ES2523886T3 - Sole with tangential deformation - Google Patents

Abstract

A sole, in particular for sports footwear, which exhibits elastic deformability also in the forward and backward tangential direction, and which is only substantially rigid in view of the tangential deformation beyond a critical deformation in the hitherto deformed area, in the present document its elastic deformability also in the tangential direction, is effected by a plurality of first elements (6a) and its stiffness indicated in view of the tangential deformation beyond this at least one critical deformation and the degree of at least one Critical deformation in the zone up to now deformed is effected by at least one second element (6b), and here the zones determined by the first elements and the zones determined by the at least one second element in the heel zone and in the metatarsal area of the foot of the sole in each case, alternate several times in the longitudinal direction and in the transverse direction, characteriz Because the first elements have the shape of truncated cones, they are rotationally symmetrical and, therefore, are tangentially deformable in the same way in all directions, the first elements are hollow and also deformable up to the critical deformation with exclusively vertical load , the at least one second element in the heel and the metatarsal area of the foot in each case, forms an intrinsically contiguous surface in which the first elements, in each case, are arranged in a dispersed manner, and the first elements are arranged in grooves of the intrinsically contiguous surfaces in the heel and metatarsal area of the foot in such a way that they project relative to these surfaces and, in each case, can also be deformed at an angle relative to these grooves.

Description

DESCRIPTION

Sole with tangential deformation.

FIELD OF THE TECHNIQUE

[0001] The present invention relates to a sole, especially for sports shoes, according to the generic term of claim 1.

[0002] The deformation in the tangential direction is understood here as a deformation, caused, for example, by a bending effort, in a tangential direction and / or parallel to the two-dimensional extension of the sole or its tread. The deformations in a direction perpendicular to the two-dimensional extension of the sole or its tread, caused, for example, by compression, must be distinguished from it. The tangential directions coincide approximately with horizontal directions and perpendicular directions with vertical directions and a horizontal substrate.

PREVIOUS TECHNIQUE

[0003] A large number of flexible elastic soles of different constructions are known, using elastic materials of different hardness. Soles with embedded air or gel padding are also known. They are designed to dampen the tension that occurs when running, and, by these means, to take care of the locomotor system of the runner, especially the joints, and impart a pleasant running sensation.

[0004] Most of the running shoes for sports purposes, which can be obtained in the market today, have spring characteristics, which allow cushioning mainly in the vertical direction or in the direction perpendicular to the tread with compression of the sole, which is, however, relatively rigid in the horizontal and tangential directions and not flexible enough when the foot is obliquely positioned at an angle. The reason for this may well be that a greater deformability of the sole in the horizontal direction will produce a kind of swimming effect, which will have a negative effect on the stability and constancy of the runner. The runner will also lose some distance with each step, since the sole, when pushed from the point of impact, will first have some deformation in the opposite direction to which the foot is placed. To some extent, the swimming effect, of course, already occurs in conventional commercial running shoes. To avoid this effect, the front area of the soles of most of these sneakers, from which the thrust takes place, is relatively hard and is constructed so that it is not flexible.

[0005] On the other hand, despite the pronounced tangential deformability, soles of the type mentioned above, as also disclosed in WO 03/103430, avoid the swimming effect, since, beyond at least of a critical deformation in the area so far deformed, 30 are still essential as regards the tangential deformation. For the runner, after reaching the critical deformation, there is a secure posture in the respective steps or tension point, from which he can march again without losing the trajectory.

[0006] In WO 03/103430, different examples are described, whereby the principle of tangential deformability solution of the sole together with its stiffness beyond at least one critical deformation 35 can be well understood. For example, hollow tubular elements of a rubber material are described, which, in perpendicular, but especially also due to their tangential deformation, can be compressed completely forward and backward and then, due to friction between their upper half-shells and lower, also prevent tangential deformation.

[0007] EP 1264556 discloses a sole for sports shoes, whose floor has a softer outer layer 40 and a harder inner layer. The projections in the inner layer, more resistant, penetrate the softer outer layer. Tangential deformability of the sole is not provided.

[0008] A sole, known from FR 2709929, has a similar construction, the inner layer being provided with sharp metallic peaks.

