WO2006089448A1

WO2006089448A1 - Outsole with tangential deformation

Info

Publication number: WO2006089448A1
Application number: PCT/CH2006/000114
Authority: WO
Inventors: Hans Georg Braunschweiler
Original assignee: Glide'n Lock Gmbh
Priority date: 2005-02-24
Filing date: 2006-02-23
Publication date: 2006-08-31
Also published as: JP5398144B2; CN101128131A; MX2007011043A; EP1858358B1; US20120167412A1; RU2007135172A; KR101276771B1; EP1858358A1; RU2385140C2; CN106923439A; US20080209766A1; JP2008531092A; KR20070106577A; ES2523886T3; CA2597987A1; CA2597987C

Abstract

The invention relates to an outsole (1), especially for sports shoes (2), that can be formed with a large amount of elastic deformability even in the tangential direction towards the front and the back, enabling a good cushioning effect even when the tread of the foot is inclined and somewhat slipping. Beyond at least one critical deformation in the deformed region, the sole remains however essentially rigid in relation to tangential deformation. In this way, the runner has a secure footing on the respective tread point. The runner can then push off from the tread point without losing ground. A swimming effect on the sole is thus prevented. According to the invention, the elastic deformability of the sole also in the tangential direction is caused by at least one first element (3a), and the cited rigidity of the sole in relation to tangential deformation beyond said at least one critical deformation, in addition to the degree of the at least one critical deformation in the deformed region is due to at least one second element (3b). So that said first and second elements (3a, 3b) can be independently designed, dimensioned and produced, there are extensive structuring, formation and variation possibilities. Certain areas in the heel and/or the ball region of the sole can be varied by the at least one first element (3a), and certain areas by the at least one second element (3b), in the longitudinal direction.

Description

DESCRIPTION TITLE

Outsole with tangential deformability

TECHNICAL AREA

The present invention relates to an outsole, in particular for sports shoes, with elastic deformability also in the tangential direction to the front and to the rear, which is only beyond beyond at least one critical deformation in the deformed area substantially rigid against tangential deformation.

In the case of deformation in the tangential direction, a deformation caused by shearing in the direction of tangential or, parallel to the surface extension of the outsole or its tread. It is to be distinguished from e.g. deformations caused by compression in the direction perpendicular to the flat extent of the outsole or its tread. On a horizontal surface the directions tangentially coincide with horizontal and vertical with vertically.

STATE OF THE ART

Elastic compliant outsoles are known in large numbers in a variety of forms, elastic materials are used with a variety of hardnesses. Also known are outsoles with embedded air or gel pads. They are intended to cushion the loads occurring during running and thereby protect the musculoskeletal system of the runner, in particular its joints, and also convey a pleasant ride.

Most sports running shoes currently commercially available have spring characteristics that allow suspension primarily in the vertical direction, or in the direction perpendicular to the tread, under compression of the sole, which in FIG horizontal or tangential direction, however, are relatively stiff and so far not give enough in an oblique and slightly pushing appearance. The latter is probably due to the fact that a greater deformability of the sole in the horizontal direction would create a kind of floating effect, which would have a negative effect on the stability and stability of the runner. Also, the runner would lose a certain amount of distance at each step, since the sole would be deformed when repelled from the point of occurrence only in the opposite direction as the occurrence of something. To some extent, of course, the swimming effect occurs in the commercial sports shoes already on. To avoid this effect, in most of these sports shoes, the front portion of the sole, from which the repulsion is usually made, is relatively hard and unyielding.

Outer soles of the type mentioned in the introduction, as they are also known from WO 03/102430, in contrast to the pronounced tangential deformability, avoid the floating effect by being substantially stiff with respect to tangential deformation beyond at least one critical deformation in the deformed region. For the runner results after reaching the critical deformation of a safe standing on the respective occurrence or load point, from which he can repel without loss of path again.

In WO 03/102430 various embodiments are described, by means of which the solution principle of the tangential deformability of the sole in conjunction with its rigidity beyond the at least one critical deformation can be well understood. Thus, e.g. tubular hollow elements of a rubber material described, which can be completely compressed under vertical, but in particular tangential deformation to the front and rear and then prevent frictional engagement between their upper and lower half shell further tangential deformation.

From EP 1264556 an outsole for sports shoes is known, in which the sole has an outer, softer layer and an inner, harder layer. Projections on the inner, harder position penetrate the softer, outer layer and protrude beyond it in the manner of studs. A tangential deformability of the sole is not provided and would also be prevented by the studs. Similarly constructed is a sole known from FR 2709929, wherein the inner layer is provided with sharp, metallic tips.

