EP2708150A1 - Sports shoe, in particular ski boot - Google Patents

Abstract

The sports shoe has a two reinforcing elements (17), which extend on both sides of a sagittal plane of the sports shoe along a shaft portion (35), and are joined to a foot shell (15) in an ankle area with a joint (21). A deflection movement of the reinforcing elements is realized at the joint. The reinforcing elements are formed as one-piece and have one end oriented above the joint and another end oriented below the joint. The reinforcing elements are reinforced with fibers, particularly with carbon fibers, aramid fibers or glass fibers.

Description

Field of the invention

The invention relates to a sports shoe according to the preamble of claim 1 and a sports shoe according to the preamble of claim 17.

State of the art

The ski boots used today by skiers consist of a hard outer boot and a soft and insulating inner boot, which holds the skier's foot. The outer shoe generally has a rigid plastic shell made of a shell body and a ski boot shaft. The ski boot shaft is articulated in the ankle area to the shell base body and allows a certain mobility between the shell base body and the ski boot shaft. The ski boot shaft typically has one or two flexible tongues on which are secured clasps or tooth elements which can cooperate with buckles attached to the shaft outer surface to reduce the ski boot shaft diameter to fit the lower leg circumference of the shoe wearer and provide good leg support can.

The shell main body consists of a sole, which is generally integral with a ski boot shell The sole has front and rear standardized locking extensions for snapping into the jaws of a conventional safety binding. The sole is smooth in the toe area according to the DIN ISO standard, in order to enable a lateral release of the ski binding. The upper part of the ski boot usually has two overlapping flexible tongues on which cooperating closure devices are provided in order to be able to contract the tongues differently , Usually, the closure devices are formed by one to three buckles, which are arranged at a distance from each other on the Schischuhrücken, wherein the number of buckles used depends on the respective construction and the external appearance.

While the described alpine ski boot is closed as a front entrant with buckles, there were many models in the 80s and 90s, which should offer more comfort as a rear beginner. In these models, the rear shaft area could be folded from the heel to facilitate entry and exit. These shoes sometimes came with only one buckle on the shaft end. The system of the Heckeinsteigers has not been able to prevail in practice and remained a fad of these years, so that the buckle shoe with front entry is now dominant again.

In a sporty driving style, the power must be transmitted as directly as possible to the ski or the snowboard. In this regard, the resilience of the ski boot shaft relative to the rest of the shell plays a crucial role. The resistance (stiffness) of the ski boot shaft forward is specified by the statement of the so-called "Flex". The harder the flex (= higher flex number), the stiffer / immobile the shaft shell is. A stiffer shaft shell has the advantage that it provides the user with a bit more grip, but also limits the freedom of movement of the ankle. It is therefore important that the flex is neither too hard nor too soft because the build-up of pressure mainly results from weight transfer skier's own weight plays a (co-) decisive role in choosing the appropriate flex. On the one hand, the Flex should provide enough resistance to transmit control impulses (such as blade pressure) to the ski, but it must not interfere with the natural movement of the ankle. It should be added that the "flex" is not a standardized size, so that comparability is only within the shoe program of a single manufacturer. It should also be noted that the flex varies greatly due to temperature fluctuations

There are shoe manufacturers who offer shells that differ in the degrees of hardness of the ski boot shaft. While professional athletes prefer extremely hard shoes, a mediocre flex is recommended for the occasional rider.

In addition to hardness, the weight of the ski shoe also plays a major role for the user. Commercially available shells usually have a weight of about 2 kg. A weight reduction would be desirable in principle, but the shell must have a minimum wall thickness so that the pressure to be exerted by the skier on the ski as directly as possible can be introduced into the ski. Since the Schischuhschaft (shaft shell) is articulated usually in the ankle area on the shell body, the upper part of the ski boot must be made of a relatively tough, durable hard plastic, so that a forward inclined ski boot shaft can transfer the power via ski boot shell on the sole.

