EP0775454A1 - Sportsshoe - Google Patents

Abstract

The boot has a foot part (4) and an upper part (5) with link connections (9,9') so that the angle included by the link axis and the plane formed by the shoe sole can be changed. The distance between the link axle and the shoe sole may also be changed. One of the pivot points (9) of the link connection is movable in relation to the plane (3) of the sole. The inside link connection has a disc (7) and a slope (11) forcing the pivot point away from the sole when the upper is tilted towards the toe-part of the boot.

Description

The present invention relates to a sports shoe with a swivel or tilt axis between the shoe shell shaft part and the shoe foot part.

Sports shoes with tilt axles or articulated axles in the heel area are known, such as ski boots. Their tilt axis for the upper ankle runs exactly across and practically parallel to the shoe sole, i.e. at right angles to the normal longitudinal plane of the shoe center. This tilt axis is therefore in a normal plane to the longitudinal axis of the ski. The skier has previously gripped the edges for cornering control so that the lower leg and the entire leg are tilted towards the inside of the curve. The lower ski surface and the longitudinal axis of the lower leg viewed from the front remain fixed at a predetermined right angle to one another. This right-angle relationship between the ski surface and the lower leg is constant with every possible flexion in the upper ankle.

This known, 90 ^o transverse tilt axis or joint-like connection in the shoe, especially in the ski boot, does not correspond to the normal anatomy of the human leg. The human lower leg has a physiological external gyration in the range of 20 ^o - 25 ^o with a corresponding direction of the ankle axis to the longitudinal axis of the foot of 110 ^o - 115 ^o or 70 ^o - 65 ^o .

When kneeling without or with a low shoe, this axis adjustment of the upper ankle automatically causes the floor area of the foot to tilt in the sense that the inner edge of the foot is lowered and the outer edge of the foot is raised. There is an "edging" of the foot, as the skier strives for, with the inner edge of the ski during cornering or the cross-country skier pushing off while skating.

Another disadvantage of the ski boots used today is their rigidity. Even the mentioned ski boots with tilting axles have very stiff plastic shells in order to guarantee the skier an optimal hold on the ski. However, this makes it impossible to play with the knees and ankles, which also enormously limits the possible variations in so-called freestyle riding. But especially the youth want more mobility, which partly explains the great success of snowboarding.

Ski boots are known from DO S 36 36 496 as well as from EP-A 356 400, in which a boot shell and a boot shaft are connected to one another via a joint-like connection, the joint either being arranged further forward on the inside of the boot, or the two joints of a shoe are staggered in the vertical direction. As a result, when a skier is in a crouched position or bent, the ski and edge guidance is supported when cornering, but at the same time the skier is no longer parallel to the ski in the longitudinal direction, but angled to it, which is not the case with long turns is desirable.

The present invention thus aims to create a sports shoe which allows increased mobility and which takes into account the position of the ankle axis of the lower leg of the human body and thus provides the advantages described below, for example.

Such a sports shoe is characterized by the content of one of the claims, in particular of claim 1.

According to the invention, a sports shoe is proposed, at least comprising a foot part and a shaft part, which are connected to one another in an articulated manner, the articulated axis being designed to be displaceable in relation to the plane formed by the shoe sole in such a way that its distance from the plane mentioned can be changed and / or whose angle included with the plane of the sole can be changed, ie an upturning of the sole of the shoe relative to the shaft part enables, which is almost impossible in contrast to previous ski boots.

According to the invention, the joint axis mentioned in the rest position or in the starting position runs essentially parallel to the plane of the shoe sole, whereas when the shaft part is tilted forward towards the tip of the shoe, the joint axis is increasingly angled to the plane of the shoe sole. It is provided that one of the centers of rotation of the joint-like connection is displaceable with respect to the sole plane, wherein preferably the center of rotation of the inside, joint-like connection is displaceable with respect to the shoe sole plane.

Further preferred design variants of the sports shoe according to the invention are characterized in the dependent claims 2-9.