From UK 2285569 a training shoe with a sole is known which has yielding first and stiff second elements. The first elements are inclined at an angle to the rear towards the heel part and collapse under load in this direction between the second unyielding elements, which then take over the load. A corresponding deformation of the first elements forward is not possible because of their arrangement relative to the second elements.

From JP 5309001 a shoe with a sole is known, which is provided in an inner zone with tangentially deformable in all directions, provided with a cavity projections. This inner zone is surrounded by a border zone with stiff, lower ribs, which take over the load from a certain deformation of the hollow protrusions.

From the German Utility Model G 8126601 a shoe with a sole is known, in which brush-shaped pieces are used with rearwardly directed stiff bristles. The bristles are supposed to start a quick start as well as through

Apply to the rear to allow forward sliding. A corresponding deformation of the bristles forward is not provided and probably not possible.

From US 3299544 a shoe with a sole is known, the front heel area is provided with transversal, inclined back ribs. The rear edge zone of the heel area forms a plateau slightly lower than the ribs. The ribs should come into contact with the ground during normal running in front of the plateau and thereby be pushed backwards until the plateau gets in contact with the ground and limits further deformation of the ribs.

From DE 29818243 a shoe drive with a sole is known with the elements inclined backwards, which fold in the direction of the heel when they appear and rest on the other sole. In the context of practical applications of the principle known from WO 03/102430 and the tubular hollow elements described therein, it has been found that these, at least in their concretely described form, can not meet all practical requirements. It is not by chance that sports shoes are specially designed for almost every sport and on the

Sport shoes tailored to the requirements of the respective sport are offered, whereby, above all, the training of the soles plays an important, if not the decisive, role for their respective suitability.

PRESENTATION OF THE INVENTION

Object of the present invention is to specify how outsoles of the known from WO 03/102430 type can be adapted to the different requirements of the practice including the requirements of different sports in an economical manner.

This object is achieved according to the invention by the features as indicated in the patent claims.

The two functionalities required for the desired effect, namely the tangential deformability on the one hand and the rigidity with respect to tangential deformation beyond at least one critical deformation on the other hand, are assigned to different elements according to the invention. Since the at least one first and the at least one second element can be designed, dimensioned and manufactured independently of one another, there are many more possibilities for design, training and variation with which the desired adaptation to the requirements of the practice can be better achieved , as is the case with elements such as the known tubular hollow elements, which fulfill both functions at the same time.

A corresponding division into a plurality of tangentially deformable first elements and a plurality of rigid second elements basically already provides the aforementioned JP 5309001. There, however, the first and second elements are arranged separately from one another: the first elements in an inner zone and the second elements in a peripheral zone surrounding the inner zone. As a result, it may happen that so-called inner or outer foot runner, which will be discussed below, roll exclusively on the hard, arranged in the edge zone elements or that when rolled over the middle of the sole, practically only the first elements are charged and this comes to a floating effect, the just want to avoid the invention.

The invention therefore provides that in the heel and / or in the ball area of the sole zones in the longitudinal direction (from the heel to the ball area) alternate several times, which are determined on the one hand by the at least one first element and on the other hand by the at least one second element. This ensures that when rolling over the heels and / or over the ball area both functions are always used in sufficiently close temporal and spatial relationship to each other. The characteristic of the sole according to the invention therefore largely corresponds to that of WO 03/102430.

Several first elements can be provided. The zones determined by the at least one first element can each be formed by one but also by a plurality of such first elements. Correspondingly, a plurality of second elements can be provided and the zones determined by the at least one second element can each be formed by one but also by a plurality of such second elements.

Like the outsoles known from WO 03/102430, the outsole according to the present invention can also be dimensioned such that the at least one critical deformation during running is locally limited only in the respectively maximally loaded zone and in time only around the load maximum. In this case, the at least one critical deformation, in which the tangential deformability of the outsole according to the invention is frozen, so to speak, depends on the type of deformation. The deformation does not just have to be tangential. A critical deformation can be achieved even with purely vertical or vertical deformation.

According to a preferred embodiment of the invention, the critical deformation is achieved only after a tangential and / or vertical deformation path, which greater than 20% of the deformable thickness of the sole, possibly even greater than 50% of this thickness. Preferably, the tangential deformability of the vertical deformability should even correspond approximately. Absolutely, that can be about a cm.

