ITMI20130296U1 - FOOTWEAR INCLUDING A PERMEABLE AIR LAYER AND A PERMEABLE AIR PORTION ON A LOWER PERIPHERAL PORTION OF THE UPPER GROUP - Google Patents

Description

DESCRIPTION

The present invention relates to a shoe with an air permeable layer and an air permeable portion in a lower peripheral zone of the upper structure. The air-permeable layer is arranged in a lower area on the sole side of the upper structure above the sole and has a three-dimensional structure, which makes it possible for air to pass at least in the horizontal direction. The at least one air-permeable portion makes it possible for the air-permeable layer to be connected with the external environment in such a way that the air can be exchanged between the external environment and the air-permeable layer .

In previous times the shoes offered in the sole area a certain permeability to water vapor, a characteristic also called breathing activity, as a consequence of the use of materials for the sole such as leather, with the disadvantage of water permeability in the sole area. or the shoes were waterproof thanks to the use of soles of waterproof material such as rubber or plastic materials similar to rubber, but also impermeable to water vapor, with the disadvantage of the accumulation of moisture from perspiration in the area of the sole.

In more recent times, shoes have been made, which in the area of the sole are both impermeable to water and permeable to water vapor, as their soles are perforated with passage or vent openings and the said passage or vent openings they are covered by a membrane impermeable to water and permeable to water vapor arranged on the inner side of the sole, so that water cannot enter from the outside into the inner space of the shoe, and in any case the humidity from perspiration that forms in the area of the sole it can flow from the internal space of the shoe to the outside. Two different types of solutions have been adopted for this purpose. On the one hand, the soles are equipped with vertical passage or vent openings along the entire thickness, through which the humidity from perspiration can be guided or conducted from the internal space of the shoe to the surface in contact with the ground of the sole, or on the other hand, the sole is equipped with horizontal channels, through which the humidity from perspiration that has accumulated above the sole can flow or disperse along the lateral edge of the sole.

Examples of the first solution, according to which the sole has vertical passage or vent openings extending throughout its thickness, are known for example from the document EP 0 382 904 A1. Examples of the second solution, according to which the sole has vent channels parallel to its contact surface with the ground are known for example from EP 0 479 183 B1.

In documents WO 2009/149887 A and WO 2009/149886 A a shoe is described, respectively, which has an upper structure and a sole, wherein the upper structure comprises an upper upper material and a layer permeable to air disposed on the bottom of the upper. upper. The air permeable layer is disposed in a lower area on the sole side of the upper structure above the sole. The alfaria-permeable layer has a three-dimensional structure which allows air to be vented at least in the horizontal direction, and at least one air vent opening is arranged in a lower edge region on the sole side of the upper upper material. connection with the air permeable layer in such a way that air can be exchanged through the air permeable layer between the environment and the air permeable layer. The shoe described in this document is in particular described for the so-called pressure gluing process and therefore suitable only for a predefined use, ie for a predefined type of shoe.

In consideration of these points, a shoe according to claim 1 is made by means of the present invention.

According to an aspect of the present invention, a shoe is described, which comprises: an upper structure and a sole, wherein the upper structure has an upper material of tubular shape, which, in a lower peripheral area, has at least a portion air permeable, as well as an air permeable layer, which is arranged in a lower area on the sole side of the upper structure above the sole, where the air permeable layer is permeable to water vapor and has a three-dimensional structure, which allows the passage of air at least in the horizontal direction, and at least one functional layer permeable to water vapor, which is arranged on the inner side of the upper structure and above the permeable layer all <'> air. The at least one portion permeable to air makes it possible for the air permeable layer to be in connection with the external environment in such a way that air can be exchanged between the external environment and the air permeable layer. A first protective layer permeable to water vapor is arranged between the at least one air permeable portion and the functional layer in at least one zone of the at least one air permeable portion above the air permeable layer , wherein the first protective layer is suitable for protecting the functional layer from particles which could enter through the air-permeable portion. A bottom portion of the tubular shaped upper material extends along the underside of the air permeable layer and contacts the sole, and can be connected with the underside of the air permeable layer and sole .

