CH702899A1 - Shoe sole and shoe. - Google Patents

Abstract

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 (5.1). In addition, the shoe sole has a midsole. The midsole has a carrier (7, 8) with a plurality of recesses, which are continuous, for example, from the outside to the inside. The carrier is elastically compressible. In the recesses pin elements (9) are 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.

Description

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.

On the other hand, for example, soles are known that have nubs or similar structures according to the aspects of foot reflexology or foot reflexology therapy, which should stimulate the sole of the foot. An example of such a sole is the insole shown in DE 4406 063.

For certain applications shoes are also known, which have only a thin, flexible sole, so that bumps for the shoe wearer are directly noticeable. These shoes - for example, available as barefoot shoes on the market - also have the advantage that they allow a sensitization of the foot sensors 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 and shoes, allow a reinforced feeling of the foot for the ground and at the same time versatile in work, sport and everyday life for walking and running are suitable for a variety of documents.

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

The inventive shoe sole has a flexible outsole, which is for example waterproof and protects the other elements of the shoe sole from water and / or sharp objects and makes the shoe slip resistant. 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 pin elements are 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 connected by an elastic, flexible element - eg. The outsole. The pin elements have the effect that unevenness of the pad in a controlled manner to the foot surface are passed: under the outsole lying small elevation - as can be formed for example by a pebble on a paved road or a tree root on a natural path - directs one or more of 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, although such a cylindrical shape is suitable. Rather, the pin elements may have any cross-sectional shapes. The pin elements are made for example of a polymeric material.

The pin elements thus enable 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 may be present more or less of the material / materials of the carrier 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 carrier may have a total elasticity, which is similar to that of a midsole of known shoes and surface acting on the sole pulses - as they arise, for example, when racing on a paved road - in a known manner 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 separate sections, for example a heel part and a forefoot part.

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

In addition, given by the limited elasticity of the wearer also a limited relative deflection of the pin elements relative to the inner surface of the carrier, which in contrast to the barefoot go on an advantageous way maximum load on the shoe bottom allows.

The carrier may have a plurality of carrier layers. According to a group of particularly advantageous embodiments, the carrier can, for example, have an outer, elastically compressible intermediate layer, which is connected to the outer sole. 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 surface bumps and distributes the static load when standing and 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 still not or not significantly protrude from the inside of the carrier. 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.

Another advantage of a multilayer structure 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 interlayer - similar considerations apply also in the case that the carrier is homogeneous, i. E. one-layered or composed of several layers of similar elasticity - is thus chosen with advantage so that it is only slightly compressed in the pressure applied under normal conditions in the shoe pressure. 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 parked on a pebble and loaded with the weight of the shoe wearer, the pressure acting locally on the pebble at the location of the pebble is markedly higher, for example of the order of 10 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, related to the modulus of elasticity measure of the properties of the materials used is the 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).

Of course, the configuration of the inner pin ends of shoe model to shoe model and distributed within a shoe over the area may be different.

Optionally, on the inside of the midsole may still rest an insole, which is also flexible, i. E. is 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" in this text therefore by no means implies the need for an additional insole or insole.

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 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, i. they may be formed as projections of the outsole projecting towards the inside and, for example, may be formed in one single step using the injection molding method or in another shaping method 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. 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.

The invention also relates to a shoe provided with a shoe sole of the type described above.

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: FIGS. 1 and 2 each show a cross section through an embodiment of a shoe sole according to the invention; FIG. 3 is a cross-sectional view corresponding to FIG. 1, in which a foot of a shoe wearer is also shown schematically; FIG. <tb> - Fig. 4 <sep> an exploded view of a shoe designed according to the invention; <tb> - Fig. 5 <sep> is a cross section of a variant of a shoe sole; and <tb> - Fig. 6-8 <sep> each have a longitudinal section through embodiments of a shoe sole.

Fig. 1 shows schematically a section through an embodiment of a shoe sole 1, which is placed 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 outer layer material is Poron (Urethane) from 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, with 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 be, for example, between 30 and 100 Shore A, in particular between 40 and 80 Shore A. In one example, the carrier layer 8 is made of an ethylene-vinyl acetate (EVA) with a Shore hardness of approx. 58 Shore A made.

The pin elements 9 are not bonded to the inner layer 8 and preferably also not to the outer layer 8 but are guided displaceably in the corresponding formed by the intermediate layer and the carrier layer through opening. 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 8 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 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. When the shoe sole is placed under load on a bump 11, the pin element 9 located at the point of unevenness - depending on the size of the bump 11 - may also be a plurality of pin elements - is pushed up relative to the layers 7, 8 of the carrier. 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 Fig. 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 manner of a sneaker shaft: of course, but also any other shaft can be used; 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 one. in the illustrated example, rounded support 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 FIGS. 6-8, different sole thicknesses in different areas, such as heel-toe balls, are advantageously effected by the midsole, ie, the wearer with the pin members, while the outsole 5 and any insole, if any, have a uniform or approximately uniform thickness can.

In the illustrated exemplary embodiment with a non-constant sole thickness (FIGS. 6 and 7), the inner, elastic intermediate layer has an approximately constant layer thickness, so that the entire stroke is effected by different thicknesses of the carrier layer 8 and different lengths of the pin elements 9. 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, the maximum deflection in more sensitive areas - eg. At the outer edge of the foot and in the longitudinal arch - may be lower than needed 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.

As a further variant, in contrast to the illustrated embodiments, the sole can 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, angular basic shapes (eg with rounded or chamfered edges), irregular shapes, etc. this includes non-convex cross-sectional shapes, eg. 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 pin element shapes is not a necessity; 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 (10)

A shoe sole (1) comprising a flexible outsole (5) and a midsole arranged on the inside of the outsole, characterized in that the midsole has a carrier with a plurality of recesses (7.1, 8.1), the carrier being elastically compressible, and that in the recesses pin elements (9) are guided whose elastic compressibility is smaller than the compressibility of the carrier. 2. Shoe sole according to claim 1, characterized in that the outsole (5) has a raised edge. 3. Shoe sole according to claim] or 2, characterized in that the carrier has an elastically compressible intermediate layer (7) and a carrier layer (8). 4. Shoe sole according to claim 3, characterized in that the intermediate layer (7) on the outside and the carrier layer (8) is arranged on the inside. 5. Shoe sole according to claim 3 or 4, characterized in that the modulus of elasticity of the intermediate layer (7) based on pressure loads between 0.2 MPa and 5 MPa. 6. Shoe sole according to one of claims 3 to 5 characterized in that the modulus of elasticity of the carrier layer (8) based on pressure loads higher than that of the intermediate layer and is at least 2 MPa. 7. 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. 8. 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). 9. Shoe sole according to one of the preceding claims, characterized by an inner side of the wearer lying insole. A shoe comprising a shoe sole according to any one of the preceding claims.