With such sized spring and damping paths, the outsole according to the invention effectively dampens the forces and stresses that result during running. Above all, the sole according to the invention behaves in an optimally damping way on landing, in that it compensates for the horizontal forces in the direction of travel, which are predominant here. can yield softly by shearing. In the running shoes provided with outsoles according to the prior art, this results in a high load peak, even if they are provided with a pronounced vertical damping, because of the so far lacking tangential deformability. During unrolling, the sole according to the invention absorbs the prevailing vertical forces by vertical deformations as well as damping. In addition, however, it also reacts in this phase by a variety of tangential deformations in different directions to movements between foot and floor, which usually manifest in a slipping of the foot in the shoe and often lead to frayed socks or even blistering. The shoe does not resist the movement that the foot would like to make when rolling against the ground. The shoe allows a largely fatigue-free running. At full

Stress in the phase of repulsion loses the sole according to the invention, however, their damping properties as well as completely. In this phase, the damping is no longer needed and would only be a hindrance to an effective repulsion. In the repulsion phase, the sole according to the invention behaves "hard".

On soles that have been used by different runners for longer, large differences in terms of their predominant load on the wear patterns can be observed. This comes from different, for the individual runners characteristic running styles. Differences also arise from the different running distances. Thus, short-distance runners are predominantly so-called forefoot runners with load practically only on the ball area. Long-distance runners usually land on the heel and roll over the entire foot. Here one differentiates so-called outside and inside foot runners. Outrigger • land on the outside of the heel, roll over the outer area of the heel Midfoot and repel in the outer ball area or from the area of the small toes. In the Innenfussläufem is the reverse. There are also mixed forms in which, for example landed outside, unrolled across the middle foot and repelled from the area of the big toe and vice versa. The sole according to the invention can adapt well to all these different loads and to participate in the natural movements of the foot, since its deformability is vertical but also tangential to the front and back.

BRIEF EXPLANATION OF THE FIGURES

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. Show it:

1 shows a sports shoe in side view with an outsole according to a first embodiment of the invention under a) unloaded, under b) biased obliquely forward and under c) when pushed backwards;

Fig. 2 first and second elements of the outsole of Fig. 1 in a schematic

Detail under a) unloaded, under b) biased forward and under c) vertically loaded;

Fig. 3 in a similar representation just such first and second elements, however, partially embedded and positively anchored in a midsole;

Fig. 4 in the same illustration an embodiment in which only first elements embedded in a midsole, second elements, however, are integrally formed therewith;

Fig. 5 shows a variant of the embodiment of Fig. 4 and a) in the unloaded and under b) in the loaded state, in which case the first elements are so deeply embedded in the midsole 4 that second elements are no longer needed as extra parts;

Fig. 6 schematically under a) and b) further variants in the manner of Fig. 5; Fig. 7 in a schematic detail representation of a continuous layer or

Layer with first and second elements formed thereon, under a) unloaded, under b) biased obliquely forward and under c) vertically loaded;

8 shows under a) - d) several views of the tread of inventive outsoles; and

Fig. 9 under a) - e) further layers according to FIG. 7 in the unloaded state.

WAYS FOR CARRYING OUT THE INVENTION

An embodiment will first be described with reference to FIG. 1 which, although not necessarily the preferred one, on the basis of which the inventive teaching is well represented.

FIG. 1 shows a running shoe 2 equipped with an outsole 1 according to the invention. The outsole 1 is formed by a plurality of first profile-like hollow elements 3a, as already known from WO 03/102430, as well as a plurality of platform-shaped second elements 3b. The hollow elements 3a may have a height of e.g. 15 mm and the platform-shaped elements 3b have a height of e.g. 10 mm. Both the hollow elements 3a and the second elements 3b can extend over the entire respective width of the running shoe 2. However, they could also be arranged in several rows next to each other. Also, the platform-shaped elements 3b could surround at least partially single or multiple hollow elements 3a ring-like. Attached are the elements 3a, 3b at the bottom of a midsole 4 of the running shoe 1, e.g. by sticking.

The hollow elements 3a are made of a material which can deform elastically under the loads occurring during running. The second elements 3b and the midsole 4 may also have a certain flexibility, but in comparison with the hollow elements 3a substantially rigid, in particular stiff against tangential deformation. The hollow elements 3a have compared to the platform-shaped elements 3b also a greater height and are therefore in front of them down.

