EP2547227A1

EP2547227A1 - Shoe sole and shoe

Info

Publication number: EP2547227A1
Application number: EP11710661A
Authority: EP
Inventors: Dominic Von Roll
Original assignee: Rolnic GmbH
Current assignee: Rolnic GmbH
Priority date: 2010-03-19
Filing date: 2011-03-17
Publication date: 2013-01-23
Also published as: CH702899A1; WO2011113171A1

Abstract

The shoe sole according to the invention has a flexible outsole (5), which is, for example, waterproof and protects the further elements of the shoe sole from water and/or sharp objects and makes the shoe slip-resistant. The outsole may have a drawn-up edge (5.1): furthermore, the shoe sole has an intermediate sole. The intermediate sole has a carrier (7, 8) with a plurality of clearances, which, for example, pass right through from the outside to the inside. The carrier is elastically compressible. Arranged in the clearances are pin elements (9), the elastic compressibility of which is at least (significantly) less than the compressibility of the carrier, wherein optionally the pin elements are substantially not elastically compressible at all.

Description

SHOE SOLE AND SHOE

The invention relates to a shoe sole and a shoe.

It is known to provide shoes with soles, which perform additional functions in addition to the protection and support function for the foot. For example, shoe soles are known, which have specially designed means to absorb larger impact or pressure loads so that the foot and the entire musculoskeletal system of the shoe wearer are spared. An example of such a shoe sole is shown in DE 10 2006 025 990.

There are also insoles which have orthopedic purposes such as the gentle correction of a malposition or the avoidance of stress after surgery or an accident. Insoles of this type are known from DE 203 14 683 and EP 1 797 785.

On the other hand, for example, insoles are known that have nubs or similar structures according to the aspects of foot reflexology or foot reflexology therapy, which are designed to stimulate the sole of the foot. As examples of such insoles are mentioned in DE 44 06 063, US 2004/0000076, US 6,71 5,221 and DE 35 20 956 embodiments mentioned. The aforementioned insoles are made of flexible material and have recess for the different pin elements. Insoles can be placed in various shoes and worn, where they are placed on the shoe sole - including insole - and do not come into contact with the ground. For certain applications shoes are also known, which have only a thin, flexible sole so that bumps for the wearer are immediately felt. These shoes - for example, as 'barefoot shoes' are available on the market - also have the advantage that they allow a sensitization of the Fusssehsorik and a better training of the postural muscles. However, such shoes have the disadvantage that they are unfavorable due to fashionable aspects and unsuitable for walking or running on hard and / or uneven surfaces due to low shock, support and insulation properties.

It is an object of the invention to provide a shoe sole and a shoe which overcome disadvantages of existing shoe soles, insoles and shoes, a reinforced feel of the foot for which the pad (the ground) allow, but also versatile in work, sport and everyday life are suitable for walking and running on a variety of documents.

This object is achieved by the invention as defined in the patent claims.

The shoe sole according to the invention has a flexible outsole which is, for example, waterproof and protects the further elements of the shoe sole from water and / or pointed objects and makes the shoe non-slip. The outsole may have a raised edge. In addition, the shoe sole has a midsole. The midsole has a carrier with a plurality of recesses, which are continuous, for example, from the outside inwards. The carrier is elastically compressible. In the recesses are Pin elements arranged whose elastic compressibility is at least (substantially) smaller than the compressibility of the carrier, wherein the pin elements are optionally substantially not elastically compressible. The pin elements are interconnected or not interconnected at most in smaller subgroups and / or by an elastic, flexible element - for example, the outsole or the pins for easier handling during manufacture connecting membrane or a network or the like - connected to each other. The pin elements are substantially directly (directly) on the outsole, without intervening, stress-balancing elements such as insoles or the like. They have the effect of passing unevenness to the floor surface in a controlled manner: a small elevation under the outsole - such as can be formed by a pebble on a paved road or a tree root on a natural path - guides one or more the pin elements inward, making the unevenness felt by the wearer and accordingly stimulates the foot base when walking or running. It also stimulates the holding muscles. The body receives information and stimuli that come close to walking barefoot. The term "pin element" does not necessarily imply that the elements are in the form of cylindrical pins, even if such a cylindrical shape is suitable, but rather the pin elements may have any cross-sectional shapes.