The EP-A-1 462 019 discloses a sports shoe for a gliding board, such as ski, snowboard or ice skate, comprising a first part of a molded synthetic resin material and a second part, also of a molded synthetic resin material superimposed on the first part. In addition, reinforcement means in the form of a reinforcement are provided which are at least partially disposed between the mentioned first and second parts. The reinforcing means may be made of plastic reinforced with mineral or synthetic fibers. Concretely, the shoe has a shell forming a rigid core which is surrounded by a reinforcement on both sides of the ankle area. The rigid core provided with the reinforcement is covered with a flexible shell

French patent no. 2,928,523 discloses a ski boot with a shell body to which a collar is hinged The shell body has formed on the back of a manhole for a foot. The shell and the collar each consist of a plurality of superimposed layers of a bidirectional composite material. Incidentally, said ski boot is characterized in that a reinforcing band of a composite material formed of threads is provided around the access opening

In the WO 92/16120 is a ski boot with a sole plate, a shell and a above the ankle fixed to the lower leg support disclosed The support is connected via a yoke to the sole plate. The support is designed as a sleeve, which is connected via a bracket with the yoke. The yoke is integrally provided with the bracket at its upper end. The temple covers about half the leg circumference. The yoke each has two arms arms whose lower ends are firmly connected to the rear sole plate area. The support is anatomically and individually adaptable. However, the damping of the bracket or the arms relative to the sleeve is elaborately constructed by arranged within the bracket elastomers

In the FR 2 653 310 discloses a plastic ski boot with a shell, a front cuff and a rear cuff, both hinged to the shell. Two rigid U-shaped stirrups are hinged to the shell The first stirrup supports the front cuff, the second stirrup supports the rear cuff. The two lateral legs of each U-shaped bracket, which are oriented in a direction parallel to the tibia, are hinged to the shell at one of its ends. At the other end, the legs are each connected by a rigid connection in the form of a U-channel which comprises a part of the lower leg, at the front and at the back. The construction is complex and the ski boot is not very comfortable because both cuffs and both U-shaped brackets must be hinged to the shell.

Object of the invention

It is an object of the present invention to provide a sports shoe, in particular a ski boot, which has sufficient rigidity and nevertheless allows a comfortable entry or exit. Another object is to show a sports shoe, which is characterized by a particularly low weight Yet another goal is to show a sports shoe, especially ski boot, whose flex is substantially independent of temperature and whose flex is realized by simple structural means

description

According to the invention the object is achieved in a sports shoe according to the preamble of claim 1, characterized in that the first and second reinforcing element are integral and each having a first free end, which is oriented to the upper edge of the shaft portion above the joint and have a second end below the joint, which second end is movable along the foot shell or the sole in the direction of the deflection movement, whereby the stabilizing function of the shaft part is transmitted to the reinforcing elements. The reinforcing elements enable the shaft shell of a ski boot of the prior art to be inserted through Component is replaced, which provides sufficient stability with the lowest possible weight and dimensions By providing the second end of the athlete's foot is enclosed and sta-bilized on both ankle sides from top to bottom in the sports shoe. Due to the small dimensions, the outside temperature has almost no influence on the material rigidity of the reinforcing elements. The flex of the sports shoe according to the invention is therefore essentially unaffected by the outside temperature. In the context of this document, an articulation in the area of the ankle should be understood to mean a radius of less than 5 cm, preferably less than 3 cm and particularly preferably less than 2 cm about the ankle axis. A greater distance of articulation to the ankle joint makes no sense, since the ankle of the athlete's shoe user is otherwise hampered in its mobility by the arrangement of the reinforcing elements on both sides of the sagittal plane remains the shank part of the ski boot at its front and rear free of reinforcing elements. The entry and exit in the ski boot is therefore particularly comfortable. The reinforcing elements allow a simplified construction of the ski boot, since no further supports or shells for stabilizing the foot are needed on the joint. Also, no complicated damper designs or Auslenkbegrenzer necessary because the reinforcing elements can strike with their second ends directly to the foot shell or the sole. The reinforcing elements therefore act like a rocker which can rock with the first and second end along the deflection movement. The reinforcing elements can be connected to the joint within or outside the foot shell with the same gelen-kig.

