse direction and also torsionally rigid in the longitudinal direction.

The metatarsal area MP is flexible in the longitudinal direction (x-direction), rigid in the the uppercase direction (y-direction) and also torsionally rigid in the longitudinal direction. Tädelen TP is flexible in the longitudinal direction (x-direction), rigid in the transverse direction (y-direction) and also torsionally rigid in the longitudinal direction (around the x-axis).

AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 11 A rigid ski boot sole will therefore be considered rigid in the (x-direction) of an adult of about 75 kilograms if the sole has the following stiffness: A force of 12 Newtons with 20 mm deflection and a force of 120 Nevvton with 85 mm deflection and a torque of 1 Newtonmeter with a turning angle of 5 degrees and a torque of 20 Newton meters with one rotation angle of 40 degrees.

Similarly, a soft ski boot sole will be considered soft in the longitudinal direction (x-direction) of an adult of about 75 kilos about the sole has the following rigidity: A force of 1 Newton with 20 mm deflection and a force of 32 Newton with 85 mm deflection and a torque of 0.4 Newton meters with a torque torque of 10 Newton meters with a rotation angle of 40 degrees.

The deflections and angles of rotation indicated above are obtained by to take the force / deflection measurements in accordance with standard procedures to measure deflection, as is known to those skilled in the art. Deflection re- the results indicated above were obtained using a sole that had fastened to a bench and where a force was applied to the sole at a length L = 140 mm from the clamping point, and the deflection caused by the at L = 140 mm was measured. Similarly, the angle of rotation was obtained by means of a sole that is fastened to a bench and there a torque was applied to the sole at a length L = 140 mm from the clamping point, and where the angle of rotation of the sole caused by the torques at L = 140 mm was measured.

It should be mentioned that whether a ski boot sole is considered stiff or soft is also a subjective assessment which also depends on, among other things other things than the skier's weight and whether the ski boot / binding is used for skating, classic cross-country skiing or telemark skiing, etc. Although the absolute physical measurements are given as a definition of softness and stiffness, it should therefore be noted that the terms "stiff" and "soft" as they are AH p4503seO0 2014-01-27 pans se över.doc 14-02-05 ver. 182 10 15 12 used here should be construed as ‘perceived as rigid’ and ‘perceived as soft’, depending on the skier's weight, the size of the boot, type of skiing discipline etc.

The same results as indicated above can be obtained using woven carbon fiber or woven glass fiber, or by combinations thereof. There is different weave configurations and angles between the fibers, where for example a 45-degree angle can be used between the fibers.

It should also be mentioned that flexibly rigid / flexible in the longitudinal direction should understood as flexibly rigid / flexible when deflected around an axis in a transverse the y-direction in a corresponding manner, flexibly rigid / flexible in the transverse the direction should be understood as flexibly rigid / flexible when deflected around an axis in the longitudinal direction. Longitudinal torsionally rigid should also be understood as torsionally rigid around a longitudinal axis in the x-direction.

Table 1 below shows an example of the orientation of the fiber layers 12.

The fibers can be oriented in the longitudinal direction, ie. parallel to it longitudinal central axis In the transverse direction, i.e. perpendicular towards the central axis 1, or in a diagonal direction, i.e. at an angle of 30 degrees, 45 degrees or 60 degrees to the axis I.

AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 13 Table 1: Examples of number of layers and orientation of fiber layers 12 in a sole.

Part of Number of stocks Number of stocks with fi- Number of stocks with Total sole with fiber-rich orientation in fiber orientation in the in the longitudinal transverse direction - the diagonal direction the direction (x- one (y-direction) a bearing direction) Front 0 2 2 4 del FP Toe part TP 0 2 2 4 Meta- 1 1 2 4 tarsal del MP Rear part 2 2 2 6 RP As an alternative to oriented fibers as in the table above, woven fibers are used, for example prepreg with a 45 degree angle between the fibers. These are slightly stiffer and can generally result in fewer layers than what appears in the table above. Depending on the thickness of a layer as supplied by the manufacturer, the above number of layers can be in the different stocks, may need to be increased, maintained or decreased.