The pin elements thus allow the transmission of the impact forces by a thin and in particular by a thick shoe sole. The number of pin elements and their size (in cross-section) can be adapted to the needs of the shoe wearer. In many embodiments, the number of pin elements will be between 30 and 500, in particular between 40 and 300. The pin elements can each be in one piece or joined together from several pieces of material of the same or different composition. Depending on the size and number of pin elements, more or less of the material / materials of the carrier may be present between the pins; In principle, it is also possible that at least partially the pins abut each other directly and the carrier material completely disappears there.

The wearer may have a total elasticity which is similar to that of a midsole of known shoes and flat on the sole acting impulses - as they arise, for example, when racing on a paved road - in a known way receives and partially absorbed. For this purpose, optionally, the length of the pin elements may be slightly smaller than the thickness of the compressible carrier when it is not pressure loaded. It is also possible that the carrier is constructed of several layers, of which a carrier layer performs the function of a known midsole.

The elasticity of the carrier is, as mentioned, greater than the elasticity of the pin elements. However, this does not mean that in a multi-layered structure of the carrier, each individual layer will necessarily be more elastic than the pin elements, although this will be the case in many embodiments. Rather, the teaching concerning the elasticity of the wearer relates to the overall elasticity.

The carrier may be continuous over the entire foot surface, or it may, for example, have two or more separate sections, for example a heel part and a forefoot part.

Due to the function of the wearer, despite the perceived barefoot walking, the advantages of known, supporting and protective footwear are completely present. Very large bumps are compensated. The shoe sole also provides protection against objects that could cause injury. Flat impacts and loads are absorbed and distributed by the wearer.

In addition, given the limited elasticity of the carrier and a limited relative deflection of the pin elements relative to the inner surface of the carrier, which allows in contrast to barefoot walking in an advantageous manner maximum load on the shoe bottom. The carrier may have a plurality of carrier layers. According to a group of particularly advantageous embodiments, the carrier may comprise, for example, an outer, elastically compressible intermediate layer which is connected to the outer sole or rests against it, wherein optionally a thin element connecting the pins (membrane, net etc.) is located therebetween. On the inside of the elastically compressible intermediate layer is an inner carrier layer which, for example, is substantially less elastically compressible and supports the foot like a conventional midsole, thereby guiding the pin elements. The thickness of the elastically compressible intermediate layer - this can be constant or not constant over the foot surface - determines the locally possible maximum deflection of the pin elements.

The inner, less elastic carrier layer absorbs flat bumps and distributes the static load when standing or walking. The cushioning and comfort effect can be as in a conventional, optimized for comfort and minimal stress on the musculoskeletal shoe sole. The elasticity of the outer, elastically compressible intermediate layer is chosen so that it is compressed by the surface load under the weight of the shoe wearer only to a smaller percentage. The pin length can be selected accordingly so that in this compression under 'static' conditions with only flat load the pins not yet or not substantially inside of the carrier protrude. On the other hand, in the case of punctual loading - due to unevenness - under locally correspondingly higher pressure, the intermediate layer is locally compressed, and therefore one or more of the pin elements is locally pressed inwards and project beyond the carrier on the inside. This is done without the area-supporting effect of the inner support layer is impaired. The foot is supported as in the condition with no punctiform load, but the feeling for the shoe wearer is that of a barefoot walking.