[0009] Document UK 2285569 discloses a training shoe with a sole, which has first 45 flexible elements and second rigid elements. The first elements lean at an angle towards the back in the direction of the heel and fall under the load in this direction between the second inflexible elements, which subsequently deal with the load. A corresponding deformation of the first elements forward is not possible due to their arrangement with respect to the second elements.

[0010] JP 5309001 discloses a shoe with a sole, which is provided in an internal area with projections, which can be tangentially deformed in all directions and are provided with a cavity. This internal zone is surrounded by an edge zone with rigid lower ribs, which, from a particular deformation of the hollow projections forward, absorb the load.

[0011] The German utility model G 8126601 discloses a shoe with a sole, in which 5-piece brush-type pieces with rigid bristles directed backwards are inserted. These bristles are designed to make a march as fast as possible and, pointing to the back, a forward slide. A corresponding deformation of the front bristles is not provided and, most likely, is not possible either.

[0012] US Patent 3,299,544 discloses a shoe with a sole, whose front heel area is provided with transverse ribs, which are directed backwards. Compared to the ribs, the rear edge zone forms a somewhat lower plateau. Under normal running conditions, the ribs are designed to make contact with the ground before the plateau and, at the same time, deviate to the rear until the plateau is in contact with the ground and limits additional deformation of the ribs.

[0013] Document DE 29818243 discloses a shoe mechanism with a sole, with elements, which lean towards the back and, when the foot is placed on the floor, fold in the direction of the heel and come into contact with The rest of the sole.

[0014] US2541185 discloses a game shoe that has a sole that includes a plurality of cylindrical projections, where the greater the height of the projections, the smaller its diameter. The highest and finest projections have a damping effect when placed on a surface, folding to the side to the point where the tension is exerted and is limited by the lower and thicker elements. twenty

[0015] US6082024 discloses a shoe sole with an element that stimulates pressure, which, in relation to the rest of the surface of the sole, protrudes downwards and when it is tensioned it is pressed up vertically thus compressing a sole soft intermediate. The tangential deformation of the elements is prevented by their intrusion into the intermediate sole.

[0016] Within the scope of the practical applications of the principle, which is known from document WO 25 03/103430, as well as the hollow tubular elements described herein, it has turned out that they cannot do justice to all practical requirements, at least not in its concretely described form. It is not by chance that, in the area of sports shoes, especially in the construction of these shoes, coordinated with the requirements of the respective sport, they are offered for almost any type of sport, especially for the construction of the playing soles, in each case, an important function, if not even 30 decisive, for their respective convenience.

PRESENTATION OF THE INVENTION

[0017] It is an object of the present invention to indicate how the soles of the type known from WO 03/103430 can best adapt, in an economical way, to the practical requirements, including the requirements of the different types of sport. 35

[0018] In accordance with the invention, this objective is achieved by the distinctive features given in the claims.

[0019] The two functionalities, required for the desired effect, namely the tangential deformability on the one hand and the stiffness as regards the tangential deformation beyond at least one critical deformation on the other, are assigned, in accordance with the invention, to different elements. Due to the fact that the first element and at least one second element can be conceived, dimensioned and produced independently of each other, a lot more design, construction and variation possibilities arise in practice, whereby the desired adaptation to practical requirements can be better achieved. than in the previous case with elements such as the known hollow tubular elements, which fulfill the two functions called simultaneously.

[0020] A corresponding division into several first tangentially deformable elements and several second rigid elements is basically also provided in JP 5309001 mentioned above. However here, the first and second elements are arranged separately from each other. The first elements are in a first inner zone and the second elements in the dividing zone surrounding the inner zone. Therefore, it may happen that the so-called interior or exterior corridors, which will be discussed in greater detail further below, will be developed exclusively on the hard elements 50, which are arranged in the dividing zone, or that, when development takes place On the center of the sole, practically only the first elements are tensioned and there is a swimming effect here, which is what the present invention wishes to avoid.

[0021] Therefore, the invention ensures that, in the heel area and in the metatarsal area of the sole, areas, which are determined on the one hand by the first elements and, on the other, by at least one second element, alternately alternate in the longitudinal direction (from the heel to the metatarsal area). By this, it is ensured that, while they are developed on the heel and / or on the metatarsal area, both functionalities are always used in a sufficiently close temporal relationship, as well as spatial with each other. Therefore, the 5 characteristics of the sole of the invention correspond largely to those of WO 03/103430.