Examples of different layers in the sole are shown in Fig. 10 and in Table 1. Here it is possible it is seen that layers number 2 and 5 are common to all zones of the sole, FP, TP, MP and RP, and thereby a continuous sole is obtained. Furthermore, the that the bearings may be partially overlapping as indicated in Figure 10, i.e. some layers continue partially into the adjacent sole portion, thereby giving one more gradual change in the flexibility of the sole.

AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 14 The ski binding 30 will now be described with reference to Figs. Figures 4a-b, Figures 5a-b and Figure 6. The ski binding 30 comprises a base plate 31. The base plate 31 is attached to the upper surface of the ski in a manner that is known to a person skilled in the art. The base plate has studs that increase friction one between the base plate 31 and the wear layer 13 of rubber or similar material.

The ski binding 30 comprises a locking mechanism 35 which is attached to the base plate 31. The locking mechanism 35 of the base plate is arranged in front of the base plate 31.

The ski binding 30 further comprises a guide channel 22 which has one complementary shape in relation to the platform of the ski binding attachment 20 sole tip 21 on the front of the ski boot sole. The control channel 22 is limited by one front wall 24 and the two side walls 33, all of which protrude from the base plate. The guide channel 22 forms an area on the base plate 31 between the front the wall 24 and the side walls 33 to the end of the bond 30 during skiing the boot sole 12 and may have a friction pattern or a friction surface.

The ski binding 30 further comprises two grooves 32 in the guide channel side walls 33. The guide channel 22 has a shape which makes it suitable to take against the extension 15 in the front part of the ski binding bracket 20 in the sole 12.

The ski binding 30 further comprises a ski boot bracket 40. The ski boot bracket The clamp 40 comprises a clamping arm 41 and a clamping bolt 27. This is rotatable and connected to the base plate 31. The ski boot bracket 40 can be cast / manufactured as a part.

In an open position, the locking plate 25 will tilt forward, pulling the lever the rod arm 26 which in turn is attached to the clamping arm 41, and which opens the clamping bar 27. The lever arm 26 is attached between the clamping arm 41 and the locking plate. tan 25. The clamping arm 41 and the locking plate 25 are attached at two pivot points independently of each other on the base plate 31. In the open position it comes platformed the sole tip 21 on a flexible ski boot sole 12 with associated extension 15 to can be inserted into the guide channel 22, and the ends of the extension 15 to be inserted down into the grooves 32 in the side walls 33 of the base plate 31 with the result that the extension 15 is inserted into the same groove 32 as the clamping bolt 27 is then used for locking and closing the ski binding bracket 20 at the ski binding 30.

AH p4503seO0 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 15 The clamping arm 41 may have spanner slots 28 in which a spacer paragraph can be placed, which at the end of the kick-off will be squeezed between the front part of the upper part 11 of the boot and the keyway 28 for individual adjustment of the boot's return point after completion of the kick-off. Di- the punch is elongated in shape and can at most be the same length as the distance between the two side walls 33.

Figure 6 illustrates the binding of the ski boot sole 12. It can be seen that the side the walls 33 with a side stabilizing effect, the sole 12 and the ski binding The mounting bracket 20 fits in the indicated channel 22 and the groove 32 on the ski the bond 30. It should be noted that the side walls 33 in fig. 6 are provided in front of the toe part TP on the sole (ie when the sole 12 is attached to the binding 30).

Nevertheless, it is conceivable that the side walls may extend slightly on the side of the ski boot, although not so far into the toe part TP of the ski boot sole 12 that the side walls 33 end on the outside of the toes (i.e. the outside of the big toe respective little toe on each side of the foot) on a person wearing the ski boot.

The base plate 31 has side walls 33 of sufficient height to prevent lateral movement of the sole / boot during the execution of a kick-off, and thereby provide good control of the ski. In the folded position, the locking plate is tan 25 built into the binding which ensures that objects can not hit or open the lock, or prevent snow from entering the binding mechanism.