A further advantage of a multilayer construction is that the maximum deflection of the pin elements can be influenced and limited by the choice of the layer thickness of the intermediate layer. Provided that the carrier layer is not or only slightly compressed during the load, the maximum deflection is at most equal to the thickness of the compressible intermediate layer. This allows a targeted adjustment of the effect of the pin elements. The maximum deflection can also be varied, distributed from shoe to shoe or even over the surface of a specific shoe (for example different deflections in the heel area, foot ball area, in the area of the longitudinal arch of the foot, etc.).

The elasticity of the intermediate layer-similar considerations also apply to the case where the carrier is homogeneous, ie single-layered or composed of several layers of similar elasticity-is thus advantageously chosen so that it is only insignificantly compressed under the pressure load applied under normal conditions in the shoe , When an adult is standing still, the heel and foot pad load is generally of the order of 50 kPa (these are just orders of magnitude - they may vary by factors depending on the physique or situation). When walking or running - on a still flat surface - the load can also be a multiple of it for a short time. If, for example, the shoe is placed on a pebble and loaded with the weight of the shoe wearer, it is locally at the location of the pebble on the pebble Shoe sole acting pressure markedly higher, for example, of the order 1 0 MPa. The intermediate layer can therefore be chosen so that it yields only slightly at pressures of 50 kPa, but yields pressures of the order of 10 MPa very well. The intermediate layer can thus - depending on the situation and the user - for example be chosen so that the modulus of elasticity (based on the compressive load, or in a linear approximation corresponding to the tensile modulus (Young's modulus)) of the order of, for example. Between 0.2 MPa and 10 MPa is. For shoe soles for adults, a range of about 0.3 MPa to 2 MPa is particularly favorable.

Both the carrier layer (if present) and the pin elements should have a significantly higher modulus of elasticity, for example at least 2 MPa, at least 3 MPa or at least 5 MPa (carrier layer) or at least 5 MPa or at least 20 MPa (pin elements). In particular, however, the modulus of elasticity of the pin elements can also be markedly higher and optionally exceed 100 MPa. The elasticity of the carrier layer is generally chosen so that the carrier layer is still easily bendable. By contrast, the pin elements can feel stiff and hard and, in many embodiments, are significantly less elastic than the carrier layer.

Another measure of elasticity modulus for the properties of the materials used is Shore Hardness. The intermediate layer has a Shore hardness of preferably between 10 and 40 Shore A, particularly preferably between 12 and 30 Shore A. The hardness of the carrier layer is preferably between 30 and 100 Shore A, particularly preferably between 40 and 80 Shore A, in particular between 45 and 70 Shore A. The hardness of the pin elements is preferably at least 70 Shore A. Another possibility - in addition to the elasticity and thickness of the carrier or of its intermediate layer - to influence the felt effect of the pin elements consists in the design of the inner pin ends. These may be rounded in various ways, and optionally may be slimmed at the inside end (they then feel sharper, with a consequently intensified perception) or, according to another option, at the inside end may be provided with heads that increase the area of action (then they feel flatter, with a consequently gentler-feeling effect). The different design of the inner pin ends leads to a variety of pin element shapes. Thus, a pin element can be configured overall, for example in the form of a mushroom or a wedge. A mushroom-shaped pin element has a cylindrical shaft, for example, and a head mounted on the inner end of the shaft. The head may have the shape of an inwardly curved hemisphere. A wedge-shaped pin element has a widening inwardly, for example, conical shape. The inside end of the mushroom-shaped or wedge-shaped pin element may be flat or rounded. The respective pin element shapes may have a wide variety of cross sections (perpendicular to the bottom surface), for example, round or square. If the pin elements have a mushroom-shaped or similar shape with a shank and a broader head that adjoins the shank, or else a wedge shape, the heads or inner ends of the pin elements can abut one another directly at least in some areas. You can even form the entire surface or areas of the surface on which the foot rests - so the foot is then at least partially no longer in contact with the wearer. In this case, the entirety of the inner pin ends forms a closed surface which corresponds approximately to the foot area or areas thereof. The carrier extends, for example, to just below the respective head or to the inner end of the respective shaft. In this embodiment, with directly abutting heads / inner ends of the carrier can in particular consist of the outer, elastically compressible intermediate layer and thus do without inner, less elastic support layer - the foot supporting layer is formed by the heads / inner ends of the pin elements themselves.