In this way, a breathable or air-permeable shoe of the type mentioned at the beginning is therefore created according to the so-called moccasin and tubular processing, which offers various disadvantages, such as high flexibility of the shoe when worn.

According to an embodiment of the present invention, the upper material of the tubular shaped upper is closed by means of a seam, which is located on the lower side of the air permeable layer.

According to another embodiment of the present invention, the upper material of the tubular-shaped upper is closed by means of a seam, which is located on an upper side of the upper material of the upper, which faces the instep area.

According to an embodiment of the present invention, the at least one air-permeable portion has at least one air vent opening in the upper upper material, where the air vent opening has a second protective layer permeable to air. '> air. For example, the second protective layer has a net-like structure and offers a protective function against particles, in particular against stones or pebbles.

According to an embodiment of the present invention, the at least one air-permeable portion is made of at least one air-permeable material.

Preferably, the first protective layer is selected from a group of materials consisting of: fabric, knitted fabric, fleece, fibrous materials, porous materials, non-porous materials, foam, mesh-type materials, or a combination thereof.

According to an embodiment of the present invention, the first protective layer extends into a bottom area of the upper structure, which faces the sole, and is located between the functional layer permeable to water vapor and the layer permeable to water. '> air. By way of example, the first protective layer is provided with fixing means, in particular adhesives distributed discontinuously on an upper internal and external surface of the first protective layer.

According to another embodiment of the present invention, the first protective layer extends only in a peripheral or edge area of the upper structure. For example, the first protective layer is provided with fixing systems, in particular with adhesives, distributed discontinuously on an upper internal surface of the first protective layer.

Preferably, the first protective layer is different from the second protective layer.

The first protective layer preferably protects the functional layer from dirt, small particles and wear.

According to an embodiment of the present invention, the shoe has a hull with functional layers of the sock type, which includes at least one functional layer. The at least one functional layer is preferably impermeable to water.

In the following, these and other embodiments of the present invention are described in detail with particular reference to the figures represented in the drawing tables. In the tables:

Figure 1 shows a crosswise perspective view of a first embodiment of a shoe made according to the present invention with different portions permeable to air in the upper upper material;

Figure 2 shows a crosswise perspective view of a further embodiment of a shoe made according to the present invention with different portions permeable to air in the upper upper material;

figure 3 shows a schematic view of a section through a part of the front region of a shoe according to a first embodiment;

figure 4 shows a schematic view of a section through a portion of the front area of a shoe according to a further embodiment;

figure 5 shows a first embodiment of an air permeable layer usable for a shoe according to the present invention;

figure 6 shows a second embodiment of an air permeable layer usable for a shoe according to the present invention;

figure 7 shows a third embodiment of an air permeable layer usable for a shoe according to the present invention;

figure 8 shows a fourth embodiment of an air permeable layer usable for a shoe according to the present invention;

Figure 9 shows a fifth embodiment of an air permeable layer usable for a shoe according to the present invention.

Figure 1 shows a first embodiment example of a shoe 10, which comprises an upper structure 20 with an upper upper material 12 and a ground or bottom 30 disposed on the lower end portion of the upper structure 20, where, for as far as the bottom or ground 30 is concerned, in this case it is a sole. The upper structure 20 usually has an opening for introducing the foot in correspondence with its upper terminal part. The shape of the upper structure corresponds to that of the type of processing commonly called "moccasin" or "tubular". In particular, this presents an upper material 12 of tubular shape, as described in more detail below. In the lower end region of the upper structure 20 there is a plurality of air-permeable portions 14 arranged around a part of the edge or perimeter of the upper structure, said air-permeable portions being shaped according to the present invention. embodiments such as breathable or air vent openings. The air-permeable portions 14 are distributed around the lateral peripheral portion of the upper structure 20 at approximately the same distance from each other. In addition, the albana permeable portions 14, in particular when they are shaped as air permeable openings, are equipped with an air permeable protective layer 26 to prevent the entry of raw particles. The protective layer 26 can cover the air permeable or air vent openings from the outside and / or from the inside.