The clamping bolt 27 will be built into a groove 32, and thus provided keep transverse movements. The clamping rule 27 may be constructed with same diameter as the extension 15 as illustrated in Figure 8a.

In the closed configuration, the clamping bolt 27 will be locked so that it cannot be opened. The locking plate 25 for the binding will be located in the leading edge of the bond and preferably be centered, but this is not necessary. The locking plate 25 will generally be made of metal, aluminum nium, plastic material, carbon fiber, fiberglass, long fiberglass, thermoplastic, polymer, POM, PEM, PET, polyamides, polyamide composites, semi-aromatic materials, plastic fiber, rubber or composite material. When closed, the locking plate comes AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 16 To preferably be built into the bond but not necessarily. Ju the greater the force applied to the clamping bar 25, the more the bond is locked.

The base plate 31 of the ski binding comprises a base as well as a housing 34 for the bond which secures and protects internal components. Base plate 31 will typically be glued directly to the ski, mounted directly on a ski with 4-5 screws and screw holes or fixed to a plate which is glued or attached otherwise on the ski. The base plate 31 can be made of metal, preferably a light metal such as aluminum, strong and lightweight plastic materials, carbon fiber and fiberglass, long fiberglass, thermoplastics, polymer, POM, PEM, PET, polyamide polyamide composite, semi-aromatic materials, plastic fiber, rubber or composite materials which can withstand cold and abrasion. The materials in the binding need normally have a tensile strength up to 300 MPa and a stiffness up to 30,000 MPa. The components of the binding can be shaped or manufactured in one piece. Clamping the latch 27, the clamping arm 41 and the locking plate 25 will as a rule be made of plastic materials, carbon fiber, fiberglass, long fiberglass, thermoplastic, polymer, POM, PEM, PET, polyamides, polyamide composites, semi-aromatic materials, plastic fibers, rubber or composite material.

Between the locking plate 25 and the clamping arm 41 comes a lever arm 26 to be arranged to transmit force between the locking plate 25 and the clamping arm 41. The lever arm 26 may have a curvature which ensures locking of the extension 15. The lever arm can be made of the same material as the base plate 31, but also of metal.

The rotatable connection points between the lever arm 26 and the locking plate 25 and the clamping arm 41 are connected via shaft holes through which, for example, metallic scissor pins pass to ensure that they remain in correct position. Other methods that may be relevant for a connection between these parts, such as clamping couplings or click-couplings between them which will be known to one skilled in the art.

Figure 7 shows that the bond 30 will also include a half-straight ion layer 16 across the ski. The heel friction bearing 16 supports the heel 12 of the sole 14. The heel the friction bearing 16 will create friction between the sheath 2 and the rubber bearing AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 17 13 and the fiber layer 12, and helps to keep the boot stable laterally. Hälfrikt- ion storage 16 may be available in several different versions to satisfy the individual wishes. The height variations in the heel friction bearing 16 can be between 0.1 mm and 0.5 cm.

The full friction bearing may or may not be separate from the base plate 31 the base plate cover the entire ski from the front 31 to the heel portion. Under the foot, ie. in toe part TP and / or metatarsal part MP, the base plate may be wider than the ski, eg stick out 0.2-3 cm on each side of the ski with the intention of improving downhill stability.

The movement of the sole 12 relative to the ski binding 30 is illustrated in Figs. 8a-8d there the toes touch the base plate in each part of the kick-off process.

As illustrated in fig. 8d, is lifted during the initial phase of ken the rear part RP from the binding 30 and the ski, while it most of the metatarsal part and the whole toe part TP and the whole front part FP of the sole is in contact with the binding 30. This movement is achieved due to the flexibility of the metatarsal part MP.

In a subsequent part of the kick-off, as illustrated in fig. 8c, lifted the rear part RP further. Here, all or most of the meta- tarsal part MP from the base plate 3, but the toes are in contact with the ski and presses against the surface. This movement is achieved due to the flexibility of the tarsal part MP and toe part TP.