In the sense of the definition given above, the hollow elements 3a each form "zones determined by the at least one first element". If a plurality of hollow elements 3a are arranged side by side, they can also be attributed to such a zone together. The same applies to the platform-shaped second elements 3b, which each form "zones determined by the at least one second element". In the longitudinal direction of the sole, the various zones alternate in the bale as well as in the heel area several times. If the platform-shaped second elements 3b individually or several hollow elements 3a at least partially surround, different zones on the sole surface are additionally mixed with each other.

When the running shoe 2, e.g. shown in Fig. 1 b) and loaded by the loading arrow P1 when appearing obliquely forward, initially come only the protruding hollow elements 3 a with the bottom 5 in contact and are deformed under elastic cushioning of the load vertically but also horizontally. This deformation is limited by the adjacent, platform-shaped second elements 3b, as soon as the hollow elements 3a are aligned with these at the same height. From this point in time, the platform-like second elements take over the main part of the load, whereby due to their higher stiffness mentioned, they allow at least no significant tangential displacement of the running shoe relative to the floor 5. The wearer of the running shoe has a safe and firm footing on the ground at this stage. In addition, it can, as shown in Fig. 1 under c), repel from the position shown in FIG. 1c) to carry out the next step again, without having to take a loss of path into account, as the podium-shaped second elements Here, too, in a significant extent in the direction of the new when you repel, indicated by the arrow P2 load horizontally practically can not deform.

Fig. 2 shows in a detailed view of one of the hollow elements 3a and two platform-shaped elements 3b of Fig. 1 and under a) in the unloaded state and under b), inter alia, tangentially loaded. Under c) is a deformation vertical or shown vertically down, from which it is clear that the above-mentioned advantages in terms of stability and repulsion are achieved without loss of travel even under purely vertical load.

In the above-described outsole, the hollow elements 3a allow their desired elastic deformability while the platform-shaped elements 3b on the one hand determine and limit the possible degree of deformation of the hollow elements 3a and on the other hand ensure the desired stiffness of the sole against tangential deformation beyond the critical deformation. By distributing these two functionalities among different elements, there is a greater degree of freedom of design with regard to these elements. For example, different materials may be used for the first and second elements. The hollow elements 3a no longer need to allow a firm frictional engagement under load as in WO 03/102430 and are burdened much less. Above all, they do not have to carry the full dynamic weight and are relieved by the second elements 3b at a still uncritical degree of deformation. It is advantageous if the surfaces of the second elements 3b which come into contact with the ground have a good "grip" with respect to the ground, which may possibly be achieved by a special nature of these areas.

The hollow elements 3a can be characterized as "damping elements" and the platform-shaped elements 3b as supporting elements.

The above-described embodiments are characterized by extremely large deformation paths, which between the unloaded state, e.g. according to FIG. 1 a) and the state e.g. According to Fig. 1b) may well more than 20%, possibly even more than 50% of the vertical supernatant of the hollow elements 3a on the platform-shaped elements 3 b may be. The runner thus floats "as if on clouds", but never has an insecure sense of stability.

In the embodiments described above, the first and / or the second elements 3a, 3b are subjected to relatively high alternating loads, inter alia, by tangential or shear forces. In the case of purely adhesive fastening, the elements could permanently detach from the midsole 4. An improvement can be made here Partial embedding and possibly additional positive anchoring of the elements 3a and / or 3b are achieved in the midsole 4, as shown in FIG. 3 for one of the hollow elements 3a and two of the platform-shaped elements 3b.

Fig. 4 shows an embodiment in which only the illustrated hollow element 3a embedded in the midsole 4, the two elements 3b, however, formed integrally with the midsole 4 and formed directly on this. In addition, the anchoring of the hollow element 3a in the midsole 4 is further improved by a dovetail connection.

A variant of the embodiment of Fig. 4 is shown in Fig. 5 under a) in the unloaded and under b) in the loaded state. The hollow elements 3a are so deeply embedded in the midsole 4 that platform-like protruding second elements such as the above-described elements 3b are no longer needed and therefore are not formed. The "normal" surface 4.1 of the midsole 4 assumes the function of the above-described second elements 3b in this embodiment. Thus, the hollow elements 3a in the recesses 4.2, in which they are arranged, "sunk", i. can each be deformed into obliquely until they are aligned with the surface 4.1 of the midsole, the wells 4.2 must be sufficiently wide or wide, as shown in Fig. 5 also.

Fig. 6 shows under a) and b) further variants in the manner of Fig. 5, in which the first elements 3a are also embedded relatively deep in the midsole 4 and in which the "normal" surface 4.1 of the midsole 4, the function of the above second elements 3b takes over. The individual variants of FIG. 6 differ insofar only by the formation of the first elements 3 a. On the left side of Fig. 6, the unloaded and on the right side of the loaded state in the phase of the critical deformation is shown in each case.