A ski boot or, for example, a cross-country ski boot is preferably designed in the inventive sense.

The invention will now be explained in more detail, for example, and with reference to the accompanying figures.

Fig. 1

eine Seitenansicht von innen gesehen eines rechten, erfindungsgemäss ausgebildeten Skischuhs in Ausgangsposition, d.h. bei aufrechter Position einer den Skischuh tragenden Person,

Fig. 2

den Skischuh von Fig. 1 in Seitenansicht, auf die Innenseite gesehen, in angewinkeltem Zustand, d.h. bei gebeugter Haltung einer den Skischuh benutzenden Person,

Fig. 3

den Skischuh von Fig. 1 in Ansicht, von hinten gesehen, in aufrechter Haltung, ohne Beugung von Knie- und Fussgelenk,

Fig. 4

den Skischuh von Fig. 2 in Ansicht, von hinten gesehen, mit schräggestellter Schuhsohle, bei gebeugtem Knie- und Fussgelenk,

Fig. 5

eine weitere Ausführungsvariante eines erfindungsgemässen rechten Skischuhs in Seitenansicht, auf die Innenseite gesehen, in Ausgangslage, d.h. bei aufrechter Haltung einer den Skischuh tragenden Person,

Fig. 6

den Skischuh von Fig. 5 in angewinkeltem Zustand, d.h. bei gebeugter Haltung einer den Skischuh tragenden Person,

Fig. 7a und 7b

eine weitere Ausführungsvariante eines erfindungsgemässen rechten Skischuhs von beininnenseitiger Draufsicht in Ausgangslage sowie in gebeugter Haltung einer den Skischuh tragenden Person,

Fig. 8

den Skischuh aus den Fig. 7a und 7b in beinaussenseitiger Draufsicht,

Fig. 9a und 9b

den Skischuh aus den Fig. 7a, 7b und 8 im Querschnitt durch das Schaftteil und darstellend eine rückseitig integrierte Rückstellfeder im Fersenbereich, um das Schaftteil nach hinten zu treiben,

Fig. 10a und 10b

schematisch anhand von Prinzipskizzen mögliche menschliche Beinstellungen,

Fig. 11a und 11b

eine weitere Ausführungsvariante von Schalen eines erfindungsgemässen Schalenskischuhs in Seitenansicht und

Fig. 12a und 12b

die Schalen aus den Fig. 8a und 8b in anderer Darstellung, geeignet, um die Funktionsweise der gelenkartigen Verbindung der einzelnen Schalen untereinander schematisch darzustellen.

Show:

Fig. 1

2 shows a side view seen from the inside of a right-hand ski boot designed according to the invention in the starting position, ie in the upright position of a person wearing the ski boot

Fig. 2

1 in a side view, seen from the inside, in an angled state, ie when a person using the ski shoe is bent,

Fig. 3

1 in view, seen from behind, in an upright position, without bending the knee and ankle,

Fig. 4

2 in view, seen from behind, with an inclined sole of the shoe, with the knee and ankle bent,

Fig. 5

a further embodiment variant of a right ski boot according to the invention in a side view, seen on the inside, in the starting position, ie when a person wearing the ski boot is kept upright,

Fig. 6

5 in an angled state, ie when a person wearing the ski boot is bent,

7a and 7b

a further embodiment variant of an inventive right ski boot from the inside of the leg Top view in the starting position and in a bent position of a person wearing the ski boot,

Fig. 8

7a and 7b in a top view from the outside of the leg,

9a and 9b

7a, 7b and 8 in cross section through the shaft part and depicting a return spring integrated in the heel area in order to drive the shaft part backwards,

10a and 10b

schematically possible human leg positions using schematic diagrams,

11a and 11b

a further embodiment variant of shells of a shell ski boot according to the invention in side view and

12a and 12b

the shells from FIGS. 8a and 8b in a different representation, suitable for schematically representing the functioning of the joint-like connection of the individual shells to one another.