[0022] Several second elements can be provided and the zones, determined by at least a second element, can, in each case, be formed by one, but also, by several said second elements.

[0023] As the soles, known from WO 03/103430, the soles of the present invention can also be sized so that at least one critical deformation is achieved, locally limited 10 when running, only in the maximum zone tension and, temporarily, only at maximum tension. The at least one critical deformation, in which the sole of the invention is, to say frozen, depends on the type of deformation. A critical deformation can also be achieved in the case of a strictly perpendicular or vertical deformation.

[0024] According to a preferred development of the invention, the critical deformation is achieved only after a tangential and / or vertical deformation path, which is greater than 20% of the deformable thickness of the sole and optionally even greater than 50 % of this thickness. Preferably, the tangential deformability should even correspond approximately to the perpendicular deformability. In absolute terms, it may well increase to approximately 1 cm.

[0025] For the spring and damping paths thus dimensioned, the sole of the invention effectively dampens the forces and stresses that arise when running. In particular, the sole of the invention behaves optimally by damping when touching the ground, since the horizontal forces, which predominate here, can yield smoothly in the direction of travel, by means of a bending effort. During development, the sole of the invention absorbs the predominant vertical forces by a vertical deformation equally well due to a damping action. In addition, it reacts at this stage also by different tangential deformations in 25 different directions of movement between the foot and the floor, which normally manifest themselves in a slip on the foot in the shoe and often lead to friction drilling the socks or even to the formation of blisters. The shoe does not resist the movement that the foot would like to perform with respect to the ground during the development movement. The shoe makes a march largely without fatigue. During the full load in the march phase, on the other hand, the sole of the invention loses its damping properties almost completely. In this phase, damping is no longer required and would only be an obstacle to an effective march. In the march phase, the sole of the invention behaves as if it were "hard".

[0026] The sole wear model, which had been used for some time by different runners, revealed large differences with respect to the predominant tension. This is due to the characteristic walking styles, which are different for individual runners. Differences also arise from the different walking distances 35. For example, short distance runners run predominantly on the front of the feet, there is practically only tension on the metatarsal area. On the other hand, the bottom runners land predominantly on the heel and develop over the entire foot. A differentiation is made here between the so-called external foot corridors and internal foot corridors. The external foot runners land on the outside of the heel, develop over the outer area of the center of the foot and also push in the area of the metatarsal or from the area of the small toes. The situation is the other way around for internal foot runners. There are also mixed forms, which, for example, land on the outside, develop transversely over the center of the foot and push from the area of the big toe and vice versa. The sole of the invention, which can be deformed both vertically, as well as tangentially, as well as forward and backward, can adapt well to these different tensions and participate in the natural movements of the foot. Four. Five

BRIEF EXPLANATIONS OF THE FIGURES

[0027] The invention is explained in greater detail below by means of examples together with the drawing, in which

Figure 1 shows a sneaker in side view with a sole, a) in a relaxed state, b) when there is tension forward at an angle and c) during the push back,

Figure 2 shows first and second elements of the sole of Figure 1 in a detailed schematic representation 50, a) in the relaxed state, b) when there is forward tension at an angle and c) when there is vertical tension,

Figure 3 in a similar representation also shows first and second elements, which, however, are partially fitted and positively fixed in an intermediate sole,

Figure 4 in a similar representation shows an embodiment, for which only the first elements are embedded in an intermediate sole, while the second elements are made of a piece with this intermediate sole,

Figure 5 shows a variation of the embodiment of Figure 4, a) in the relaxed state and, as b), in the tensioned state, the first elements, however, being so deeply embedded in the intermediate sole 5, 4 that the second elements are no longer required, as extra parts,

Figure 6 schematically as a) and b), shows additional variations of the type of Figure 5,

Figure 7 in a detailed schematic representation, shows a continuous layer or stratum, and forming first and second elements, a) relaxed, b) with forward tension at an angle and c) with vertical tension, 10

Figure 8 shows several views of a) to d) of the running surface of the soles of the invention

Figure 9 as a) to e) shows other layers of Figure 7 in the relaxed state.