Conveniently, the two reinforcing elements have a greater rigidity than the shaft part. The shank part can accordingly be designed to be light and comfortable for the ski boot wearer, since it has little or no stabilizing function to assume. Also, the shank part, since it takes little or no stabilizing function, be free of a connection or articulation with the foot shell over the joint. Although the foot shell is conveniently made of a hard plastic, it may have a smaller wall thickness than foot shells of the prior art because of the high strength and stability of the reinforcing elements. In the area of the articulated connection of the reinforcing elements However, the wall thickness must be adapted to the load introduced by the reinforcing elements and have a corresponding wall thickness. The rigidity of the reinforcing elements therefore leads to a significantly reduced weight of the inventive ski boot in comparison with conventional ski boots.

In a preferred embodiment, the shaft part consists of a waterproof textile. Since the stability and strength of the shaft shell is completely taken over by the reinforcing elements, the shaft part no longer requires compressive strength. The task of the sheep part is therefore only to protect the foot from snow, moisture and cold. Neoprene with a corresponding wall thickness, for example, is very well suited to fulfill these tasks. Instead of a textile, leather would be conceivable, as it is waterproof, durable and easy to care for.

It proves to be advantageous if the reinforcing elements are reinforcing struts. The reinforcing struts can have a rectangular shape, require minimal space and support the foot at the side of the ankle, exactly where the foot needs support during skiing

Advantageously, a reinforcing strut has a first open end which is oriented to the upper edge of the shaft part and has a second end, on which a projection for supporting against the foot shell is arranged. The protrusion allows the reinforcing strut to be limited in its displacement relative to the foot shell and the ankle is not overloaded. As a projection, all elevations are conceivable, which can be the reinforcing element reliably strike the foot shell, without the reinforcing element or the foot shell would be damaged.

Conveniently, the movability of the two reinforcement struts is limited to an angular range relative to the foot shell to provide a typical ski boot flex.

The fact that the second end of the reinforcing struts are movable between a first and second end stop of the foot shell, which is necessary for a ski boot flex by simple design features realized without additional components would be necessary in addition to the reinforcing elements and the end stops. The reinforcing struts can be hinged to the inner or the outer wall of the foot shell in the ankle area. Accordingly, the sole must be formed: If the reinforcing elements are arranged outside, then it is expedient if a depression is provided on the underside of the sole, whose front and rear end serves as the first and second end stops are arranged inside the reinforcing elements, it is expedient if at the top of the sole a recess is provided, whose front and rear end serves as a first and second end stop It is also conceivable that the reinforcing struts strike at other attachment points of the foot shell. These may be elevations on the foot shell which are integral or formed by additional parts, such as pins. The elevations limit the deflection movement of the reinforcing struts.

In a particularly preferred embodiment, elastic elements are provided between the second ends of the reinforcing struts and the end stops. The elastic elements enable the stops of the reinforcing elements on the sole to be damped. The elastic elements may be interchangeable fixable to the sole. This allows softer or harder elastic members to be used and the flex is adaptable to user requirements. It is also conceivable that the exchangeable elastic elements have different widths. Thereby, the distance between the first and second end stop and the reinforcing elements can be changed, whereby the angular range can be increased or decreased. The replacement of the elastic elements therefore makes it possible to customize the ski boot according to the invention in accordance with the user requirements for the flex. Are conceivable as elastic elements elastomers but also spring elements or spring leaves.

In a further preferred embodiment, the first and second reinforcing struts are connected at their second ends by means of a leg, so that a one-piece U-shaped reinforcing element is formed. The U-shaped reinforcing element has the advantage that the leg serves as a projection, which on the End-strokes of the sole strikes. The fact that the U-shaped reinforcing element is integrally formed, it is particularly stable and suitable to absorb the compressive and tensile loads caused by weight shift of the user but also by off-road strikes on the ski. The U-shaped reinforcing element encloses the user's lower leg and foot like a basket and acts as a splint.

For secure connection of the reinforcing elements to the user's lower leg, a cuff adjustable in width is provided at the free ends of the reinforcing struts. The movements of the lower leg relative to the foot of the user can therefore be transmitted directly to the reinforcing elements. To adjust the width of the cuff Velcro is useful. But it can also be used other forms of closure, such as a buckle.

