DE102009009589A1 - Shoe, has air-permeable sole comprising reinforced textile flat structure that is made from fibers e.g. mineral fibers or chemical fibers, where flat structure is arranged between running surface and insole - Google Patents

Abstract

The shoe has an air-permeable sole comprising a reinforced textile flat structure (14) that is made from fibers e.g. mineral fibers or chemical fibers. A material (3) swellable by absorbing liquid is arranged in cells (4) formed between the fibers, where the flat structure is arranged between a running surface and an insole. Walls (6) of the cells are partially made from a binding medium e.g. polymer compound, where the flat structure has water-density zones. The flat structure has a carrier layer (1) and a covering layer (2) that are connected with one another by a layer (5).

Description

The Application relates to a shoe with breathable sole comprising a consolidated textile fabric Fibers, wherein cells formed in between the fibers under Fluid intake absorbed swellable material is.

Breathable shoes are already known from the prior art. The DE 10 2006 042 145 B3 For example, shows a ventilation insert, which consists of seven layers. Three layers form a core element, which is enclosed on both sides by two further functional layers. The core element has two air-permeable layers which enclose a swellable material. Due to the further functional layers, the air-permeable layers of the core element are compressed in partial regions, whereby a chamber structure of regular chambers is created. The preparation of such a ventilation insert is complicated and expensive. There are a total of seven layers must be joined together to make a usable ventilation insert. Furthermore, it is disadvantageous that metal or plastic meshes whose mesh width is limited are used to form the chamber structure as functional layers. Due to its construction, this ventilation insert has a large height and is relatively stiff and inflexible. These properties are particularly disadvantageous when the ventilation insert is to be sewn or glued in textiles.

outgoing Of these disadvantages, the object was the object of a to create an airy sole for a shoe, which is inexpensive and easy to produce and at the same time does not affect the wearing comfort.

These Task is solved by a sole according to claim 1.

It It has been recognized that taking one under fluid intake swellable material in the sole construction a simple Possibility to make a breathable shoe. Thereby, that the textile fabric is substantially full-surface placed between the outsole and the insole provides it's a big breathable area. Furthermore the textile fabric can be especially made easy to integrate into the shoe. The production process The sole of the shoe needs to be adjusted only slightly. It eliminates the need for elaborate production of a ventilation insert, which has to be fixed in the sole.

The Cells can form a layer in which the swellable Material encapsulated in such a way encapsulated that the layer at swollen swellable material is waterproof sealed.

According to one Embodiment, the textile fabric are formed from a carrier layer and a cover layer, which include a layer in which the cells are formed are. The cells are formed such that the swellable material predominantly captive in the cells encapsulated is added. The encapsulated Absorption of the swellable material in the cells allowed occlusion of the cells upon swelling of the swellable Material. The layer can then function as an independent functional Element fulfill the sealing function. The sole construction as well as the textile fabric does not need any separate grilles and elaborate injection molding constructions, to control the swelling of the swellable material so that a seal against air and water through the textile Sheet is given. The creation of cells in a layer allows the production of thin and very flexible insole inserts between the outsole and the insole, which consists of only three layers, namely the carrier layer, the layer and the cover layer can exist.

Around To achieve a good water resistance, it is suggested that the fabric along the circumference of the outsole is waterproof connected to the outsole. This can be done by gluing or Plastic welding done. It is also possible during injection molding of the outsole, the intermediate layer of textile fabric to arrange in the mold and in the area of perforations of the sole cover. Then the sheet with the outsole potted and in the area of the openings is the sheet free from the sole material and provides air permeability. Also can the textile fabric along the circumference of the Outsole, in particular along the inner circumferential surface the outsole, be glued to the outsole.

Also For example, the textile sheet may at least provide the insole partially form. For example, the carrier layer, which faces the foot, made of a skin-friendly material be formed. The insole is often divided into two parts. So For example, the heel area and / or the ball area the insole formed from the textile fabric be.