An important element of embodiments of the present invention is the 'barefoot' feel: the foot is to be given a feel for the pad, and information about bumps, etc., should be transmitted to the foot as directly as possible without the risk of pinching To hurt objects, edges or the like. For this purpose, it is preferred that the outsole and the pin elements are designed and cooperate in such a way that the pins can also be deflected individually. This requires, for example, that the pin elements are not firmly connected to the carrier. In addition, the individual pin elements are not interconnected or only in small groups or over a very thin outsole (as described on the following pages). In addition, they are designed at their outer end in such a way that they can move more or less freely inward in the carrier and, for example, free from external anchorages. Such anchorages which are wider than a pin shaft are, for example, known from insoles and cause them in that a pin is not relative to the sole in which it is embedded, can be deflected. In addition, the deflectability of the pins individually also requires that the outsole has not too high rigidity. Preferably, for this purpose, the thickness of the outsole is at most 4 mm. The deflectability of the pins individually has the consequence that small bumps only a pin element and large bumps press several pin elements inwards, where they protrude beyond the carrier.

Of course, the configuration of the inner pin ends or the configuration of the pin element as a whole may be different from shoe model to shoe model and also distributed within a shoe over the surface and optionally over the raised edge. In order to make the ground condition noticeable even when putting on the foot, it is possible to provide the outsole with a raised edge on the side and / or front and / or in the heel area. In the area of this raised edge, the pins are arranged at an angle to the foot surface, for example, always approximately at right angles to the sole. The wearer can follow the shape of the outsole while optionally becoming continuously thinner and leaking towards the outside. The guided in the carrier pin elements can be accordingly shorter to the outside accordingly. As soon as the shoe wearer puts on the foot - this is usually done first with the heel -, the corresponding pin element is deflected and thus the corresponding pressures on the elements and makes them deflect to the foot. So the shoe wearer feels the ground conditions early, which increases the feeling of walking barefoot.

Optionally, on the inside of the midsole can still rest an insole, which is also flexible, ie bendable and / or elastic. However, such an insole is optional, and preferred embodiments of the invention will do without such an insole (or insole). The term "midsole" thus does not imply the necessity of an additional insole or insole.Furthermore, it should be mentioned here that the "midsole" in the context of the present invention is not an insole of the kind known from the prior art , It does not make sense and generally not possible to put them in a conventional sports or other shoe. Rather, it must interact with a (thin) outsole of the type described, and directly and without intervening insole or the like. This is because, in contrast to the prior art - including insoles for foot reflexology or the like - the effect of outside on the shoe occurring bumps not distributed as possible on the foot surface but on the contrary deliberately forwarded locally to the footing. Depending on the embodiment, however, the midsole may be removable as a whole. The pin elements are generally not connected (glued) to the carrier or at least not to the inner carrier layer of the carrier. But they are - at least if there is no insole - preferably connected to the flexible outsole, so they can not fall out. They can, for example, be glued to the outsole. According to a specific embodiment, they may also be integral with the outsole, ie they may be formed as protrusions of the outsole projecting towards the inside and, for example, molded in one single step by injection molding or in another molding process with the outsole. In spite of the hardness of the material required for the pin element, in order to have the necessary flexibility, the outer sole should be correspondingly thin in such a case. It is generally advisable to choose an outsole of a thickness of at most 5 mm, in particular at most 4 mm, preferably between 2 mm and 3.5 mm. Such a thin outer sole has the advantage that the normal force locally can be passed almost 1: 1 to the foot surface and no or only a slight attenuation occurs. The outsole may also be multi-layered, in which case the pin elements may be integral with an inner layer of the outsole, or the pin elements may possibly project through an inner layer of the outsole by piercing corresponding recesses. For example, production purposes, the pin elements can be connected to a membrane or a network, which holds the pin member together and thus substantially facilitates the introduction into the carrier layer. The net with the pin elements mounted thereon is preferably mounted on or connected to the inside of the outsole.