Each individual air-permeable portion 14 can be assigned a protective layer or a common protective layer extends over all the air-permeable portions 14 (not shown). The protective layer 26 can, for example, be made in the form of a grid or a net.

Figure 2 shows a second embodiment of a shoe 10, which for the most part corresponds to the embodiment shown in Figure 1, but differs from this embodiment as regards the arrangement and shape of the portions permeable to the air or air vent 14. The air-permeable portions 14 of the shoe shown in Figure 2 have a larger shape, are drop-shaped or semi-oval and are uniformly distributed along the edge of the upper in the portion of the lower end of the upper structure.

The air-permeable portions 14 can also be made of a corresponding air-permeable material, which is provided in the positions of the air-permeable portions 14 or extends around the entire edge of the lower area of the upper. . In this way it is possible to obtain a particularly high air exchange between the air-permeable layer and the external environment of the shoe 10 with a correspondingly efficient dispersion of heat and humidity from the internal space of the shoe to the environment. external to the shoe 10. The permeable albana material is for example a component part of the upper upper material. According to one embodiment, it can be in particular a perforated material or in the form of a grid or net, or the upper upper material itself is processed in this lower edge region correspondingly mechanically, such as for example by punching or perforation. As the air permeable material, for example, nets, grids, mesh fabrics, foams with open pores, air permeable fabrics or a combination of said materials can be used. Said materials can for example be formed of vulcanized polyester, polyamide, polyolefins, TPE, TPU.

It is advantageous when at least two air vent openings at least approximately are located opposite each other in the transverse direction of the foot or in the longitudinal direction of the foot. In this way, an air current can be formed through the air permeable layer, which is necessary for the dispersion of water vapor and heat from inside the shoe by convection.

Figure 3 shows an example of a shoe according to an embodiment of the present invention according to a cross-sectional view.

In particular, Figure 3 shows an upper structure and a sole 30, which is fixed to the upper structure and which in the present embodiment comprises only one sole.

In principle, a sole of any type can be used, for example a multi-layered sole with an intermediate sole and with a walking sole fixed thereto. The sole 30 can be a multi-layer sole, as described, or a sole with a single layer of material, as shown. The fixing of the sole 30 to the upper structure 20 can be obtained by gluing the sole 30 to the upper structure 20. The shoe can in any case also be made by fixing the sole 30 to the upper structure 20 by injecting or spraying one or more layers of sole. In this context, any type of fixing of a sole to the upper structure is possible. The sole material is typically impermeable to water and non-permeable to water vapor and humidity and can be made from different types of plastic material, such as all types of rubber, foamy materials, hardened thermo-plastic materials, as well as through natural materials such as leather or other materials, which are generally used for the formation of soles and layers of soles.

The upper structure 20 comprises an upper upper material 12, with a first layered structure arranged on its inner side. For example, a laminate (hereinafter also identified as "first laminate") is used as the first layered structure, which, from the inside to the outside, presents: an internal layer of fabric 17 (so-called "lining"), which it is permeable to water vapor, but in any case not impermeable to water, a functional layer 18, roughly in the form of a membrane, and a layer of fabric 19 as a protective layer for the functional layer 18, which has, for example, a reticular structure (for example nylon), which is permeable to water vapor and allows the penetration of adhesive material. The functional layer 18 is preferably impermeable to water and permeable to water vapor, such as an ePTFE membrane (polytetrafluous polyurethane foam) or a PU (Polyurethane) membrane.

The protective layer 18 can have a porous structure and / or can be a multi-layer product, such as an ePTFE layer with a PU coating (so-called PU-Coating), or an ePTFE layer with a surface treatment. The first laminate, which is formed by the layers 17, 18 and 19 can mainly cover the whole of the upper and lateral upper structure.