In the embodiment of FIG. 6 a), the first, inter alia, obliquely or tangentially deformable element 3 a is designed in the manner of a pin. The recess 4.2 in the midsole 4 may be formed here round, for example, and with its edge on all sides the same distance from the arranged in its center pin 3a, as sketched in the two detailed representation in the lower part of Fig. 6a). In the embodiment of FIG. 6b), the deformable element 3a is designed in the manner of a tube arranged with its axis perpendicular to the midsole 4. Otherwise, the training and presentation corresponds to that of Fig. 6a).

Fig. 7 shows under a) a layer or layer 6 of an elastically deformable material having alternately formed first 6a and second elements 6b in the unloaded state. This layer 6 can be made in one piece and over a large area. In the direction perpendicular to the plane of the drawing, the same sequence of first 6a and second elements 6b may be provided, so that a structure results in which in each case a first element is surrounded by four second elements and vice versa. The first and second elements are then mixed together again, as already mentioned. Suitable cut pieces of this layer may e.g. attached to the underside of a running shoe or the midsole 4 of the running shoe 2 of Fig. 1 by gluing, as shown schematically in Fig. 8 a).

The first elements 6a have the shape of truncated cones, are hollow and slightly higher than the solid material second elements 6b, which also have the shape of truncated cones here. Like the above-described first elements 3a, the first elements 6a are relatively soft and tangentially forward and backward and vertically deformable. Due to their rotationally symmetrical shape, the first elements 6a are even tangentially deformable in all directions in the same way, which may be of additional advantage with respect to the desired rolling behavior.

By contrast, the second elements 6b are substantially rigid and correspond functionally to the protruding second elements 3b). The elements 6a and 6b may be made smaller than the elements 3a and 3b. For example, the height h1 of the entire layer 6 and thus of the first elements 6a may be 8-12 mm, preferably 10 mm, and the height h2 of the second elements 6b may be 4-8 mm, preferably 6 mm. The thickness of the layer 6 in the transition regions between the first and second elements may be, for example, 2 mm, but the thickness of the bottom of the first elements 6a is preferably greater than 2 mm. The horizontal one The distance between the centers of the first and second elements 6a, 6b may be, for example, 10-20 mm, preferably 15 mm.

Under b), Fig. 7, the layer 6 on a floor 5 obliquely loaded. The first elements 6a are under this load vertically, but above all tangentially or horizontally deformed and no longer protrude beyond the second elements 6b. Further deformation of the first elements 6a is prevented by the second elements 6b. The spacings of the first and second elements are preferably chosen to be just as large in order to allow the first elements 6a the deformation shown. The extent of the tangential deformation path until the critical deformation is reached is greater here than the possible vertical deformation path and amounts to absolutely 5 mm for the dimensions given above.

Under c) Fig. 7 shows the layer 6 under vertical load.

The elasticity of the first elements 6a should be selected such that the critical deformation occurs at a load of about 1 kg - 10 kg. This value depends on the number of elements and their arrangement on the sole surface (local density) of the desired damping and the rotor weight. The runner must be able to bring about the critical deformation with his (possibly dynamic) weight at least when pushing off. This applies to all possible embodiments of outsoles according to the invention and correspondingly also to elements of the type of elements 3a. For small shoe sizes (= rather light runner), a different flexibility or other number of first elements 3a / 6a may have to be chosen than for larger shoe sizes (= rather heavy runners). In the case of first elements according to the type of the elements 3a, a number of 8-15 elements is generally distributed over the heel and ball area. In the case of first elements of the type of elements 6a, more than 20 elements will usually be required because of their smaller size.

With regard to the shaping of the first 6a and second elements 6b of the layer 6 of FIG. 7 and their relative arrangement with each other, there is further freedom of design. For example, the second elements 6b may be formed perpendicular to the plane of the drawing as elongated ribs, regularly or irregularly shaped pedestals or the like, as shown in Fig. 8 b) and c). The second elements 6b could even form a continuous surface in which the first elements 6a are scattered, as shown in Fig. 8 at d).

It can be seen from the geometries shown in FIG. 8 that the first elements 6a are intermixed with the second elements 6b, are actually embedded between the second elements 6b and thereby protected against excessive wear with high abrasion. Along each possible Abrollweges first and second elements are thereby burdened in each case in close spatial and temporal sequence, so that the behavior of the sole and the running feeling is always determined by both elements. The mixed distribution of the first and second elements also extends over the entire bale and heel area.