[0028] Of the figures, only Figure 7 a) to c), Figure 8 d), as well as Figure 9 a) show embodiments of the invention. The other figures are simply for a better understanding of the invention.

MODES OF CARRYING OUT THE INVENTION 15

[0029] Figure 1 shows a running shoe 2, which is equipped with a sole of the invention 1. The sole 1 is formed by a plurality of first hollow elements of profile type 3a, similar to those already known from the document WO 03/103430, as well as for several seconds 3b platform type elements. The hollow elements 3a can have a height, for example, 15 mm and the platform type elements 3b have a height, for example, 10 mm. The hollow elements 3a, as well as the second elements 3b can extend over the entire width of the running shoe 2. However, they can be arranged in several rows close to each other. The platform type elements 3 can also include one or more hollow elements 3a at least partly annularly. The elements 3a, 3b are fixed to the bottom of an intermediate sole 4 of the running shoe 1, for example, by adhesion.

[0030] The hollow elements 3a are prepared from a material, which can be elastically deformed by the tensions that occur during the march. The second elements 3b, as well as the intermediate sole 4, can also have a certain elasticity; however, in comparison with the hollow elements 3a, they are essentially rigid, especially rigid as regards the tangential deformation. In comparison with the platform type elements 3b, the hollow elements 3a are also taller, protruding downwardly therefrom. 30

[0031] Within the meaning of the definition determined above, the hollow elements 3a form in each case first elements or zones defined by them respectively. If several hollow elements 3a are arranged next to each other, they can also be classified together with such area. The situation is similar for the second platform type elements 3b, which in each case form "certain zones through the at least one second element". Consequently, in the longitudinal direction of the sole, the different zones alternate repeatedly in the metatarsal area, as well as in the heel area. If the second platform type elements 3b include one or more hollow elements 3a at least partly in annular form, different zones are arranged, which are also mixed together, on the surface of the sole.

[0032] If the running shoe 2 is produced as shown, for example, in Figure 1b and, when a step is taken, with tension at a front angle as shown by the tension arrow P1, at first only 40 protruding hollow elements 3a come into contact with the floor 5 and deform vertically and also horizontally with elastic tension damping. This deformation is limited by the second adjacent platform type elements 3b, as soon as the hollow elements 3a align with them at the same height. From here, the second platform type elements assume the main part of the tension and, due to its high rigidity already mentioned above, they no longer allow at least any significant tangential displacement of the running shoe with respect to the ground 5. In This phase, the one who wears the running shoe rests firmly and regularly on the ground. In addition, as shown in Figure 1 as c), it can also be pushed once more from the position of Figure 1 c) to perform the next step, without having to accept a loss of distance here, since the second type elements platform can practically not deform horizontally with respect to what can be mentioned in the direction of the new tensions, indicated by the arrow P2, during the 50 thrust.

[0033] In a detailed representation, Figure 2 shows one of the hollow elements 3a, as well as the platform type elements 3b of Figure 1 and, in addition, as a) in the relaxed state and, as b), under a tangential tension As c), a deformation, vertically or perpendicularly downward, is shown, from which it is clear that the advantages explained above are also achieved in terms of stability and thrust without loss of distance in the case. of a strictly vertical tension. 5

[0034] For the sole described previously, the hollow elements 3a allow the desired elastic deformability, while the platform type elements 3b, on the one hand, determine and limit the possible degree of deformation of the hollow elements 3a and, by the other, ensure the desired stiffness of the sole against tangential deformation beyond critical deformation. Since these two functionalities are distributed among different elements, there is a greater degree of freedom of configuration when it comes to these elements. For example, different materials can be used for the first and second elements. The hollow elements 3a no longer need to make a fixed frictional connection under a possible load as in the case of WO 03/103430 and, as a whole, are considerably less tensioned. Above all, they do not have to carry all the dynamic weight and tension on them, it is relieved by the second elements 3b in a degree not yet critical of deformation. It is advantageous if the surfaces of the second elements 3b, which come into contact with the ground, 15 have a good grip on the ground, which can optionally be achieved by a special nature of these surfaces.