The invention also relates to a shoe provided with a shoe sole of the type described above. It should be noted that the connection of the shaft with the shoe sole according to the invention takes place over the raised edge, whereas the prior art teaches the shaft from the outside pull it under the insole, leaving the edge area parallel to the walking area. There, the shaft is sewn (in this regard, various techniques are known) or glued. Such attachment of the shaft is generally not provided in connection with shoe soles according to the invention. Rather, according to a first possibility, the edge region of the shaft lies flat against the raised edge of the outer sole and is sewn thereto and / or glued - ie. the one below the end of the shaft is "vertical" instead of "horizontal" (in relation to the walking area). According to another possibility, especially if the shoe sole does not have a raised edge, the connection is made edge to edge on the outer edge of the outsole. It is dispensed in both cases on the tensioning of an insole on the inventive shoe sole. Other types of processing are possible. Embodiments of the invention will be explained in more detail with reference to figures. The figures are not to scale. In the figures, like reference characters designate like or analogous elements. Show it:

- Figures 1 and 2 each have a cross section through an embodiment of an inventive shoe sole;

FIG. 3 shows a cross section corresponding to FIG. 1, in which a foot of a shoe wearer is also shown schematically;

FIG. 4 shows an exploded view of a shoe designed according to the invention;

FIG. 5 shows a cross section of a variant of a shoe sole; and

Figures 6-9 each have a longitudinal section through embodiments of a shoe sole. Figure 1 shows schematically a section through an embodiment of a shoe sole 1, which is parked on a flat surface 3. The flexible outsole 5 can be made of a conventional, for shoe outer soles known per se high-quality rubber compound. It can, as indicated in the figures, have an external profiling. The outsole also has a raised on both sides (and, for example, each at the front and rear end) edge 5.1.

The midsole has in the illustrated embodiment, a two-layer support in which the pin elements 9 are embedded. An outer intermediate layer 7 of the carrier is glued to the outer sole 5 and elastically compressible. The Shore hardness of the intermediate layer 7 may be, for example, between 10 and 40 Shore A, i. the intermediate layer may feel resiliently soft, yet provide sufficient resistance to compression force to not be fully compressed when loaded with the body weight of a user as a whole. According to one embodiment of the invention, the material of the outer layer is poron (urethanes) of Rogers Corporation (e.g., Poron MF; Poron Medical 4708 urethane) having a Shore Hardness of 60-70 Shore OO, depending on density Hardness of about 15-20 Shore A. But there are also other comparatively soft materials, especially plastic materials, conceivable, which have the property that they assume the original form even after many load impulses over a long time.

The second inner layer 8 (carrier layer) of the carrier is glued, for example, to the intermediate layer 7. It is made of a material or composite material, which has a much greater rigidity than the outer layer. The Shore hardness of the carrier layer 8 may for example be between 30 and 100 Shore A, in particular between 40 and 80 Shore A. In one example, the Carrier layer 8 made of an ethylene-vinyl acetate (EVA) with a Shore hardness of about 58 Shore A.

The pin elements 9 are not adhesively bonded to the inner layer 8 and preferably also not to the outer layer 8 but are guided displaceably in the corresponding through opening formed by the intermediate layer and the carrier layer. However, the pin elements may be glued to the outsole 5. The pin elements are made of comparatively dimensionally stable material whose elasticity is significantly less than that of the outer layer 7 at least. The pin elements may be, for example, polyethylene (PE) having a Shore hardness of more than 80 Shore A, for example between 50 and 80 Shore D, polypropylene, a hard rubber compound or any other suitable material.