The protective layer is not limited to the examples mentioned above, on the contrary it can be formed by fewer or more layers of this type, it can contain one or more membranes, and in the same way alternative solutions to membranes, which perform essentially the same function, as described previously. Also included are membranes of other types to integrate, or other treatments, such as a so-called water repellent treatment (Durabale Water Repellent (DWR).

The upper upper material 12 can be permeable to water vapor and can be made for example with materials such as leather, Polyamide, or other materials, or combinations thereof. The upper upper material forms the visible outer part of the upper structure. The upper upper material 12 surrounds the first laminate with the layers 17, 18:19, with the upper upper material and the first laminate essentially having the same shape, which corresponds to the shape of a foot. The upper upper material 12 and the first laminate are bonded to each other at points where it is needed, particularly in such a way that the waterproof and water vapor permeability characteristics of the upper material combination of upper and first laminate are preserved.

As shown further in FIG. 3, a further layer structure in the form of a second multi-layer material is provided in the area of the bottom of the upper of the upper structure 20.

For example, a laminate (hereinafter also identified as "second laminate") is provided as the second layer material, which essentially has the same layered structure as the first laminate (from the inside out): a layer of fabric 17 (so-called "lining"), which is permeable to water vapor and not impermeable to water, a functional layer 18 preferably impermeable to water and permeable to water vapor, such as an ePTFE membrane or a multi-layer membrane, and a layer of fabric 19 as a protective layer for the functional layer 18, such as a reticular structure (for example Nylon), which is likewise permeable to water vapor and permits the penetration of adhesive material. The second laminate forms in reason of its structure the bottom laminate of the upper.

The lower end of the first laminate and the edge of the second laminate are joined at at least one joint 9, which is for example a seam such as a Strobel seam. Said at least one joint 9 is made impermeable to water by using a joint strip 15, arranged in particular on the side of the joint opposite the foot. The structure joined together and completed with first and second laminates then forms a sock-like structure which is impermeable to water and which is also identified as a functional layered shell and forms a part of the upper structure 20. Functional layers of this type are typically made by sewing together several pieces of laminate, where the seams are typically covered in a waterproof manner, where for example a waterproof seam insulation in the form of an insulating strip is glued to the seam. In this way, an upper structure impermeable to water and permeable to water vapor 20 is made available, in order to obtain, after fixing the sole 30, a shoe that is impermeable to water and permeable to water vapor.

In general, the part facing the upper upper material and the bottom part of the upper of the functional layer 18 can be parts (joined or separated) of a common shell of the functional layer, or they can be separate parts of the functional layer, joined together one to each other and isolated from each other. The part facing the upper upper material and the bottom part of the upper of the functional layer 18 may respectively be part of a multi-layer functional layered laminate, as described above, such as for example a three-layer functional layered laminate, with one functional layer, which is embedded between two layers of fabric.

As further represented in Figure 3, at least one air-permeable layer 16, (which may also have other functions), which is permeable to water vapor, is arranged in a lower area of the upper structure 20 above the sole 30. The air permeable layer 16 is disposed in the lower area on the sole side of the upper structure 20 above the upper upper material in the area of the bottom of the upper and is permeable to water vapor in the direction of the bottom part of the upper. upper of the functional layer 18. The air permeable layer has a three-dimensional structure, which allows the penetration and circulation of air at least in the horizontal direction. In particular, the air permeable layer 16 is arranged below the bottom part of the upper of the functional layer 18.

As further represented in Figure 3, the upper material of the upper 12 has in a peripheral area or lower edge more air-permeable portions 14, where in the present cross-sectional view one of these is represented on each side. In general, each of the air-permeable portions 14 allows the air-permeable layer 16 to be in connection with the external environment in such a way that air can be exchanged horizontally between the external environment and the air-permeable layer. 16 through the air-permeable portions 14. Furthermore, each of the air-permeable portions 14 allows water vapor or moisture to be transported from an inner side of the functional layer 18 (i.e. the side facing the foot) towards the <'> outside in the environment outside the shoe.