In the final part of the kick-off, as illustrated in Fig. 8d, lift the whole metatarsal part MP and the whole greater part of the toe part TP from base plate 31. This movement is achieved due to the flexibility of the tarsal part MP and toe part TP, and also due to the bond 30, ef- as it presses the ski boot sole down into the leading edge of the upper part 11 of the boot.

In Fig. 8d it should be noted that the distance from the bottom of the toe in the upper of the boot part 11 to the base plate 31 has not increased, or has increased less than in the sole in accordance with prior art as illustrated in FIG. 1a-d, since the sole is in the toe area is firmly clamped to the binding.

AH p4503se00 2014-01-27 pans se över.doc 14-02-05 ver. 182 10 15 20 25 18 lfig. 8b-8d illustrate a dot in the sole. This dot indicates pressure the point or the rearmost part of the sole which is in contact with the binding during the execution of a kick-off. It is clear that this pressure point is moving continuously on the ski from the posterior part of the metatarsal part TP whole the way forward to the front part of the toe part TP during the execution of a kick.

We now refer to Fig. 9 and here it can be seen that the flexibility of the sole 12 longitudinal direction is relatively low (ie the modulus of elasticity is high) for the front the part FP and the rear part RP, while the flexibility of the sole 12 longitudinal direction of is relatively high (ie the modulus of elasticity is low) for toe part TP and metatarsal part MP.

We now refer to Fig. 8c which illustrates other properties of the ski the bond. The ski binding 30 may have a molded friction pattern 29 in base plate 31. This friction pattern 29 can either be formed in the base plate. 31 or be a friction pattern layer which is glued or fixed to the base plate 31. A friction pattern 16 with studs may also be provided the heel.

We refer to Fig. 10 which illustrates fiber orientation and fiber layers in sulan 12.

We refer to Fig. 11 which shows the pointer bracket between the extension 15 and ski boot sole 12. The extension 15 is covered by the ski boot sole 12 and glued or fused together so that the extension 15 is formed in the ski The sole 0. Woven fabric 17 can be attached to the bottom of the sole tip around the extension. 15 and to the top of the sole 12. Woven fabric that wraps around the front of the sole may be liquid crystal polymer, aromatic polyester, aramids, Kevlar, carbon fiber, synthetic fiber, polyester fabric covered with thermoplastic polyurethane retan / PVC or another woven textile which is wrapped in plastic material.

Alternative solutions AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 19 In the description above, a carbon extension 34 is shown in front of the ski binding. This extension 34 can be made, for example, of carbon fibers, nano carbon fibers. plastic, metal, polymer, POM, PEM, PET, Teflon or composite materials.

Figs. 12a-12b illustrate another solution for a bond with clamp order in an open and a closed position. The control channel 22 which fits together mans with the platformed sole tip 21 stands out clearly in the diagram.

Fig. 13 shows a more complex solution for the clamping device which can opens and closes with the help of a ski pole.

Fig. 14 shows an open and closed mechanism for a clamping bolt 27 on a ski binding in which is intended to be regulated by means of a ski pole for opening and closing the mechanism.

Referring to Figures 15a-b and 16a-b, a ski binding is shown with a locking device 42 comprising a transverse arm 44 and two side mar 43 attached to each end of the transverse arm 44. The side arms 43 is rotatably attached to the ski binding 30, the entire locking device being rotatable in relation to the base plate 31. Figures 15a and 16a show the locking device 42 in an open position while Figures 15b and 16b show the locking device 43 in a position where a ski boot will be firmly locked at the ski binding (the ski boot is not shown in the figures).