Advantageously, the rear part of the cuff facing away from the toe is designed as a rail for stabilizing the lower leg of the user. The rail is preferably of semicircular shape so that it is adapted to the curvature of the calf of the user. If the skier is supine, he is supported by the rail and does not fall back. It is also conceivable that the part of the cuff facing the toe is designed as a rail in order to support the shin of the user particularly well.

Conveniently, the reinforcing elements are reinforced with fibers, in particular with carbon fibers, aramid or glass fibers. The reinforcing element is preferably a plastic matrix in which the aforementioned fibers are embedded. The reinforcing element therefore has a high weight-specific strength. It is conceivable that the reinforcing elements are surrounded for their protection with a plastic jacket. For this purpose, the reinforcing struts can be encapsulated with a suitable plastic.

In yet another preferred embodiment, the athletic shoe comprises an insole disposed on a first abutment in the sole region and a second abutment in the toe region so as to form a space between the insole and the sole. This arrangement allows the insole to be sandwiched between the abutments. and can rebound. This "trampoline effect" has a positive effect on the momentum when skiing. In particular, in difficult terrain, in which a swing release is facilitated by jumping movements, the insole has a positive effect.

Advantageously, the first support serves as the first end stop for the reinforcing struts. As a result, the support fulfills two tasks and it is possible to dispense with other components.

Conveniently, the first support is formed as a heel of the insole. This has the advantage that the first support with the insole can be removed and good access to the end stop is present, for example, to exchange the elastic element.

It proves to be advantageous if the insole is made of an elastically resilient material, in particular of a wooden board. Wood has a good compromise between strength and resilient properties and can be adapted to the desired elastic properties through several layers and different thicknesses.

A further aspect of the invention relates to a sports shoe according to the preamble of claim 17, which according to the invention comprises an insole which is arranged on a first support in the sole region and a second support in the toe region, so that a gap between the insole and the sole is formed The insole leaves engage in any sports shoe, especially ski boot, the state of the art or retrofit. The effect of the insole has already been stated above

Due to the fact that the first support is designed as a heel of the insole, the foot shell does not require a first support for the insole.

Figur 1:

eine axonometrische Ansicht eines Verstärkungselements;

Figur 2:

eine Seitenansicht einer ersten Ausführungsform eines Skischuhs, bei welcher die Verstärkungselemente aussen an der Fussschale angeordnet sind;

Figur 3:

eine Seitenansicht einer zweiten Ausführungsform eines Skischuhs, bei welcher die Verstärkungselemente innen an der Fussschale angeordnet sind und von einem textilen Schaftteil umgeben sind;

Figur 4:

eine Seitenansicht einer Einlegesohle;

Figur 5:

eine Unteransicht der Einlegesohle aus Figur 4 und

Figur 6:

einen Schnitt durch einen erfindungsgemässen Skischuh mit Verstärkungselement und eingelegter Einlegesohle.

Further advantages and features will become apparent from the following description of an embodiment of the invention with reference to the schematic representations. It shows in not to scale representation:

FIG. 1:

an axonometric view of a reinforcing element;

FIG. 2:

a side view of a first embodiment of a ski boot, wherein the reinforcing elements are arranged externally on the foot shell;

FIG. 3:

a side view of a second embodiment of a ski boot, in which the reinforcing elements are arranged on the inside of the foot shell and are surrounded by a textile shaft part;

FIG. 4:

a side view of an insole;

FIG. 5:

a bottom view of the insole FIG. 4 and

FIG. 6:

a section through an inventive ski boot with reinforcing element and inlaid insole.