According to an embodiment of the present invention, the air-permeable portions 14 respectively have at least one vent opening 24 in the upper material 12. Preferably, the air vent openings 24 respectively comprise a second protective and permeable layer. air 26, which covers the corresponding air vent openings 24. For example, the second protective layer 26 can be joined with the upper upper material 12 by means of a seam or seam 13. In the area of the air vent opening 24 the upper upper material 12 is replaced by the second protective layer 26.

The second protective layer 26 is for example formed by means of a reticular structure of a textile material with high air permeability and high permeability to water vapor. The second protective layer 26 can be arranged outside or inside the corresponding air vent opening 24. Each air vent opening 24 can include its own protective layer 26.

According to other embodiments of the present invention the second protective layer can also be made in the form of a common cover strip to protect some or all of the air vent openings 24, so that the cover strip extends over a number matching of air vent openings 24.

According to an embodiment, one or more of the air vent openings 24 can have a total surface area of at least 500 mm <2>, preferably at least 1000 mm <2>, particularly preferably at least 1500 mm <2>, particularly preferably at least 2000 mm <2>, particularly preferably at least 3000 mm <2>. Preferably, the second protective layer 26 has an air permeability of at least 100 l / m <2> / sec in the presence of a pressure difference of 100 Pa. According to a preferred embodiment of the present invention, the second protective layer 26 has a reticular structure, and has a protective function for protecting against large particles, such as stones or stones and for preventing their penetration through the vent openings of the air 24.

As further represented in Figure 3, a first protective layer permeable to water vapor 22 is arranged between the air-permeable portions 14 and the functional layer 18 in at least one zone of the corresponding air-permeable portion above the air-permeable layer 16. The first protective layer 22, preferably water-repellent and permeable to water vapor, serves as protection of the functional layer 18 from particles, which could penetrate through an air-permeable portion 14. Preferably, the first protective layer 22 is selected from a group of materials consisting of: fabric, knitted fabric, fibrous materials, fleece, porous materials, non-porous materials, foam, lattice-type materials or a combination thereof. According to an embodiment of the present invention, the first protective layer 22 is formed of a fibrous material in the form of a fleece or a cloth and is made hydrophobic, for example by means of a suitable surface treatment.

The first protective layer 22 is optionally joined with the second laminate in such a way that the breathing activity is preserved, for example through the use of a discontinuous adhesive material or through the use of an adhesive material permeable to water vapor.

For example, the first protective layer 22 is optionally joined with the second laminate, i.e. in the present embodiment with the textile layer 19 of the second laminate in the area of the bottom of the upper, which can be made in the form of a net, and with the protective layer 18 through the open structure of the textile layer 19, for example with the help of a discontinuous adhesive material in the form of glue points or particles. In this way, the breathing activity of the entire layered structure is guaranteed in the area of the bottom of the upper.

In the embodiment of Figure 3, the first protective layer 22 similarly extends horizontally in the area of the bottom of the upper of the upper structure 20, which faces the sole 30 and is arranged between the water vapor permeable functional layer 18 and the air-permeable layer 16. Furthermore, according to this embodiment, the protective layer 22 is provided on its inner side and on its outer surface with adhesive material distributed in a discontinuous manner.

The first protective layer 22 can be arranged in such a way that it covers at least most of the bottom surface on the sole side of the functional layer of the bottom of the upper. The first protective layer can also extend at least partially laterally upwards around the edge of the band, so as to extend, as shown, at least in the area of the air vent openings 24. The first protective layer 22 can also completely cover or partially the waterproofing strip of the seam 15, and can even continue to such an extent as to cover at least parts of the lower end of the first laminate, in particular the functional layer 18 in the upper area of the upper in the air-permeable portion 14. The first protective layer 22 advantageously protects the functional layer 18 in the area of the bottom of the upper, which can be shaped in the form of a membrane, as described above, from rubbing, respectively from abrasions, with the air-permeable layer 16 arranged beyond below, since a relative movement of the air-permeable layer 16 and of the functional layer 18 can intervene finish during a walking movement, especially when no gluing of the layers is foreseen. The first protective layer 22 can also have a constitution of a type which is suitable for protecting the functional layer 18 from external influences, which could directly or indirectly affect the functional layer 18 through the air-permeable portion 14.