The locking device 42 further comprises one or more cam elements 46 which will rotate together with the side arms 43 when the locking device 42 is turned by a user. The cam elements 46 are mounted under one end of the rotatable clamping arm 41 with the result that when the locking device 42 is rotated in the direction of rotation R as indicated in Fig. 16a, the camel element will 46 to flatten the clamping arm so that the opposite end of the clamping arm 41 rule 27 is clamped down against the front part FP on a ski boot sole (not shown) which is arranged in the ski binding 30, and will thereby hold the ski boot sole in place in the ski binding 30. When the locking device 42 is placed row in the locking position, the transverse arm will preferably be arranged in a groove 45 in the clamping arm 41, as shown in the figures. In locking devices locking position 42, the cam member 46 is preferably rotated past the AH p4503se00 2014-01-27 pans se över.doc 14-02-05 ver. 182 10 15 20 25 20 the weight position (ie the vertical position), so that if an attempt is made to flick up the clamping arm 41, and thereby the clamping bolt 27, when the locking device 42 is used arranged in the locking position, the force comes from the clamping arm 41 on the cam element 46 to try to turn the cam member 46 and thus the locking device 42, further in the direction of rotation R, i.e. the transverse arm 44 squeezes even more or harder on the clamping arm 41, and consequently the clamping bolt 27 clamps on the ski boot sole which is firmly locked in the ski binding 30.

As can be seen in the figures above, the ski boot sole 12 can be attached to the ski the binding 30 by means of the clamping rule 27 which clamps the ski boot sole flattened sole tip 21 against the base plate 31. In order to attach the ski boot ski boot sole 12 more firmly in the ski binding 30, the ski boot sole 12 can also in addition to being provided with an extension 15 extending across the plate shaped the tip of the sole and extends forward so that the extension 15 fits into grooves 32 in the side walls 32 of the ski binding 30. The clamping bolt 27 fits in the grooves clean 32 and thereby clamps the flat sole tip extension 15 against the base plate 31.

LIST OF REFERENCE FIGURES 2 skis 10 ski boots 11 upper part of the boot 12 ski boot sole 13 wear bearings / rubber bearings 14 heel area 15 extension 16 heel friction patterns 17 woven textiles 20 ski binding bracket AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 21 21 platform sole sole 22 strength channel 24 front wall 25 làsplatta 26 lever arm 27 clamping rule 28 key tracks 29 bond friction pattern 30 ski binding 31 base plate 32 grooves in side walls 33 side walls 34 houses for bonding Locking mechanism 40 ski boot mount 41 clamping arm 42 locking device 43 side arm 44 transverse arm 45 tracks 46 camel element 50 saxprint FP front part of the boot RP rear part of the boot R at the back of the boot AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 22 F the tip of the ski boot sole 12 TP tàdelen MP metatarsal area x-direction longitudinal direction y-direction transverse direction AH p4503seO0 2014-01-27 pans se över.doc 14-02-05 ver. 182

Claims (30)