[0035] The hollow elements 3a can be characterized as "damping elements" and the platform type elements 3b as support elements.

[0036] The embodiments, which have been explained above, are distinguished by extremely large deformation paths 20, which, between the relaxed state, for example of Figure la) and the state, for example, of Figure 1b) can be amount to more than 20%, and even more than 50% of the vertical projection of the hollow element 3a on the platform type elements 3b. Therefore, the runner therefore floats "like on clouds" and never has a feeling of instability.

[0037] For the embodiments described above, the first and / or second elements 3a, 3b are subjected to quite high alternative loads, for example, due to tangential or bending forces. If they stick strictly with glue, the elements, in the long run, could be detached from the intermediate sole 4. Here, an improvement can be achieved, for example, by fitting in part and, optionally, by positively anchoring also elements 3a and / or 3b in the midsole 4, as shown in Figure 3 for one of the hollow elements 3a and two of the platform type elements 3b. 30

[0038] Figure 4 shows an embodiment, for which only the hollow element 3a shown is fitted in the intermediate sole 4. On the other hand, the two elements 3b are constructed in one piece with the intermediate sole 4 and fully molded thereto. directly. In addition, the hollow element 3a is anchored even better with the intermediate sole by a dovetail joint.

[0039] A variation of the embodiment of Figure 4 is shown in Figure 5 and, in addition, in a relaxed state as 35 a) and in the tension state as b). The hollow elements 3a are embedded here so deeply in the intermediate sole 4, that second protruding platform-type elements, such as the elements 3b described above, are no longer required at all and therefore are not formed either. For this construction, the "normal" surface 4.1 of the intermediate sole 4 assumes the function of the second elements described above 3b. So that the hollow elements 3a can be deformed "lowered", that is to say at an angle 40 in the depression 4.2, in which they are arranged, until they are aligned with the surface 4.1 of the intermediate sole, the depressions 4.2 must be sufficiently constructed wide and large, as also shown in figure 5.

[0040] As a) and b), Figure 6 shows additional variations of the type of Figure 5, for which the first elements 3a are also fitted relatively deep in the intermediate sole 4 and for which the "normal" surface 4.1 of the intermediate sole 4 assumes the function of said second elements 3b described above. The individual variations of Figure 6 differ only in the construction of the first elements 3a. On the left side of Figure 6, in each case the relaxed state is shown and, on the right side, the state with tension in the critical deformation phase.

[0041] For the construction of Figure 6a), the first element 3a, which can be deformed, for example, at an angle or tangentially, is constructed in the form of a pin. The groove 4.2 can, for example, be built around it. Everywhere, the edge of the slit is the same distance from the pin 3a, which is arranged in the center of the slit, as shown in the two detailed representations in the lower part of Figure 6a).

[0042] For the construction of Figure 6b), the deformable element 3a is constructed in the form of a small tube, which is arranged with its axis perpendicular to the intermediate sole 4. Otherwise, the construction and representation correspond to those of Figure 6a).

[0043] As a), Figure 7 shows a layer or stratum 6 of an elastically deformable material, in which first elements 6a and second elements 6b are formed as an alternative in a relaxed state. This layer 6 5 can be produced in one piece and as a large piece. The same sequence of first elements 6a and second elements 6b can be provided in the direction perpendicular to the plane of the drawing, so that a structure results, for which each first element is surrounded by four second elements and vice versa. The first and second elements are then mixed together again, as already analyzed. The pieces of this layer, suitably cut to size, can be attached by adhesion, for example, to the lower side 10 of a sneaker or of the midsole 4 of the running shoe 2 of Figure 1, shown schematically in Figure 8 as a).

[0044] The first elements 6a are in the form of truncated cones, are hollow and somewhat higher than elements 6b, which consist of a solid material and are also in the form of a truncated cone. Like the first elements that have been previously described 3a, the first elements 6a are relatively soft and 15 can be deformed tangentially back and forth, as well as vertically. Due to their rotationally symmetrical shape, the first elements 6a can even be tangentially deformed in the same way in all directions, which can also be advantageous in relation to the desired developmental action behavior.