Preferably, the first protective layer 22 has a water vapor permeability (MVTR) of at least 4 mg / cm <2> / h measured according to ISO 14268 (03-2013). According to a preferred embodiment of the present invention, the first protective layer 22 has a water vapor permeability of at least 25 mg / cm <2> / h.

According to an embodiment of the present invention, the first protective layer 22 can be formed by the textile layer 19 of the first, respectively, of the second laminate.

A main function of the first protective layer 22 is to protect the functional layer 18 from particles, which could penetrate through the air vent opening 14, in particular from dust, dirt and small particles, as well as from wear. , which is exerted for example by the upper upper material 12 and by the second protective layer 26.

Figure 4 shows an example of a shoe according to a further embodiment of the present invention in a cross-sectional view.

The shoe according to figure 4 differs from the example of realization according to figure 3 only as regards the way of making the upper structure. According to the embodiment of Figure 4, the upper material of the tubular-shaped upper 12 is closed by means of a joint 11, which is located on the lower side of the air-permeable layer 16 (so-called tubular processing, as known among those skilled in the art. branch). In this way, the joint 11 for closing the upper upper material 12 is arranged in the bottom portion 120 of the upper upper material 12, so that it assumes a tubular shape. In the embodiment of Figure 3, on the other hand, the upper material of the tubular-shaped upper 12 is closed by means of a joint 11, which is located on the upper side of the upper upper material 12, which faces the instep area ( so-called moccasin-type workmanship, as known among those skilled in the art).

In both embodiments of Figure 3 and Figure 4 the bottom portion 120 of the tubular shaped upper material 12 extends along the underside of the air permeable layer 16 and contacts the sole 30. The bottom portion 120 is further joined with the lower side of the air permeable layer 16 and of the sole 30.

In this way, an air permeable shoe of the type mentioned at the beginning is created according to the moccasin and tubular processing, which offers various advantages, such as high flexibility when worn. A particular feature of the moccasin and tubular workmanship is that there is no separate inner sole under the air permeable layer. In place of this, the lower-most layer of the upper structure is formed by means of the tubular-shaped upper material.

The upper structure is for example formed by a finished structure of upper upper material and a separate and finished structure in functional layers, impermeable to water and permeable to water vapor (Bootie). In this case, the upper upper material structure should be dimensioned in such a way that the functional layered structure (Bootie) can be placed without creases within the upper upper material structure and the air permeable layer can be firmly fixed between the underside of the functional layered structure and the inner side of the upper upper material structure in the bottom of the upper (in order to prevent it from slipping).

Advantageously, the air-permeable portions should be located in the upper material of the upper along the side edge area of the air-permeable layer, they should be mutually oriented, so as to obtain the exchange of air.

An embodiment of a process or method for manufacturing a shoe according to the present invention is described in more detail below.

During a first phase the upper material of the tubular shape (so-called "tubular" or "moccasin" processing system) is cut in the traditional way. In addition, the air permeable layer, the first protective layer and possibly the second protective layer are cut and prepared. During a second step of the process, the upper material of the tubular shaped upper is sewn into the desired shape, as well as the functional layered shell, which is first prepared separately, sewn into the desired shape, waterproofed at the seams and subsequently inserted into the material upper upper. Before the functional layered shell is inserted into the upper upper material, the first protective layer and the air permeable layer are fixed to the bottom of the functional layered shell, for example by means of reticular or point type glues, as described above.

The upper upper material and the functional stratified shell equipped with the first protective layer and the air permeable layer are then inserted one into the other, where the two parts preferably in the foot introduction area, for example at the upper edge of the upper. ) and around the tongue are sewn to each other. Before this is done, it is advantageous that some adhesive material is distributed on the inner side of the upper upper material in the bottom part, so as to well join the functional layered shell with the first protective layer and with the permeable layer at the bottom. air with the rest of the shoe. During a third phase a strip (for example in plastic) is introduced into the upper structure completed in this way (so-called “Slip-Lasting”).