The mode of operation of the shoe sole according to FIG. 1 is illustrated in FIGS. 2 and 3. FIG. 3 diagrammatically shows a heel region of a foot 21 of a person projecting on the shoe sole. If the shoe sole is placed under load on a bump 1 1, which is located at the location of the unevenness pin member 9 - it may be more pin elements depending on the size of the unevenness 1 1 - pressed relative to the layers 7, 8 of the carrier upwards , In this case, the soft intermediate layer 7 is compressed in an environment of the upwardly pressed pin member, approximately by an amount corresponding to the deflection of the pin member. This makes the unevenness felt by the person. It is stimulated in the foot area. However, due to the adapted rounded shape of the inner pin ends as well as the limited maximum deflection of the pin members, this can be prevented from causing pain to the user. In Figure 4 can be seen in an exploded view of a shoe. The shoe has, on the one hand, a shoe bottom with a sole 1 of the type described above and, on the other hand, a shoe upper 2 ("shank") .The shoe upper is drawn in the figure in the form of a sneaker shaft, but it is of course also possible to use any other shaft This also includes open, for example, sandal-like, or boot-like constructions.

In the assembled state of the shoe, the pin elements 9 are guided in mutually aligned recesses 7.1, 8.1 of the layers 7, 8 of the carrier.

FIG. 5 shows, in cross-section, a variant of the shoe sole in which the pin elements 9 each have a head 9.1. The heads protrude laterally beyond the shaft of the pin element and define an enlarged, in the illustrated example, rounded bearing surface for the foot. Such pin elements with heads - they may also be present only in some areas, for example. In places with greater sensitivity of the foot - distribute the perceived impulse to a larger foot-part surface and thereby change the ride.

As shown in Figures 6-8, the sole may be configured with heel stroke (Figures 6 and 7) or without heel stroke (Figure 8). Generally, the sole thickness is determined according to the design and shoe size. As shown in Figures 6-8 are different sole thicknesses in different areas - eg heel ball of foot - with advantage through the midsole, that causes the carrier with the pin elements, while the outsole 5 and an optionally existing insole have a uniform or approximately uniform thickness can. In the illustrated embodiment with non-constant sole thickness (Figures 6 and 7), the inner, elastic intermediate layer has an approximately constant layer thickness, so that the entire stroke through different thicknesses of the carrier layer 8 and different lengths of the pin elements 9 are effected. But it would also be possible - regardless of the total midsole thickness - to provide the intermediate layer 7 with a non-constant thickness. As a result, the maximum deflection of the pin elements over the foot surface could be selectively controlled, whereby the maximum deflection in more sensitive areas - for example at the outer edge of the foot and in the area of the longitudinal arch - may be lower, as required, than in less sensitive areas. Due to the arrangement of the pin elements and / or different maximum deflections in different areas, additional or alternatively also other aspects can be taken into account, such as foot reflex zones, etc.

FIG. 9 shows a further embodiment of the shoe sole according to the invention, in which not only the outsole, but also the wearer in the rear heel region 22 has a raised edge 1.2 relative to the walking surface A. The raised edge 1 .2 has a single or multilayer carrier with recesses, which can accommodate pin elements 9. The pin elements are inclined relative to each other and each arranged locally approximately perpendicular to the outsole. In order to allow comfortable wearing of the shoe sole, run in the illustrated embodiment, the raised outsole 5.2, the intermediate layer 7 (in the case of a multi-layered embodiment of the carrier) and the support layer 8 with the recesses towards the top together and so enclose the heel 22. Apart From the raised outsole, the intermediate layer 7 and the carrier layer 8 against the top are always thinner and finally run into the outsole 5 from. The figure below shows the shorter towards the edge pin elements 9, but this is not mandatory. Just as little is it compelling that the one or more parts carrier converges at the top with the outsole. The illustrated embodiment allows the detection of bumps already when placing the foot. If the shoe wearer steps on the foot or heel at an appropriate angle, he feels it Soil quality over the generated pressure of the pin elements on the heel. The shoe wearer is thus made aware of bumps 1 1 early. In addition, this corresponds to the feeling of walking barefoot.