In the transition region between heel and bale, first and second elements are usually not needed. It is therefore sufficient for most applications, when layers 6 are arranged separately only in the bale and heel area. It could be made instead of or in addition to a transverse pitch with respect to the longitudinal direction of the shoe also a longitudinal division. A longitudinal and transverse division with four layers 6 is shown in FIG. 8 under c). As a result, an adaptation to different shoe sizes could be achieved with standard elements by these are easily suitable, in particular more or less far away from each other. Finally, different layers with different properties could be provided in the different areas.

The zones introduced above, which are determined either by at least one first element or by at least one second element, can be found in the

Embodiments of Fig. 8 with the first elements 6a and the second elements 6b are equated. In the example of FIG. 8b), the several first elements 6a adjacent to one another in the transverse direction could also be assigned to only one zone in each case. Conversely, the area 6b) contiguous in the example of FIG. 8d) can be regarded as being formed by a plurality of zones which alternate longitudinally with first elements 6a or zones formed thereby. Further design possibilities of layers 6 are described below with reference to FIG. 9 under a) - e).

In the position 6 shown under a) in FIG. 9, the first elements 6a correspond to those of FIG. 7. The second elements 6b are provided with a rectangular cross section.

In the position shown under b), the first elements 6a are made of solid material, but have a thickened head on a slimmer neck and can thus also deform tangentially well on all sides.

In the embodiments shown under c) and d), the first elements 6a are formed by dimensionally stable nubs 6aa, which are connected via a kind of elastically deformable membrane 6ab with the second elements 6b and thereby horizontally deflectable both vertically and to approximately the same extent.

In the version shown under e) two elastic layers are connected to each other, wherein at least the outer layer is continuous and except for indentations is relatively flat. The recesses form together with approximately opposite bulges of the inner layer first elements 6a. The

Indentations also allow for a kind of buffer that different first elements 6a can be tangentially deformed simultaneously in different directions. The second elements 6b are formed by the outer layer between the indentations and underlying pedestals or ribs in the manner of Fig. 9a).

In the above description, only a few possible embodiments have been described by way of example. Other embodiments are of course possible and may result in particular from hybrid forms of the examples described. NAME LIST

1 outsole

2 running shoe

3a first elements, hollow elements 3b second elements, platform-shaped elements

4 midsole

4.1 Surface of the midsole

4.2 depression in the midsole

5 floor 6 layer or layer

6a first elements of the layer 6

6b second elements of the layer 6

P1 arrow load on occurrence

P2 arrow load on repelling h1 height of total layer 6 h2 height of second elements 6b

Claims

1. outsole, in particular for sports shoes, with elastic deformability in the tangential direction forward and backward and which is only beyond at least one critical deformation in the deformed area substantially rigid to tangential deformation, characterized in that their elastic deformability in tangential direction is caused by at least one first element and its said rigidity against tangential deformation beyond this at least one critical deformation and the degree of at least one critical deformation in the deformed area by at least one second element and that in the heel and / or Ballenbereich the sole by the at least one first element specific zones and by the at least one second element specific zones in the longitudinal direction repeatedly alternate.

2. outsole according to claim 1, characterized in that the projecting at least one first element with respect to the at least one second element seen from the sole until reaching the at least one critical deformation.

3. Outsole according to one of claims 1 or 2, characterized in that the at least one first element is aligned beyond the at least one critical deformation with the at least one second element in the deformed area so far.

4. Outsole according to one of claims 1 - 3, characterized in that the at least one second element is unencumbered until reaching the at least one critical deformation in the deformed area so far.

5. Outsole according to one of claims 1 - 4, characterized in that the at least one first and / or the at least one second element is attached to the underside of a midsole / are.

6. Outsole according to one of claims 1-5, characterized in that the at least one first and / or the at least one second element in the underside of a midsole is partially embedded / are.

7. Outsole according to one of claims 1-6, characterized in that the at least one first and / or the at least one second element as part of a

Midsole is / are formed.

8. Outsole according to one of claims 1-7, characterized in that the critical deformation is achieved only after a tangential and / or vertical deformation, which is greater than 20% of its deformable thickness, in particular even greater than 50% of this thickness.

9. outsole according to any one of claims 1-8, characterized in that the extent of the possible tangential deformation path until reaching the critical deformation corresponds approximately to the possible vertical deformation path to reach the critical deformation.