During a fourth step a sole is fixed. For this purpose, the lower side of the bottom of the upper is advantageously rubbed and glue material is distributed over it, in order to glue the sole. For this purpose, use is possibly made of heat and pressure applied to the components of the upper structure and / or of the sole in the usual way.

Alternatively, it is also possible to inject a sole onto the upper structure according to known methods.

During a fifth phase, the completed shoe is separated from the strip and any finishing works are carried out, such as the removal of superfluous materials, etc. (so-called finishing).

Figures 5 to 9 show as examples different embodiments of spacer structures, suitable for the air permeable layer 16 according to the present invention.

All these spacer structures have in common the characteristic of forming or defining two spaced bearing surfaces, where the spacer structure with the lower bearing surface rests on the relative underlying layer and its upper bearing surface acts as a support surface for the layer which it is located above the spacer structure, being in particular the bottom area of the functional layered shell or the functional layer in the bottom of the upper. Both bearing surfaces are both formed each by a surface structure, said surface structures being kept at a mutual distance by a spacer element arranged between them, and at least one of them being permeable to air (Figure 6). Or only the lower support surface is formed by a surface structure, from which spacer elements extend, the free ends of which form support points, which together perform the function of the upper support surface (Figures 5, 7 and 9) . Or there is neither a lower surface structure nor a higher surface structure, but rather a single surface structure, which is shaped in an undulating or zig-zag shape, with lower and upper waves or with indentations, which define the lower bearing surface and the upper bearing surface respectively (figure 8).

In the following, the spacer structures represented in Figures 5 to 9 will be considered more particularly.

According to the embodiment shown in Figure 5, a spacer structure 60 suitable as an air permeable layer is curved upwardly starting from a lower surface structure 64 approximately in the form of semi-spheres, extensions or curvatures 65 le whose tops define an upper support surface. According to an embodiment, this spacer structure 60 consists of a initially flat knitted fabric or of a rigid material, which after having assumed the desired shape, for example by means of a punching process, is rigid or is made rigid so as to maintain this shape also under the load, to which it is subjected during the walk with the shoe that is equipped with this spacer structure. In addition to a punching process, further solutions among those mentioned can also be used, namely deformation and stiffening by means of a thermal formation process or impregnation with a hardenable resin in the desired shape and rigidity.

Figure 6 shows an embodiment example of a spacer structure 60 suitable for an alphial permeable layer 16, the upper and lower bearing surfaces of which are formed by means of two surface structures 62 and 64 which are permeable to air and arranged parallel to each other. , which for example can be selected from the group which includes Polyolefins, Polyamide, Polyester, where the surface structures 62 and 64 are joined to each other in an air permeable way by means of support fibers 66 and at the same time spaced apart. At least part of the fibers 66 is arranged as a spacer at least approximately transversely between the surface structures 62 and 64. The fibers 66 consist of a flexible and deformable material such as polyester or polypropylene. The air can circulate and flow through the surface structures 62 and 64 and through the fibers 66. As regards the surface structures 62 and 64, these are textile materials woven with open pores, knitted or knitted fabrics. A spacer structure of this type 60 can be a spacer structure just named and available from the firm Tylex or Miiller Textil.

The spacer structure 60 shown in Figure 7 has a structure similar to that of the spacer structure shown in Figure 5, except that it consists of a knitted fabric of knitted fibers or knitted filaments, which is shaped in this form, for example by a thermal process or by impregnation with artificial resin and then stiffened in this form.

Figure 8 shows an embodiment of a spacer structure 60 with a zig-zag or saw-tooth profile, shaped in this way starting from a first flat material, so that the upper and lower ridges 60a and 60b respectively define the upper and lower bearing surfaces of this spacer structure 60. The spacer structure 60 of this shape can also be made by means of the aforementioned methods and stiffened so as to have the desired rigidity.