Fig. 1 shows schematically in side view a right ski boot 1, seen on the inside. The ski boot is constructed in two parts and has a foot part 4 and a shaft part 5, which are connected to one another via an articulation axis of rotation 9. This articulated connection enables a skier to squat or bend, especially when cornering. A heel section 10 is formed in the rear area of the shoe sole 3, comprising an upper shoulder edge 11, which serves as an abutment for the eccentric 7-9 of the shaft part.

The articulated connection between the shaft part and the foot part has a movable pivot point 9, which e.g. in a slot of the turntable 7, depending on whether the shaft part of the shoe is upright or inclined forward with its eccentric lever against the supporting ramp 11 in the heel area 10.

When the shaft part 5 tilts in the direction of the arrow against the foot part 4, the disk 7, which is firmly connected to the shaft part 5, is now rotated about the center of rotation 9 of the joint, the disk 7 or the eccentric being driven downward by the eccentric arrangement of the center of rotation 9 . Fig. 2 shows the dashed disc 7 in the starting position and with a solid line in the downward position, caused by the forward tilting of the shaft part 5. By resting the disc 7 on the ramp 11 of the heel part 10 is the center of rotation 9 driven upwards in the direction of the arrow, whereby the shoe sole 3 is driven downward and the shoe sole is angled in relation to the longitudinal center plane through the shaft part 5. The pivot point 9 can be shifted by the articulated connection in the inner foot part being mounted in a longitudinally displaceable manner in a longitudinal slot 8 shown in dashed lines.

For a better understanding of this process, the ski boot is shown in FIGS. 1 and 2, in FIGS. 3 and 4, each in a view from behind. 3 shows the right ski boot from FIG. 1 in a view from behind, ie in the starting position with the person wearing this shoe in an upright position. It clearly shows that the center of rotation 9 of the joint axis between the shaft part 5 and the foot part 4 is eccentric 4 eccentrically shifted downward in the disc or the eccentric 7 is arranged on the inside of the shoe. With the turntable 7 ', however, the center of rotation 9' lies exactly in the middle. When the shaft part 5 is tilted, the eccentric 7 now rotates about the eccentrically arranged center of rotation 9, as shown in FIG. 4. This downward rotation of the disk 7 increases the distance between the center of rotation 9 and the shoe sole 3 by the distance a, as is also shown in FIG. 4. By driving the shoe sole 3 away, it is angled with respect to the central plane of the shaft part 5, specifically by the angle α shown in FIG. 4. As a result, a skier who crouches to the left automatically bends the sole 3 of his right ski boot by the angle α, which of course also bends the ski located under the sole by the angle α. Since, as is well known, the left ski, ie the mountain ski, is not loaded on a left turn, angling the right loaded ski by the angle α enables safe and easy cornering without the skier being forced to do this by turning inwards. To tilt the lower leg. The lower leg thus remains in the "normal position" even when the skier is bent while cornering, ie in a position not tilted inward. Nevertheless, by angling the ski, a secure grip of the leading valley ski is made possible, especially if the loaded leg or knee joint and hip area are tilted towards the inside of the curve, as is the case with today's ski technology.

Of course, the left ski, ie the mountain ski, is tilted at the same angle in the other direction, which is not a problem, since, as mentioned above, the inner ski or the mountain ski is not loaded. In addition, this angling of the inner ski in the opposite direction ensures that it cannot grip, making "canting" impossible.

It is of course irrelevant which construction on the ski boot is ultimately responsible for the sole of the shoe or the entire foot part being angled relative to the shaft part when the shaft part is tilted against the tip of the shoe. The representations in FIGS. 1-4 are an example of how this pivoting away of the shoe sole or the one-sided "lifting" of the center of rotation of the joint axis can be produced.