Frequently, the shaft is sewn to the insole in such a way that in the region of the tread facing side of the insole of the shaft is sewn to the insole. The area offset, which thus forms in the area of the insole, is regularly due to a full-surface balancing of the insole, which forms the space between the insole and outsole. padded. The The condensation can also be formed by the textile fabric.

According to one advantageous embodiment is the textile fabric watertight along the circumference of the insole with the insole connected is. Thus, the insole is waterproof the outsole sealed. Breakthroughs in the outsole, such as openings with diameters between 1 mm and 5 mm or micro-openings or window-like openings, allow air circulation. By these openings can penetrate water through the outsole. To prevent the water from getting through the insole, this is the whole surface through the textile fabric sealed. For this, this is along the outer Circumference of the insole associated with this, for example glued or welded.

Also The outsole may have openings. In the field of breakthroughs is a breathability and breathability important. It is therefore proposed that the textile fabric has at least two zones, the zones by an internal weld sealed against each other waterproof. The internal weld connects the cover layer with the carrier layer. The internal weld closes the horizontal connection between the cells along the weld. It can be honeycombed and / or irregular zones are formed. Water in a zone only swells the material in this zone. The water from this zone can not get into the others Penetrate zones. These zones remain as long as no water is immediate gets to these zones from the outside, permeable to air. Also less water is absorbed, for example when the shoe only partially wet. This also leads to a faster one Drying. A zone can be formed in the area of the openings become. This zone must be free of glue. The rest of the textile fabric can be glued to the outsole and / or the insole, preferably flat. A horizontal water passage is prevented by the internal weld. An air passage is possible in the zone of the opening. The internal weld Can be made by ultrasonic welding or other plastic welding process be formed.

The Textile fabrics can be used as fleece, nonwoven or Textile be designed. The cells can be one layer form, with the sizes of the cells statistically are distributed randomly. The use of nonwovens, nonwovens or textiles allows a particularly flat construction of the textile Sheet and makes this easily deformable.

The textile fabric can be formed from mineral fibers, animal fibers, vegetable fibers or chemical fibers. This fiber or fiber blends of glass, mineral wool, basalt, silk, wool or cotton are possible. Also, fibers or fiber blends of chemical fibers such as natural polymers, eg. Cellulose, synthetic polymers, e.g. Polyamide, PA 6.6 ( ^Nylon® ), PA 6.0 ( ^Perlon® ), polyester, PET (polyethylene terephthalate), PBT (polybutylene terephthalate), PVC (polyvinyl chloride), PP (polypropylene), PE (polyethylene), PPS (polyphenylene sulfide), PAN (polyacrylonitrile), PI (polyimide), PTFE (polytetrafluoroethylene, ^Teflon® ) or aramids possible.

The Textile fabrics can be mechanical, chemical or thermal be solidified. Mechanically, a needling or by hydroentanglement respectively. Chemically, a solidification by the addition of binders respectively. Thermally, a solidification by softening in a suitable gas flow, between heated rollers or in take place a vapor stream.

The statistically random distribution of sizes The cells ensures that the cells have a very high uniformity are distributed. As a result, defects are effectively avoided. By the statistically random distribution of the sizes cells are also created with microscopic extension. By cells of microscopic extent, the reaction time of the In the cells encapsulated absorbed swellable material and thus the time until the seal through the textile fabric very much shortened. Furthermore, it is realized that very small amounts of swellable material in the cells encapsulated can be included. This will be a Fast kinetics realizes a fast response causes the swellable material to liquid. This results in a dynamic porosity of the textile fabric created, which passes through a rapid sealing against liquid and characterized a fast drying in the absence of moisture.

Of the geometric construction of the cells could be random. One The random geometric structure of the cells surprisingly shows a very fast liquid distribution in the layer, in which the cells are located. By the statistically random Distribution of the sizes or the extent of the cells in combination with their random buildup occur capillary effects on, leading to a very rapid distribution of the liquid within the shift.