The invention relates to a sports shoe for fixing to a gliding board, in particular a ski boot 11, as in the Figures 2 . 3 and 6 is shown. The ski boot 11 comprises a sole 13 and a foot shell 15, which is firmly connected to the sole. Preferably sole 13 and foot shell 15 are integrally formed

In ski boots of the prior art, a shaft shell is hinged to the foot pan 15 to stabilize the user's foot. As an orientation aid, a sagittal plane of the ski boot has been inserted at this point, which extends from the ski boot tip to the heel area of the ski boot along the midline of the ski boot. The foot shell is pivotally connected on both sides of the sagittal plane by means of a joint in the ankle area to the foot shell with the same. In order to circumvent this inflexible and chunky way of foot fixation, in particular the tedious entry into a ski boot of the prior art, the inventive ski boot 11 comprises a reinforcing element preferably in the form of a one-piece U-shaped reinforcing element 17. The U-shaped reinforcing element 17 has two reinforcing struts 18 a, 18 b, which are connected to one another by a leg 20. The U-shaped reinforcing element 17 is as small and lightweight as possible component, which nevertheless has sufficient stability in order to adequately fix the foot of a user in the ski boot 11. The reinforcing element 17 is therefore formed from a matrix structure in which carbon, aramid or glass fibers are embedded in a plastic matrix. FIG. 1 shows that the reinforcing element 17 has first through openings 19 for receiving joints 21. Second passage openings 23 serve to receive a sleeve, not shown, in order to connect the leg of the user in the calf area with the reinforcing element 17 can. The cuff can be in the range the calf be additionally reinforced with a half shell, for example made of hard plastic, to stabilize the foot of the user also when this is when skiing in a supine position. Above the passage openings 19, the reinforcing element 17 has free first ends 22a. Below the passage openings 19, the reinforcing element 17 has second ends 22b which can be pivoted along the foot shell 15 or the sole 17 substantially parallel to the sagittal plane. The second ends 22b stabilize not only the lower leg but also the foot of the athlete below the ankle , Another stabilizing element, which is realized in ski boots of the prior art by a front overlapping shaft shell, is superfluous in the ski boot 11 according to the invention. The tedious expansion of the overlapping parts of the shaft shell when entering and exiting the ski boot is therefore eliminated in the present subject matter.

FIG. 2 shows a first embodiment of the ski boot 11 according to the invention in which the reinforcing struts 18a, 18b extend along the sagittal plane on the outside of the foot shell. The legs 20 acts as a support against the foot shell 15. A first and second end stop 25,27 are formed in that in the sole 13 a notch is provided whose width is greater than the width of the leg 20. To the joints 21 is the Reinforcement 17 along the arrows 29,31 forward and backward pivoted until it stops at the first and second end stop 25,27 To damp the stop, the end stops 25,27 may be provided with elastic elements 33. To individualize the deflection and flex, elastic members 33 having different widths and hardnesses may be locatable on the first and second end stops 25, 27.

The arrangement of the reinforcing struts 18a, 18b on both sides of the sagittal plane, allows a simplified entry or exit from the ski boot 11, since the reinforcing member 17 is open to the front and rear Due to the high stability of the reinforcing member 17 and the foot shell 15 of a made less stable or softer material than in a ski boot of the prior art.

FIG. 3 shows a second embodiment of the ski boot 11, in which the reinforcing struts 18a, 18b are hinged within the foot shell 15 at selbiger. The shaft part 35 does not require stability like the shaft shell of a conventional ski boot and can therefore be made of a waterproof, elastic textile, for example of neoprene, be made. As a material for the shaft portion 35 but leather can be used. The user can slip into this shaft part as in a stocking, whereby the dressing and undressing of the ski boot 11 proves to be very comfortable. The end stops 25, 27 described in the first embodiment must be formed within the foot shell 15 in this embodiment.

Another aspect of the invention relates to an insole 37 according to the FIGS. 4 and 5 , The insole 37 is made of a resilient material, in particular of a wooden board. In order to enable the resilient action, which is indicated by the arrow 39, the insole 37 in the toe and heel area must rest on a first and second support 41, 43. FIG. 6 ). The first support 41 may be realized by a lever 45.

FIG. 6 shows the insole 37 inserted into the foot shell 15. The insole 37 is located between the first and second supports 41,43, whereby between the insole 37 and the sole 13, a gap 47 is formed. In the space 47, the insole 37 can bend when it is loaded by the user of the ski boot 11.

The U-shaped reinforcing element 17 is rotatable in an angular range around the joints 21 relative to the foot shell 15. The angular range is limited by the stalk 45, which serves as a first end stop 25, and a second end stop 27. The forked arrow 49 indicates how a pressure on the insole 37 is returned by the "trampoline effect" of the insole.