5 and 6 show a further embodiment variant, in which case the center of rotation on the inside of the shoe is not arranged eccentrically with respect to the turntable, but rather by providing a cam-like projection 13 on the shaft 5 in the region of the inner ankle . This means that a disc or an eccentric can be dispensed with in this variant. In contrast to the embodiment variant in FIGS. 1-4, the heel part 10 is wedge-shaped, with the result that the upper heel 11 is formed at an oblique angle with respect to the sole 3.

When going into a crouch or when the skier is in the knee position, the shaft part 5 is again tilted forward in the direction of the arrow, as shown in FIG. 6, whereby the cam 13 is rolled or shifted in the direction of the arrow along the oblique heel. As a result, the shaft part is pushed upwards and the axis of rotation 9 then shifts from A to B, but only in the shaft part, because the axle bolt is immovably fixed to the sole part of the shoe in the embodiment variant according to FIGS. 5 and 6. Since the shaft part presses against the wedge-shaped heel part or the ramp 10, it must A slot-shaped hole 8 may be formed in the shaft part for the pivot bolt, so that the shaft part is pushed upwards or the sole is pushed downwards for prevention. Since this does not happen on the outside of the shoe, this automatically results in a fold-up of the sole of the shoe and thus also of the ski.

So that the construction proposed according to the invention really allows the sole of the shoe or the foot part to be edged, it has proven to be advantageous to make the foot part less high in the heel area than is the case with today's very stiff ski boots. In contrast, the shaft part 5 should be made stiff or stiffer so as to ensure a good hold of the skier on the ski.

7a, 7b, 8, 9a and 9b again show a further embodiment variant of a multi-part shell ski boot according to the invention, the purpose of the construction shown being the same as that of the embodiment variants described above. It is essential to the embodiment variant shown here that an additional element is provided both on the inside of the shoe and on the outside of the shoe, the element 20 being designed like a lever on the inside of the shoe, while the element 22 on the outside of the shoe is rod-shaped. The lever-shaped element 20 on the inside of the shoe is connected with its short lever arm to the foot part 4 via, for example, a bolt 19, while, on the other hand, the longitudinal lever leg extending along the shaft part is firmly connected to the front shell part 5b of the shaft part via, for example, rivet connections 21.

As can be clearly seen from FIGS. 7a and 7b, in particular the front shaft shell 5b is pushed away from the sole 3 by the distance a when the shaft part tilts forward, or the virtual axis of rotation 9 which exists between the shaft part shell 5b and the foot part 4 '' pushed away from the sole 3 by the distance a or the sole 3 on the inside of the shoe is pushed away from the shaft part. This is particularly because, as shown in FIG. 8, a connecting element 22 is provided on the outside of the shoe, which is rod-shaped and not lever-shaped. This connecting element 22, which is arranged between the foot part 4 and the shaft part 5b (not shown), only allows the shaft part to tilt relative to the foot part 4 about the axis of rotation 9 ', without, however, causing the sole to be pushed away. The edging process thus arises again, as has already been described in detail with reference to FIGS. 3 and 4. 7a and 7b already shown in a hint and now clearly recognizable in the cross-sectional view in FIG. 9a, a leaf spring-like return spring 23 is further arranged in the heel or calf region of the shell ski boot, which leaf spring 23 on the one hand in the heel region 10 of the foot part 4 with this is connected and on the other hand, for example integrally, is connected to the rear shell part 5a of the shaft part. In particular, due to the relatively low design of the foot part 4, the uprighting of a skier after passing through a curve could become a problem in that the Achilles tendon is overstressed during the uprighting. For this reason, it is advantageous to arrange the aforementioned leaf spring 23, which should be pivotable at least partially about an axis of rotation 24 transversely to the longitudinal axis of the shoe, so that when the sole 3 is pivoted away according to the invention, the leaf spring 23 can also perform this movement.