The carrier layer and the cover layer could be interconnected by a layer, wherein the layer consists at least partially of a binder. Against this background, it is possible that both the cover layer and the carrier layer are made of a nonwoven or nonwoven fabric. The binder connects the cover layer with the carrier layer captive and closes the swellable material captive encapsulated between the carrier layer and the cover layer.

there is it possible that the swellable material homogeneously mixed with the binder or in agglomerated form is combined with the powdered binder and is stored on the carrier layer. After placing the cover layer then the binder can be heated so that this melts. After cooling the binder are the carrier layer and the cover layer are joined together and are in particulate form and / or fiber form present swellable materials encapsulated in cells.

In front this background could be the walls of the cells at least partially consist of the binder. By this configuration is ensured that the swellable materials to the walls of the cells are tethered. A trickle out the swellable material from the textile fabric is thereby effectively avoided.

The Walls of cells could make the layer reticulate build up. Due to the net-like structure is the textile fabric given a high flexibility. The textile fabric can be rolled up or bent without the layer breaking. The reticular design also leaves surprisingly a non-destructive expansion of the textile fabric to.

The Binder could be used as a thermoplastic polymer compound be designed. Thermoplastics can be melted without difficulty and can be cohesive with other substances Make connections.

The swellable material could contain superabsorbers. Superabsorbents are characterized by the fact that they can bind a large amount of liquid. Swelling-capable materials that can be used in particulate form or in fibrous form in the textile fabric described here are, for example, swellable polymers selected from the group consisting of polyacrylic acid, polyacrylic acid copolymers and crosslinked sodium polyacrylate or casein, protein or a thermoplastic-elastomer mixture. Preferably, the absorber is mixed with a filler and filler and absorber together form an absorber layer. As absorbers for example superabsorbents can be used as HySorb ^® from BASF AG or Favor ^® by Degussa AG.

The Swellable material could be with the binder form at least partially agglomerated particles. This will the application of the swellable material on the carrier layer facilitated. Furthermore, the amount of swellable Material can be reduced. This allows a relatively small weight increase be achieved with fluid intake.

The Cover layer could be made hydrophilic. Through this Design ensures that water on the cover homogeneously distributed and evenly into the cells can penetrate. This will be a uniform Swelling of the swellable material realized. The uniform swelling leads to a uniform seal over the entire surface of the textile fabric or over the entire surface of the cover layer. The hydrophilic treated cover layer further serves as Diffusion layer, thus the horizontal distribution of the penetrating Water, so that the subsequent layer evenly is acted upon by the penetrating water. Furthermore, the Cover layer responsible for ensuring that in the swellable Material evaporate stored water as quickly as possible can. This is achieved by adding water through capillary action and concentration gradients are transported to the outside and thus evaporates. The cover layer may face the outsole be.

The Carrier layer could be made hydrophobic. This ensures that water stored in the cells and swollen, moist swellable material the carrier layer is retained and not with the body of the wearer of a textile product comes into contact. This is the wearing comfort of shoes through an active exchange of air and by dissipation of moisture significantly improved as a result of perspiration. The carrier layer may be facing the foot.

It has been recognized that the textile fabric or the swellable material only under direct water influence swells. Humidity is not enough, the textile fabric or swell the swellable material. this leads to to that foot sweat through the fabric after outside can be dissipated, without the material swells.

In front In this background, the textile fabric can be a Air permeability in the dry state of at least 200 dm ^ 3 / (m ^ 2 s), preferably of at least 600 dm ^ 3 / (m ^ 2 s) at a pressure difference of 200 mbar between upstream side and Have downstream side. These values have proven to be special proven beneficial to give a good feeling in humans when wearing textile products.

The Textile fabrics may have a drying time at room temperature of at most 20 minutes, preferably at most 10 minutes, in which the mass of the textile fabric reduced by at least 400%. The carrier of a textile Product, which with the textile fabric described here is equipped, therefore, after soaking of the product only a few minutes on a breathable and breathable need to dispense textile product.