10 15 20 25 30 1. A patent ski sole (12) with a longitudinal direction (x-direction) and a transverse direction (y-direction) and comprising a toe part (TP), a metatarsal part (MP), adjacent to the toe part and a rear part (RP) extending from the metatarsal alveolar (MP) to a rear end (R) of the ski boot sole (12), which ski boot sole (12) comprises at least one fiber layer, thereby enabling the ski boot sole (12) to have different degrees of rigidity in the different parts (TP, MR, RP) of the ski boot sole (12) in the longitudinal direction and / or the transverse direction where the metatarsal part (MP) is flexurally soft in the longitudinal direction, flexurally rigid in the transverse direction and torsionally rigid around an axis in longitudinal direction; the toe portion (TP) is flexurally soft in the longitudinal direction, flexurally rigid in the transverse direction and torsionally rigid about an axis in the longitudinal direction; the front part (FP) is flexurally soft in the longitudinal direction, flexurally rigid in the transverse direction and torsionally rigid about an axis in the longitudinal direction; which ski boot sole (12) further comprises a front part (FP) extending from the toe part (TP) in the longitudinal direction to the front (F) of the ski boot sole (12), which front part (FP) comprises a flat sole tip (21) with an extension ( 15) and a shape which is complementary to a guide channel (22) in a ski binding (30) which comprises a clamping bar (27) which enables the ski boot sole (12) to be attached to the ski binding (30) by means of the flat sole tip (30) is firmly clamped in the ski binding (30) by means of the clamping bar (27). A ski boot sole according to claim 1, wherein the extension (15) is provided with a transverse element extending in the transverse direction of a ski boot sole (12). AH p4503se00 2014-01-27 pans se över.doc 14-02-05 ver. 182 10 15 20 25 30 24. A ski boot sole according to any one of claims 1-2, wherein the extension (15) is mounted in the front part of the platform-soled tip (21). . A ski boot sole according to one of claims 1-3, wherein the extension (15) has a thickness which is between 200% to 800% thicker than the ski boot sole (12). A ski boot sole in accordance with one of claims 1-4, wherein the ski boot sole (12) goes around or wraps the extension (15). . A ski boot sole according to any one of claims 1-5, wherein a cloth or woven fabric (17) wraps the extension (15) and the fiber sole (12). . A ski boot sole according to any one of claims 1-6, wherein the ski boot sole (12) comprises a wear layer (13) which has a modulus of elasticity which is in the range of 10 MPa to 200 MPa. . A ski boot sole according to any one of claims 1-7, wherein the width (W20) of the ski binding bracket (20) is less than the width of a standard width ski track. . A ski boot sole according to any one of claims 1-8, wherein the fiber layers in the ski boot sole (12) comprise at least one carbon fiber layer and / or at least one fiberglass layer. A ski boot sole according to claim 9, wherein the at least one carbon fiber layer has a modulus of elasticity which is in the range of 20 GPa to 190 GPa. AH p4503se00 2014-01-27 pans se oversdoc 14-02-05 ver. 182 10 15 20 25 30 25 A ski boot sole according to claim 9, wherein the at least one fiberglass layer has a modulus of elasticity which is in the range of 60 GPa to 80 GPa. A ski boot sole according to any one of claims 1-11, wherein the rear part (RP) is flexurally rigid in the longitudinal direction, flexurally rigid in the transverse direction and torsionally rigid around a shaft in the longitudinal direction. A ski boot sole according to any one of claims 1-12, wherein the ski boot sole (12) comprises a heel area (14) which has a friction pattern either molded in or glued. A ski boot sole according to any one of claims 1-13, wherein the ski boot sole (12) is defined as flexurally rigid when a force of 12 N causes a deflection of 20 mm and when a force of 120 N causes a deflection of 85 mm, and where the ski boot sole (12) is defined as torsionally rigid when a torque of 1 Nm around an axis in the longitudinal direction causes a rotation angle of 5 degrees and when a torque of 20 Nm around an axis in the longitudinal direction causes a rotation angle of 20 degrees, where the force is applied 140 mm from a clamping point and the resulting deflection is measured 140 mm from the clamping point and the torque is applied 140 mm from the clamping point and the resulting turning angle is measured 140 mm from the clamping point. A ski boot sole according to any one of claims 1-14, wherein the ski boot sole (12) is defined as flexurally soft when a force of 1 N causes a deflection of 20 mm and when a force of 32 N causes a deflection of 185 mm, and where the ski boot sole (12) is defined as torsionally soft when a torque of 0.4 Nm around an axis in the longitudinal direction causes a rotation angle of 5 degrees and when a