Furthermore, the cross-sectional view in FIG. 9a shows that the two lateral longitudinal elements 20 and 22 are preferably connected via the axes of rotation 19 and 9 'to a fixed chassis 12 which is arranged integrally in the foot part 4 and which has a high strength. The high strength is important because, particularly in this area of the foot part 4, increased forces can occur, particularly when a skier goes into a crouch, since the virtual axis of rotation 9 ″ or the sole 3 is shifted in the inside area of the ski boot and the associated skis are pushed away.

In Fig. 9b the individual parts of this construction are shown in an exploded state, i.e. The chassis 12 and the two lateral, longitudinally formed elements - the lever 20 and the longitudinal bar 22 can be seen.

In the embodiment variant according to FIGS. 7a, 7b, 8, 9a and 9b, it is essential that the structural parts responsible for the process according to the invention have increased strength, which is why they are preferably made, for example, of fiber-reinforced plastic, such as a composite material, or even made of metal. For example, a construction made of carbon fiber-reinforced epoxy resin is conceivable, although other suitable materials can of course also be used. It is important to have a high strength, and in particular with respect to the leaf spring on the back, also a high breaking strength, since even at low temperatures a material which is too brittle could inevitably lead to breaks, which is not desirable. With regard to the leaf spring 23, it should also be noted that a rubber or spring balance can of course also be used instead of this leaf spring. It is important that the Shoe is driven backwards when a skier straightens up again.

In conclusion and in addition, it should be mentioned with regard to the embodiment variant described that, of course, the illustration in FIGS. 7a-9b only contains the structurally relevant elements and elements known per se have been omitted from a ski boot for reasons of clarity. 7a-9b do not show any elements connecting the two shaft shell parts 5a and 5b, such as wire pulls, buckles and the like, as are common in shell ski boots used today. Also the representation of the "soft" liner, which is necessary for the comfort of the shell ski boot, is missing.

In FIGS. 10a and 10b possible human leg positions are shown schematically on the basis of schematic diagrams, with a normal position being shown in FIG. 10a, while a so-called “O-leg” position is shown in FIG. 10b. Of course there are also other positions, but on the basis of these two basic sketches it becomes clear that it would be advantageous if a skier, even when not in a crouched position, could compensate for these different leg positions by appropriately designing the shoe. This is made possible in particular by means of a shell ski boot, as shown in FIGS. 11a, 11b, 12a and 12b. 11a and 11b show a foot part 4 and the rear part of a shaft part 5, which two parts are intended to be connected to one another in a rotatable manner. A longitudinal recess 25 is provided on the inner shoe side of the foot part 4 with a toothed rack 27 arranged on one side. Correspondingly, a toothed wheel 29 is provided on the shoe inner side of the shaft part 5 from FIG. 11b, having a toothing 31 on at least one side. which gear is firmly connected to the shaft part 5. The toothing 31 is provided in order to engage in the toothing or toothed rack 27, as is already indicated schematically in FIG. 11b.

The operation of this construction will now be explained in more detail with reference to FIGS. 12a and 12b. 12b clearly shows that the disk-like gear wheel 29, which has the toothing 31, is projecting inwards from the shell-like shaft part 5. This inward protrusion is therefore necessary so that the gear 29 can engage in the longitudinal recess 25 or in the toothing 27 of the foot part 4 arranged thereon. Depending on the leg position, the starting position between the shaft part 5 and the foot part 4 is now chosen by appropriately placing the gear wheel 29 in the recess 25 such that a skier stands straight on the ski without bending his leg. When the skier squats in the direction of the arrow, as shown schematically in FIG. 12a, the gear wheel or the disk 29 now moves “upwards” by the rotational movement along the toothing 27, as a result of which the pivot point 9 by the distance a in the inner region of the foot is moved away from the sole 3. Or vice versa, the sole 3 or the ski attached to the sole is pushed away from the center of rotation 9 by the distance a, which causes the ski to be edged earlier, in order to enable perfect cornering.

The construction of a shell ski boot shown in FIGS. 11a-12b already makes it possible when purchasing a ski boot to optimally adapt it to the position of the skier.