The statistically randomly formed cell structure ensures that the encapsulated absorbed swellable material spatially limited. This is the textile Fabric against air and moisture passage sealed. The swelling of the swellable material is surprisingly mainly in the horizontal direction. The air permeability in the dry state is surprisingly many times over higher than the air permeability of known water vapor permeable Membrane systems. Therefore, the wearing comfort of shoes is clear improved.

at Water entry from the outside closes the textile Immediately the air intake opening and seals against the penetrating water. The swelling of the swellable Material in the spatially limited cells causes a Reduction of the porosity of the textile fabric to almost zero%. In addition to the moisture absorption and the permanent Sealing by the textile fabric upon entry Of moisture, it is crucial that the porosity or the air permeability of the textile fabric in the absence of moisture penetrate as quickly as possible regenerated. It is desired that the porosity as quickly as possible reaches the value that the textile fabric in the dry state shows. This behavior becomes dynamic porosity called and takes place in the textile fabric described here reversible without changing the physical properties of the textile fabric.

So far Here is the question of cells, it is irrelevant whether the cells closed or open. Similar to a foam layer For example, the layer comprising the cells may be open-celled or closed-celled be designed.

following the object will be shown on the basis of an exemplary embodiments Drawing explained in more detail. In the drawing show:

1 a schematic sectional view of a textile fabric;

2 a diagram showing the drying behavior of the fabric;

3 a diagram showing the air permeability of the fabric in the wet and in the dry state;

4 a shoe with a fabric applied over the entire surface of the outsole;

5 a plan view of an embodiment according to 4 ;

6 a shoe sole having a fabric between the outsole and a midsole;

7 a shoe with a textile fabric applied over the entire surface of the insole;

8th a plan view of a fabric;

9 a sectional view through an insole.

1 shows a textile fabric as an air-permeable layer 14 for full-surface arrangement on an outsole of a shoe, comprising a carrier layer 1 and a cover layer 2 , wherein between the carrier layer 1 and the cover layer 2 a swellable under liquid absorption material 3 in particulate form in cells 4 encapsulated is included.

The cells 4 form a layer 5 from, in which the swellable material 3 encapsulated in such a way that the layer 5 with swollen swellable material 3 seals. The seal causes a gas flow or a liquid flow from the cover layer 2 to the carrier layer 1 or through the carrier layer 1 prevented or reduced.

The carrier layer 1 and the cover layer 2 are designed as nonwovens, wherein the cells 4 a layer 5 form and where the sizes of the cells 4 statistically randomly distributed. Also, the layer can 5 be formed as a nonwoven.

The geometric structure of the cells 4 is random. With the cells 4 are not regularly constructed geometric bodies such as octahedron or cuboid, but to open-cell or closed-cell spaces, through walls 6 are separated from each other.

The carrier layer 1 and the cover layer 2 are through the layer 5 connected together, the layer 5 made of a binder. The walls 6 the cells 4 consist of binder and build the layer 5 reticulate. The binder is designed as a thermoplastic polymer compound. The swellable material 3 contains superabsorbent.

The cover layer 2 is hydrophilic and allows a homogeneous horizontal distribution of penetrating from the outside in the direction of arrow water in the layer 5 , The shorter arrow X shows that the water has passed through the cover layer 2 from the swellable material 3 is absorbed. By absorbing the penetrating water swells the swellable material 3 open and close the cells 4 , The layer 5 seals off. The larger arrow Y shows schematically that air in the dry state through the cover layer 2 , the layer 5 and carrier layer 1 can pass through.

The carrier layer 1 is hydrophobic and prevents ingress of water or swollen, moist swellable material can contact the support of a textile product.

The textile fabric may be constructed according to the embodiments in the following manner: The carrier layer 1 is formed from a hydroentangled nonwoven fabric made of polyester, which has a weight per unit area of 100 g / m 2. This nonwoven fabric is hydrophobic. The binder is formed from a polyethylene powder having an average particle size of 200-400 microns. The polyethylene powder is sold by Sabic under the name Sabic LDPE 1695 Z. The swellable material 3 consists of a superabsorbent powder with a mean particle size of 80 to 160 microns. The superabsorbent powder is sold by Sumitomo Seika Chemicals Co. under the name Aqua Keep 10 SH-MB 3. The polyethylene powder and the swellable material 3 are mixed homogeneously and on the carrier layer 1 applied. Thereafter, the cover layer 2 to the homogeneous mixture of swellable material 3 and binder applied. The cover layer 2 is formed from a hydroentangled nonwoven fabric made of polyester with a weight per unit area of 100 g / m 2. The cover layer 2 is hydrophilic. By a thermal lamination of carrier layer 1 and cover layer 2 the binder is melted and the cells 4 are generated which the swellable material 3 encapsulated.