[0045] In comparison, the second elements 6b are essentially rigid and functionally correspond to the second elements described above 3b). Elements 6a and 6b may be smaller than elements 3a and 3b. For example, the height hl of the total layer 6 and, with it, the first element 6a can be 8 to 12 mm and preferably 10 mm and the height h2 of the second elements 6b maybe 4 to 8 mm and preferably 6 mm The thickness of the layer 6 in the transition zone between the first and second elements may be, for example, 2 mm, the thickness of the lower part of the first elements 6a, however, preferably being greater than 2 mm. The horizontal distance between the centers of the first and second elements 6a, 6b, for example, can be 10 to 20 mm and preferably 15 mm.

[0046] As b), Figure 7 shows the layers 6 loaded at an angle on a floor 5. The first elements 6a deform vertically under this load, especially, however, tangentially or horizontally and no longer protrude over the second elements 6b. Further deformation of the first elements 6a 30 by the second elements 6b is avoided. The distances of the first and second elements are preferably selected to have such magnitude, that the first elements 6a can reach the deformation shown. The degree of the tangential deformation path before it reaches the critical deformation is larger here than in the possible vertical deformation path and, for the dimensions given above, amounts to at least 5 mm in absolute terms. 35

[0047] As c), Figure 7 shows layer 6 in a vertical load.

[0048] The elasticity of the first elements 6a should be selected so that the critical deformation occurs at a load of approximately 1 kg to 10 kg. This value depends on the number of elements and their arrangement on the surface of the sole (local density), the desired damping and the weight of the runner. With its weight (optionally dynamic), the runner, at least while pushing, must be able to cause critical deformation. This is provided for all possible embodiments of soles of the invention and also correspondingly for elements of the type of elements 3a. A different compliance or a different number of first 3rd / 6th elements must be selected for small shoes (a smaller weight runner) and for larger shoes (a larger weight runner). For the first elements of the type of elements 3a, a number of 8 to 15 elements, distributed over the heel and the metatarsal area, is usually sufficient. 45 Due to its smaller size, more than 20 first elements of type 6a are usually required.

[0049] There is additionally a configuration latitude with respect to the shape of the first elements 6a and second elements 6b of the layer 6 of Figure 7 and their arrangement with each other. For example, the second elements 6b can be constructed perpendicular to the drawing plane as elongated ribs, platforms with regular or irregular shape, or the like, as shown in Figure 8 as b) and c). The second elements 6b, according to the invention form a coherent surface, in which the first elements 6a are arranged in a dispersed manner, as shown in Figure 8 as d).

[0050] From the geometries, shown in Figure 8, it is evident that the first elements 6a are arranged mixed with the second elements 6b, regularly fitted between the second elements 6b and, by these means, protected against excessive load With high abrasion. Along each possible development path, the first and second elements are also tensioned by these means in each case in a narrow, as well as temporal, spatial sequence, so that the behavior of the sole and the sensation of running are determined

Always for both elements. The mixed distribution of the first and second elements also extends over the total heel and metatarsal areas.

[0051] In the transition zone between the heel and the metatarsal, first and second elements are not usually required. Therefore, it is usually sufficient for most applications if the layers 6 are arranged separately in each case only in the heel and metatarsal areas. On the other hand, or in addition to a transverse division with respect to the longitudinal direction of the shoe, a longitudinal division can also be made. A longitudinal and transverse division with four layers 6 is shown in Figure 8 as c). By these means, adaptations to different shoe sizes with conventional elements could also be achieved, in which these are simply arranged properly, especially closer or further from each other. Finally, different layers with different properties could be provided in different areas. 10

[0052] The zones, which have been presented above and which are determined by at least a first element or by at least a second element, can be compared in the embodiments of Figure 8 with the first elements 6a and with the second elements 6b respectively . In the example of Figure 8b), the first several elements 6a, which are arranged close to each other in the transverse direction, can also be counted as a single zone. On the contrary, the coherent surface 6b) in the example of Figure 8d) can be considered as formed by several zones, which alternate in the longitudinal direction with the first elements 6a or with zones formed by these elements.

[0053] Next, possible additional configurations of layers 6 are described by means of Figure 9 as a) to e).

[0054] For layer 6, shown in Figure 9 as a), the first elements 6a correspond to those of Figure 20 7. The second elements 6b are provided with a rectangular cross-section.