Additionally or alternatively, the edge can be pulled in the front, in the area of Zeherl and / or upwards and provided with corresponding angled pins.

As a further variant, in contrast to the illustrated embodiments, the sole may have a further inner, flexible, for example thin layer, which covers the pin elements and the carrier layers. Such a layer acting as insole may be present to protect the pin elements, the carrier layers and the interface between pin elements and carrier layers from moisture and - with appropriate design / strength of the insole layer; depending on the user's request - also distribute the force acting through the pin elements on a larger area.

The shape of the pin elements is circular cylindrical in the illustrated embodiments, and the cross section is the same for all pin elements. Both are not necessary.

Rather, it is firstly possible to provide the pin elements with other than circular cross-sectional shapes, for example. Elliptical shapes, polygonal basic shapes (eg with rounded or chamfered edges), irregular shapes, etc. this includes non-convex cross-sectional shapes, for example. In cross-section. 8 -shaped or T-shaped pin elements. Second, alternatively or additionally, the cross section of different pin elements may be different, this relates to the cross-sectional shape and / or the size of the cross-sectional area.

Finally, the cylindrical-translationally symmetric of the Stiftelement- forms no need; rather, some or all of the pin elements may, for example, have stepped slightly conical or other shape deviating from translational symmetry; this also includes, for example, ellipsoidal pin element shapes.

Claims

PATE T CLAIMS

Shoe sole (1), comprising a flexible outsole (5) for resting on the ground and a midsole arranged on the inside of the outsole, characterized in that the midsole comprises a carrier with a plurality of recesses (7.1, 8.1), the carrier being elastically compressible is, and that in the recesses pin elements (9) are guided, the elastic compressibility is smaller than the compressibility of the wearer.

Shoe sole according to claim 1, characterized in that the outsole (5) has a raised edge (5.1).

Shoe sole according to one of the preceding claims, characterized in that the outer sole (5) is at most 4 mm thick,

Shoe sole according to one of the preceding claims, characterized in that the pin elements lie directly against the outsole.

Shoe sole according to one of the preceding claims, characterized in that the carrier has an elastically compressible intermediate layer (7) and a carrier layer (8).

6. Shoe sole according to claim 5, characterized in that the intermediate layer (7) on the outside and the carrier layer (8) is arranged on the inside.

7. Shoe sole according to claim 5 or 6, characterized in that the modulus of elasticity of the intermediate layer (7) based on pressure loads between 0.2 MPa and 5 MPa.

Shoe sole according to one of claims 5 to 7, characterized in that the modulus of elasticity of the carrier layer (8) is higher than that of the intermediate layer with respect to pressure loads and is at least 2 MPa.

9. Shoe sole according to one of the preceding claims, characterized in that the modulus of elasticity of the pin elements (9) based on pressure loads is at least 5 MPa.

Shoe sole according to one of the preceding claims, characterized in that at least some of the pin elements (9) have an inside head (9.1).

1 1. Shoe sole according to one of the preceding claims, characterized in that the pin elements (9) are rounded at its inner end.

12. Shoe sole according to one of the preceding claims, characterized in that the pin elements (9) by a outside of the outsole existing unevenness (1 1) are individually and independently deflected.

1 3. Shoe sole according to one of the preceding claims, characterized in that the pin elements (9) are interconnected.

14. Shoe sole according to one of the preceding claims, characterized by an inner side of the wearer lying insole.

1 5. Shoe, comprising a shoe sole according to one of the preceding claims.

16. Shoe according to claim 1 with a shaft (2), wherein the outsole has a raised edge (5. 1), characterized in that the one edge region of the shaft (2) lies flat against the raised edge of the outsole and attached thereto is.