Also, the carrier layer 1 from a hydroentangled nonwoven fabric made of polyester, which has a basis weight of 100 g / m ^ 2, be formed. This nonwoven fabric is hydrophobic. The binder is formed from a polyethylene powder having an average particle size of 200-400 microns. The polyethylene powder is sold by Sabic under the name Sabic LDPE 1695 Z. The swellable material 3 is formed from a superabsorbent powder having an average particle size of 80 to 160 microns. The superabsorbent powder is sold by Sumitomo Seika Chemicals Co. under the name Aqua Keep 10 SH-MB 3. The polyethylene powder is applied to the carrier layer in a regular pattern 1 applied. The swellable material 3 is placed in spaces of the pattern that are not covered with polyethylene powder. Thereafter, the cover layer 2 on the swellable material 3 and the binder applied. The cover layer 2 is formed from a hydroentangled nonwoven fabric made of polyester with a weight per unit area of 100 g / m 2. The cover layer 2 is hydrophilic. By a thermal lamination of carrier layer 1 and cover layer 2 the binder is melted and become the cells 4 generates, which the swellable material 3 encapsulated.

2 shows a diagram in which the mass change of two wet fabrics according to Embodiment 1 is plotted against time in minutes. The mass change is given as a percentage. At a room temperature of 18 to 25 ° C., both textile fabrics have a drying time of at most 20 minutes, preferably of at most 10 minutes, in which the mass of the textile fabric is reduced by at least 400%.

In the diagram according to 2 Two measurements are taken, which are almost congruent. The first measurement was carried out on a first textile fabric, the second measurement on a second textile fabric. 2 vividly documents the high dynamic porosity of the textile fabrics. Furthermore occupied 2 in that the textile fabrics are reversibly wettable and dryable.

3 shows a diagram in which the air permeability of four different fabrics (# 1 to 4 plotted on the x-axis) is shown in the dry and in the wet state. All four fabrics were made analogous to the above-mentioned first embodiment and showed a thickness of 1.1 mm.

3 shows that the tested fabric in the dry state, an air permeability of at least 200 dm ^ 3 / (m ^ 2 s), preferably of at least 600 dm ^ 3 / (m ^ 2 s), at a pressure difference between upstream and downstream of 200 mbar show. The measurement of air permeability was according to DIN EN ISO 9237 carried out.

4 schematically shows a sectional view through a shoe sole consisting of a tread 12 , an air-permeable layer 14 as well as an insole 16 , In the manufacturing process, the tread 12 be produced by injection molding or vulcanization. It is also possible to make several layers to a tread 12 connect by gluing together. During the manufacturing process, first becomes the insole 16 by means of Gluing or sewing with the shoe upper attached. The thus prefabricated shoe construction according to an advantageous embodiment with the air-permeable layer 14 connected.

Here, along the outer periphery of the air-permeable layer 14 this with the insole 16 glued or sewn. The composite of shoe upper, insole 16 and air-permeable layer 14 will with the tread 12 connected.

Here, for example, in a single process, the insole 16 with the air-permeable layer 14 be placed in an injection mold and the tread 14 can be molded into it liquid. In the area of the outer peripheral surface of the air-permeable layer 14 must be a watertight connection 18 between the tread 12 and the air-permeable layer 14 be formed. When connecting the tread 12 with the air-permeable layer 14 must be avoided in the area of breakthroughs 20 the tread 12 Glue or other bonding agents wet the air-permeable layer.

Also it is possible the tread 12 in an injection molding or vulcanization process with the openings 20 and then the air-permeable layer 14 hereby to glue or otherwise connect. For example, at the beginning of the air-permeable layer 14 an adhesive connection 18 between tread 12 and air-permeable layer 14 be formed.