Figure 9 shows a further embodiment example for a spacer structure 60 suitable as an alban permeable layer according to the present invention.

According to this embodiment, the spacer elements are not obtained as extensions or vaulted curvatures of the single surface structure 68, but rather by means of tufts of fibers 70, which rise from the surface structure 68 and whose free ends together define the upper support surface. The fixing or formation of the tufts of fibers 70 can take place by flocking the lower surface structure 68.

Claims (14)

CLAIMS 1. Footwear (10), comprising: a) an upper structure (20) and a sole (30), where b) the upper structure (20) has bl) an upper upper material (12) of tubular shape, which, in a lower peripheral zone, has at least one portion permeable to air (14), b2) an air permeable layer (16), which is arranged in a lower area on the sole side of the upper structure (20) above the sole (30), whereas the air permeable layer (16) is permeable to water vapor and has a three-dimensional structure, which makes it possible for air to pass at least in the horizontal direction, and b3) at least one functional layer (18) permeable to water vapor, which is arranged on the inner side of the upper structure (12) and above the air permeable layer (16), c) where the at least one portion permeable to air (14) makes it possible for the layer permeable to air (16) to be in connection with the external environment in such a way that air can be exchanged between the external environment and the air permeable layer (16), e d) where a first protective layer permeable to water vapor (22) is arranged between the at least one portion permeable to air (14) and the functional layer (18) in at least one zone of the at least one portion permeable to air air (14) above the air permeable layer (16), where the first protective layer (22) is suitable for protecting the functional layer (18) from particles which could enter through the air permeable portion > air (14), e) where a bottom portion (120) of the tubular shaped upper material (12) extends along the underside of the air permeable layer (16) and contacts the sole (30 ), and is connected with the underside of the air permeable layer (16) and of the sole (30). Footwear (10) according to claim 1, wherein the upper material of the tubular shaped upper (12) is closed by means of a seam (11), which is located on the lower side of the permeable albana layer (16). Footwear (10) according to claim 1, wherein the tubular-shaped upper material (12) is closed by a seam (11), which is located on an upper side of the upper upper material, which faces towards the instep area. Footwear (10) according to one of claims 1 to 3, wherein the at least one air-permeable portion (14) has at least one air vent opening (24) in the upper upper material (12), and where the air vent opening (24) has a second protective layer permeable to air (26). Footwear (10) according to claim 4, wherein the second protective layer (26) has a lattice-like structure and offers a protective function against particles, in particular with respect to stones or stones. Footwear (10) according to one of claims 1 to 3, where the at least one air-permeable portion (14) is made of at least one air-permeable material (12). Footwear (10) according to one of claims 1 to 6, where the first protective layer (22) is selected from a group of materials consisting of: fabric, knitted fabric, fleece, fibrous materials, porous materials, non-porous materials, foam, mesh-type materials, or a combination thereof. Footwear (10) according to one of claims 1 to 7, where the first protective layer (22) extends into a bottom area of the upper structure (20), which faces the sole (30), and is located between the functional layer permeable to water vapor (18) and the permeable layer albana (16). Footwear (10) according to claim 8, wherein the first protective layer (22) is equipped with fastening means, in particular adhesives distributed discontinuously on an upper internal and external surface of the first protective layer (22). Footwear (10) according to one of claims 1 to 7, where the first protective layer (22) extends only in a peripheral or edge area of the upper structure (20). Footwear (10) according to claim 10, wherein the first protective layer (22) is provided with fastening systems, in particular with adhesives, distributed discontinuously on an upper internal surface of the first protective layer (22). Footwear (10) according to one of claims 1 to 11, wherein the first protective layer (22) is different from the second protective layer (26). Footwear (10) according to one of claims 1 to 12, with a functional layered shell of the sock type, which has the at least one functional layer (18). Footwear (10) according to one of claims 1 to 13, where Said at least one functional layer (18) is impermeable to water.