[0055] For the layer, shown as b), the first elements 6a are made of a solid material; however, they have a thin head and a narrower neck and, therefore, can deform well laterally in all directions, as well as tangentially.

[0056] For the embodiments, shown as c) and d), the first elements 6a are formed by dimensionally stable knots 25, which are connected on a type of an elastically deformable membrane with the second elements 6b and, by these means, can be deflected in vertical, as well as, to approximately the same degree, in horizontal.

[0057] For the version, shown as e), two elastic strata are joined together, at least the continuous and relatively flat outer layer being joined except for the grooves. The grooves, together with the approximately opposite similar projections 30 of the inner layer, form the first elements 6a. The slits, in addition, in the form of a damper, allow the different first elements 6a to be simultaneously deformed tangentially in different directions. The second elements 6b are formed by the outer layer between the grooves and the lower platforms or ribs, as shown, by way of example, in Figure 9a). 35

[0058] Within the scope of the foregoing specification, only a few exemplary embodiments have been described. Of course, additional embodiments are possible and can be obtained, in particular, from mixed forms of the described examples.

List of reference numbers

[0059] 40

1 sole

2 running shoe

3rd First elements, hollow elements

3b Second elements, platform type elements

4 Midsole 45

4.1 Midsole surface

4.2 Middle sole groove

5 Floor

6 Layer or layer

6a First elements of layer 6

6b Second elements of layer 6 5

P1 Arrow indicating tension when taking a step

P2 Arrow indicating tension when pushing

hl Height of the entire layer 6

h2 Height of the second elements 6b

10

Claims (9)

1. A sole, in particular for sports shoes, which has elastic deformability also in the forward and backward tangential direction, and which is only substantially rigid in view of the tangential deformation beyond a critical deformation in the area so far deformed, in this document its elastic deformability also in the tangential direction, is effected by a plurality of first elements (6a) and its stiffness indicated in view of the tangential deformation beyond this at least one critical deformation and the degree of at least one critical deformation in the zone so far deformed is effected by at least a second element (6b), and herein the zones determined by the first elements and the zones determined by the at least a second element in the zone of the heel and in the metatarsal area of the sole foot in each case, alternate several times 10 in the longitudinal direction and in the transverse direction, characterized in that the first elements have the shape of truncated cones, are rotationally symmetrical and, therefore, are tangentially deformable in the same way in all directions, the first elements are hollow and also deformable until critical deformation with exclusively vertical load, the at least a second element in the heel and the metatarsal area of the foot in each case, forms an intrinsically contiguous surface 15 in which the first elements, in each case, are arranged in a dispersed manner, and the First elements are arranged in grooves of the intrinsically contiguous surfaces in the heel and the metatarsal area of the foot in such a way that they project in relation to these surfaces and, in each case, can also be deformed at an angle with respect to these grooves. 2. The sole as indicated in claim 1, characterized in that the first elements (6a) are projected in relation to at least the second element (6b) until at least the critical deformation is reached. 3. The sole as indicated in one of claims 1 or 2, characterized in that, beyond at least one critical deformation, the first elements (6a) are in line with the at least a second element (6b) in the area so far deformed. 25 4. The sole as indicated in one of claims 1-3, characterized in that the at least a second element (6b) is not loaded in the zone so far deformed until the at least one critical deformation is reached. 5. The sole as indicated in one of claims 1-4, characterized in that the first elements (6a) and / or the at least a second element (6b) are (n) fixed on the lower face of an intermediate sole 30. 6. The sole as indicated in one of claims 1-5, characterized in that the first elements (6a) and / or the at least a second element (6b) are (n) embedded in the lower face of an intermediate sole. 7. The sole as indicated in one of claims 1-6, characterized in that the first 35 elements (6a) and / or the at least a second element (6b) are formed as part of An intermediate sole. 8. The sole as indicated in one of claims 1-7, characterized in that the critical deformation is only achieved after a tangential and / or vertical deformation path that is greater than 20% of its deformable thickness, in particular , even more than 50% of this thickness. 40 9. The sole as indicated in one of claims 1-8, characterized in that the extent of the possible tangential deformation path until the critical deformation is reached is approximately equal to the vertical deformation path until the critical deformation