For a good breathability and simultaneous waterproofness of the shoe becomes the air-permeable layer 14 formed by a textile fabric as described above.

Like in the 4 It can be seen, is the air-permeable layer 14 full surface on the tread 12 arranged. This is in the range of the circumference of the tread 12 an adhesive bond 8th between the air-permeable layer 14 and the tread 12 educated. The adhesive connection 8th is waterproof. The adhesive connection 8th can between the tread 12 and the air-permeable layer 14 and / or the insole 16 and the air-permeable layer 14 be formed. Essential is the full-surface arrangement of the air-permeable layer 14 over the tread 12 and under the insole 16 ,

5 shows a schematic plan view of an embodiment according to the 4 , It can be seen that the air-permeable layer 14 essentially over the entire surface of the tread 12 rests and the openings 20 covers. Along the edge 14a the air-permeable layer 14 is the air permeable layer 14 with the tread 12 glued or otherwise waterproof connected. Water passing through the openings 20 under the air-permeable layer 14 thus can not reach the area of the insole 16 reach. Because of the air-permeable layer 14 Air circulation allows air and water vapor from the inside of the shoe through the insole 16 and the air-permeable layer 14 in the openings 20 arrive, whereby an air circulation is possible.

The tread 12 can be small area breakthroughs 20 as well as window-like opening 20 or have micro-openings.

Above the air-permeable layer 14 a spacer fabric may be arranged. The spacer fabric has a carrier, on which a plurality of thin webs are directed in the direction of the shoe sole. Under compressive stress of the spacer fabric, these webs are in the direction of the tread 12 pressed, allowing air from the inside of the shoe through the opening 20 is pressed outwards. If the spacer fabric is relieved, then the webs back up and air is from the outside through the opening 20 pulled into the inside of the shoe. Above the wearer can the insole 16 be arranged. It is also possible that the insole 16 between air-permeable layer 14 and spacer fabric is arranged.

6 shows elements of another embodiment in a plan view arranged side by side. To recognize is a tread 12 , in the window-like small openings 20 are arranged. The breakthroughs 20 are in four areas of the tread 12 arranged.

Furthermore, the shows 6 an intermediate layer 15 , which are also in the area of openings 20 lamellar openings 22 having.

The sole construction according to this embodiment has an air-permeable layer 14 on, the full surface over the tread 12 is arranged. As you can see, the air-permeable layers 14 along its circumference with a glue 8th bonded. The bond may be such that the air-permeable layer 14 on the outer circumference of the tread 12 glued to this.

The liner 15 will also work with the tread 12 glued by putting these in the tread 12 inserted. It can be seen that the areas of the openings 20 and the lamellar openings 22 lie one above the other, allowing air to pass through the air-permeable layer 14 is possible. The liner 15 can with the air-permeable layer 14 prefabricated and placed in an injection mold. Subsequently, the tread 12 around the liner 15 cast.

7 shows a sole structure similar 4 , In contrast to 4 However, here is the air-permeable layer 14 with the insole 16 bonded. At the outer periphery of the air-permeable layer 14 is an adhesive 8th attached to the air-permeable layer 14 with the insole 16 bonded. As can also be seen here, the air-permeable layer 14 arranged substantially over the entire surface of the insole.

8th shows a plan view of a fabric 14 in the area of the outsole 12 , The outsole has an opening 30 on. The textile fabric has two zones 32 and 34 on. The zones 32 . 34 are through an in-house weld 36 horizontally sealed against each other waterproof. The zone 36 is free of glue. The zone 32 is at least along its circumference 14a with an adhesive with the outsole 12 bonded. Also, the zone can 32 flat, preferably over the entire surface with the outsole 12 be glued.