torque of 10 AH p4503se00 2014-01-27 pans see oversdoc 14-02- 05 ver. 182 10 15 20 25 30 26 Nm around an axis in the longitudinal direction causes a rotation angle of 40 degrees, where the force is applied 140 mm from a clamping point and the resulting deflection is measured 140 mm from the clamping point and the torque is applied 140 mm from the clamping point and the resulting rotation angle measured 140 mm from the clamping point. A ski binding (30) comprising: - a base plate (31) with side walls (33) forming a guide channel (22), which guide channel (22) has a complementary shape to a flat-shaped sole tip (21) on a ski boot sole (12). ); - a locking mechanism (35) which is attached to the base plate (31), which locking mechanism (35) comprises a clamping bolt (27) which is arranged to lock the flat sole tip (21) comprising an extension (15), in the ski binding ( 30) in that the clamping bolt (27) clamps the flat sole tip (21) against the base plate (31). A ski binding (30) according to claim 16, wherein the side walls (33) comprise transverse grooves (32), which grooves (32) are arranged to receive the extension (15) on the ski boot sole (12) and the clamping bolt (27). . A ski binding (30) according to any one of claims 16-17, wherein the ski binding (30) comprises a ski boot attachment unit (40) comprising the clamping bolt (27) which is hingedly mounted to the base plate (31) and a clamping arm ( 41), where the clamping arm (41) is arranged to lock the clamping bolt (27), the extension (15) of the ski boot sole (12) being locked in the grooves (32). A ski binding (30) according to claim 18, wherein the clamping arm (41) communicates with a lever arm (26) which in turn is attached to the locking plate (25) for locking and closing by means of the locking mechanism AH p4503se00 2014 -01-27 pans see over.doc 14-02-05 ver. 182 10 15 20 25 30 27 (35). A ski binding (30) according to any one of claims 16-19, wherein the ski binding (30) in addition to side walls (33) also comprises a front wall (24) which extends upwards from the base plate (31). A ski binding (30) according to any one of claims 16-20, wherein the guide channel (22) is arranged in the base plate (31). A ski binding (30) according to any one of claims 16-20, wherein the guide channel (22) is attached to the base plate (31) and arranged in front of a toe part (TP) of a ski boot sole (12) which is arranged in the ski binding ( 30). A ski binding (30) according to any one of claims 16-22, wherein the clamping bolt (27) is arranged to wrap the extension (15) of the ski boot sole (12) when the extension (15) is placed in the grooves ( 32) in the side walls of the binding. A ski binding (30) according to any one of claims 16-23, wherein the ski boot attachment unit (40) is arranged against the grooves (32) when a locking plate (25) is lowered. A ski binding (30) according to any one of claims 16-24 wherein the locking mechanism (35) is arranged in front of the base plate (31). A ski binding (30) according to any one of claims 16-25 wherein the base plate (31) is provided with a friction bearing (29) and wherein a heel area (14) comprises a heel friction pattern (16). A ski binding (30) according to one of claims 16-26, wherein the locking mechanism (35) and the guide channel (22) are arranged in front of a toe part (TP) AH p4503se00 2014-01-27 pans see over.doc 14 -02-05 ver. 182 10 15 20 25 32. 28 of the ski boot sole (12) which is arranged in the ski binding. A ski binding (30) according to any one of claims 16-27, wherein the transverse groove (32) is arranged in the front part of the binding (30). A ski binding (30) according to any one of claims 16-28, wherein the material in the ski binding (30) has a tensile strength of 300 MPa or less if the material in the ski binding is a reinforced solid material, and 500 MPa or less if the material in the ski binding is a metal, and where the material in the ski binding (30) has a stiffness of 30 GPa or less if the material in the ski binding is a reinforced plastic material and 50 GPa or less if the material in the ski binding is metal. A system comprising a ski boot (10) with a ski boot sole (12) according to any one of claims 1-15 and a ski binding (30) according to any one of claims 16-28, the extension (15) and the clamping bar (15). 27) fits in the latch (32), and where a locking mechanism (35) ensures that the extension (15) in front of the sole tip (21) is clamped against the base plate (31). Use of at least one fiber layer in a ski boot sole (12) comprising a front part (FP), a toe part (TP), a metatersal part (MP) and a rear part (RP) to provide the desired rigidity in the ski boot sole parts. (FP, TP, MP, RP) in the longitudinal direction of the ski boot sole (12) and the transverse direction of the ski boot sole (12). The use according to claim 31, wherein at least one fiber layer is a carbon fiber layer and / or a glass fiber layer. AH p4503se00 2014-01-27 pans se över.doc 14-02-05 ver. 182