The sports shoe according to the invention has a reinforcing element 17, which reduces the function of the shank of a conventional ski boot to a minimum. The reinforcing element 17 shines the lower leg at the necessary points, but is also designed so open that an entry and exit from the inventive sports shoe is as simple as putting in and out of a sock. Since the front and rear part of the shaft part is covered only with a waterproof and heat-insulating material, a rear entry into the ski boot according to the invention is possible. For firm and direct connection of the lower leg with the reinforcing elements 17, a sleeve is provided, which may be reinforced by half-shells.

Legend:

11

ski boot

13

sole

15

foot shell

17

U-shaped reinforcing element

18a, 18b

reinforcing struts

19

First passages

20

leg

21

joints

22a, 22b

First and second end of the reinforcement struts

23

Second through holes

25.27

First and second stop

29.31

arrows

33

Elastic elements

35

shank part

37

insole

39

arrow

41, 43

First and second supports

45

stiletto

47

gap

49

Forked arrow

Claims (15)

Sports shoe for attachment to a gliding board, such as ski boot (11), snowboard or ice skate, with a sole (13), a foot shell (15) fixedly connected to the sole, - A shaft part (35) and - Two reinforcing elements (17) which extend on both sides of the sagittal plane of the sports shoe along the shaft portion (35) and are hinged to the foot shell (15) in the ankle area with a hinge (21), whereby a deflection movement (29,31) of Reinforcing elements (17) is realized around the joint (21),
characterized,
in that the first and second reinforcing elements (17) are integral and each have a first free end (22a) which is oriented to the upper edge of the shaft part (35) above the hinge (21) and
a second end (22b) below the hinge (21), which second end along the foot shell (15) or the sole (13) in the direction of the deflection movement (31) is movable, whereby the stabilizing function of the shaft part (35) the reinforcing elements (17) is transmitted. Sports shoe according to claim 1, characterized in that the two reinforcing elements (17) have a greater rigidity than the shaft part (35). Sports shoe according to claim 2, characterized in that the shaft part (35) consists of a waterproof textile. Sports shoe according to one of claims 1 to 3, characterized in that the reinforcing elements (17) are reinforcing struts (18a, 18b). Sports shoe according to claim 4, characterized in that a reinforcing strut (18a, 18b) has a first free end, which leads to the upper edge of the Shaft part (35) is oriented and has a second end, on which a projection for supporting against the foot shell (15) is arranged. Sports shoe according to one of claims 4 to 5, characterized in that the mobility of the two reinforcing struts (18a, 18b) is limited to an angular range relative to the foot shell. Sports shoe according to one of claims 5 to 6, characterized in that the second end of the reinforcing struts (18a, 18b) between a first and second end stop (25,27) of the foot shell (15) are movable. Sports shoe according to one of claims 5 to 8, characterized in that elastic elements (33) are provided between the second ends of the reinforcing struts (18a, 18b) and the end stops (25, 27). Sports shoe according to one of claims 5 to 8, characterized in that the first and second reinforcing struts (18a, 18b) are connected at their second ends by means of a leg (20), so that a one-piece U-shaped reinforcing element (17) is formed. Sports shoe according to one of claims 5 to 9, characterized in that at the free ends of the reinforcing struts (18a, 18b) is provided in the width adjustable cuff. Sports shoe according to claim 10, characterized in that the rear of the shoe tip facing away from the cuff is designed as a rail for stabilizing the lower leg of the user Sports shoe according to one of claims 1 to 11, characterized in that the reinforcing elements (17) are reinforced with fibers, in particular with carbon fibers, aramid or glass fibers. Sports shoe according to one of claims 1 to 12, characterized in that the sports shoe comprises an insole (37) which is arranged on a first support (41) in the sole region and a second support (43) in the toe region, so that a gap (47) between the insole (37) and the sole (13) is formed. Sports shoe according to claim 13, characterized in that the first support (41) serves as a first end stop (25) for the reinforcing elements (17) Sports shoe according to one of claims 14 to 15, characterized in that the insole (37) is made of an elastically resilient material, in particular of a wooden board

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