9 shows a sectional view through a shoe with an outsole 12 a shaft 38 and an insole 16 , Regular is the shaft 38 with the insole 16 in the area 40 sewn or glued. This creates an offset 42 on the outer circumference of the insole. This offset 42 leads to a gap, which is conventionally shed with a felt. This balancing can be advantageous with a textile fabric 14 be formed.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102006042145 B3 [0002]

Cited non-patent literature

• - DIN EN ISO 9237 [0055]

Claims (28)

Shoe with breathable sole ( 12 . 14 . 16 ) with a consolidated textile fabric ( 14 ) of fibers ( 6 ), whereby in between the fibers ( 6 ) formed cells ( 4 ) a swellable material with liquid absorption ( 3 ), wherein the textile fabric ( 14 ) substantially over the entire surface over an outsole ( 12 ) is arranged. Shoe according to claim 1, characterized in that the textile fabric ( 14 ) between an outsole ( 12 ) and an insole is arranged. Shoe according to claim 1 or 2, characterized in that the textile fabric ( 14 ) substantially over the entire surface over an outsole ( 12 ) is arranged. Shoe according to one of the preceding claims, characterized in that the cells ( 4 ) form a layer in which the swellable material ( 3 ) is encapsulated in such a way that the layer ( 5 ) with swellable swellable material ( 3 ) is waterproof. Shoe according to one of the preceding claims, characterized in that the swellable material ( 3 ) captive in the cells ( 4 ) is recorded. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) a carrier layer ( 1 ) and a cover layer ( 2 ), wherein between the carrier layer ( 1 ) and the cover layer ( 2 ) the swellable material ( 3 ) is recorded. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) along the circumference of the outsole ( 12 ) with the outsole ( 12 ) is connected watertight. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) along the circumference of the insole ( 16 ) with the insole ( 16 ) is connected watertight. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) at least partially the insole ( 16 ). Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) at least two horizontally watertight zones ( 32 . 34 ) having. Shoe according to one of the preceding claims, characterized in that the zones ( 32 . 34 ) by internal welds ( 36 ) are sealed horizontally against each other. Shoe according to one of the preceding claims, characterized in that a first zone ( 34 ) in the region of an opening ( 30 ) and that at least one second zone ( 32 ) flat with the outsole ( 12 ) is glued. Shoe according to one of the preceding claims, characterized in that the material capable of swelling under liquid absorption ( 3 ) in particle form and / or fiber form in the cells ( 4 ) is recorded. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) is designed as a nonwoven, nonwoven fabric or textile. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) is formed from mineral fibers, animal fibers, vegetable fibers or chemical fibers. Shoe according to one of the preceding claims, characterized in that the textile fabric ( 14 ) is solidified mechanically, chemically or thermally. Shoe according to one of the preceding claims, characterized in that the cells ( 4 ) form a layer and wherein the sizes of the cells ( 4 ) are statistically randomly distributed. Shoe according to one of the preceding claims, characterized in that the geometric structure of the cells ( 4 ) is random. Shoe according to one of the preceding claims, characterized in that the carrier layer ( 1 ) and the cover layer ( 2 ) through the layer ( 5 ), wherein the layer ( 5 ) at least partially from a binder ( 8th ) is formed. Shoe according to one of the preceding claims, characterized in that walls of the cells ( 4 ) are at least partially formed from the binder. Shoe according to one of the preceding claims, characterized in that the walls of the cells ( 4 ) build up the layer like a net. Shoe according to one of the preceding claims, characterized in that the bandage is designed as a thermoplastic polymer compound. Shoe according to one of the preceding claims, characterized in that the swellable material ( 3 ) Contains superabsorbent. Shoe according to one of the preceding claims, characterized in that the swellable material ( 3 ) forms at least partially agglomerated particles with the binder. Shoe according to one of the preceding claims, characterized in that the cover layer ( 2 ) is hydrophilic. Shoe according to one of the preceding claims, characterized in that the carrier layer ( 1 ) is hydrophobic. Shoe according to one of the preceding claims, characterized by an air permeability of the textile fabric ( 14 ) in the dry state of at least 200 dm ^ 3 / (m ^ 2 s), preferably of at least 600 dm ^ 3 / (m ^ 2 s), at a pressure difference of 200 mbar between inflow side and outflow side. Shoe according to one of the preceding claims, characterized by a drying time at room temperature of at most 20 minutes, preferably of at most 10 minutes, in which the mass of the textile fabric ( 14 ) reduced by at least 400%.