Of course, the embodiment variants of a ski boot shown in FIGS. 1-12 are only Examples that can be modified, modified or varied in any way. For example, the choice of a suitable material for the construction of the ski boot is irrelevant. It is quite conceivable to design the ski boot from leather, stiffened rubber, etc. instead of the plastics commonly used today. The articulated connection shown in FIGS. 1-9 can be mechanically different and can also be made of metal, for example, whereby the use of metal can also be indicated at least partially in the shoe sole. In the end, the mobility between the shaft part and the foot part is in principle irrelevant, it is important that when the shaft part is tilted relative to the foot part, the inside of the shaft part is displaceable relative to the sole of the shoe or that the sole of the shoe is pivoted away from the shaft part, that is, when the knee and foot move done automatically.

Claims (12)

Sports shoe, at least comprising a foot part (4) and a shaft part (5) with an articulated connection (9, 9 '), characterized in that the angle enclosed by the joint axis and the plane, formed by the sole of the shoe, can be changed and / or that the distance between the axis of the joint and the sole of the shoe can be changed. Sports shoe, in particular according to claim 1, characterized in that one of the centers of rotation (9) of the joint-like connection is displaceable with respect to the sole plane (3). Sports shoe, in particular according to one of claims 1 or 2, characterized in that the center of rotation (9) of the inside, joint-like connection is displaceable with respect to the sole plane (3). Sports shoe, in particular according to one of claims 1-3, characterized in that means (7, 11, 13) are provided on the inside, joint-like connection (9) around the center of rotation when the shaft part is tilted away from the sole toward the tip of the shoe to drive. Sports shoe, in particular according to one of claims 1-4, characterized in that a gear-like, joint-like connection (27, 29, 31) is provided between the shaft part and the foot part, such that a gear-like element (29, 31) arranged in the shaft part or foot part ) is arranged in or on the center of the joint on the inside of the shoe, which engages in a corresponding toothed rack (27) in the foot part or shaft part in order to counter the foot part when the shaft part is tilted the toe to drive the center of rotation (9) away from the sole (3). Sports shoe, in particular according to one of claims 1-4, characterized in that the articulated connection has an eccentrically mounted center of rotation. Sports shoe, in particular according to one of claims 1-4 or 6, characterized in that at least one section is provided on the shaft part and / or on the shoe foot part, which, when the shaft part is tilted against the tip of the shoe, abuts against a corresponding section on the foot part or on the shaft part and drives the center of rotation of the joint-like connection from the shoe sole or the shoe sole away from the center of rotation. Sports shoe, in particular according to one of claims 1-7, characterized in that on the inside of the shoe, the foot part and the shaft part are connected to one another via a lever-like element (20), the lever-like element being rotatably connected to the foot part and to its via a lever arm other leg firmly, with at least part of the upper part, such that when the upper part tilts over the foot part, the virtual center of rotation (9 '') existing between the foot part and the upper part is moved away from the shoe sole (3). Sports shoe, in particular according to one of claims 1-8, characterized in that a leaf spring-like restoring element (23) engages in or on the shaft part, which is connected in the heel area to the foot part and which on the shaft part (5) between the rotation part (9) The shaft and foot part drive away from the tip of the shoe, the restoring element (29) being arranged around a part arranged in the heel area further axis of rotation (24), is pivotally connected to the foot part (4) at least by a limited angle in the transverse direction of the shoe. Sports shoe, in particular according to one of claims 1-9, characterized in that the shaft part (5) is formed at least in two parts with a front-side shell (5b) which can be tilted at least partially towards the tip of the boot and a rear-side shell (5a), which preferably at least is partially tiltable to the rear, the two shaft parts being held together when using shoes by means of holding parts such as buckles, ropes and the like. Sports shoe, in particular according to one of claims 1-10, characterized in that it is a ski shoe. Sports shoe, in particular according to one of claims 1-10, characterized in that it is a cross-country ski shoe.

Images