DE202015002270U1 - Ventilation element for use in a shaft bottom of a shoe and shoe - Google Patents

Abstract

Ventilation element (40) for use in a shaft bottom of a shaft assembly (12) of a shoe, with an air-permeable spacer structure (60) which has a three-dimensional structure permitting at least horizontal air passage.

Description

The invention relates to a ventilation element for use in a shaft bottom of shoes with ventilation below the sole of the foot and with the removal of sweat moisture through layers below the foot to improve the climate comfort of such shoes.

In former times, shoes in the sole area either had some water vapor permeability, also called breathability, due to the use of outsole material such as leather, with the disadvantage of water permeability in the sole area, or shoes in the sole area due to the use of outsoles of waterproof material such as rubber or rubber-like Plastic waterproof but also impermeable to water vapor, with the disadvantage of the accumulation of sweat moisture in the sole of the foot.

Recently, shoes have been made which are both waterproof and permeable to water vapor in the sole area by perforating their outsoles with through openings and covering the through openings by means of a waterproof, water vapor permeable membrane arranged on the inside of the outsole, so that no water from the outside can penetrate to the shoe interior, but in the sole of the foot resulting sweat moisture can escape from the shoe interior to the outside. Here are two different solutions gone. Either you have provided the outsole with their vertical thickness through openings through which sweat moisture from the shoe interior to the tread of the outsole can be passed, or you have provided the outsole with horizontal channels over which sweat moisture that has collected above the outsole over the lateral extent of the outsole can escape.

In particular, for shoes whose outsole is not provided with vertical through-openings penetrating its thickness or which can not be provided for safety reasons, for example because of the need for a nail-protection plate, but even for shoes whose outsole is provided with such vertical through-holes, it is desirable to incorporate To create a ventilation system underneath the sole of the foot, with which a noticeable increase in climate comfort in the area of the sole of the foot can be achieved.

In this regard, the invention provides a ventilation element for use in a shaft bottom of a shaft assembly of a shoe according to claim 1 and a shoe equipped therewith according to claim 10.

The core of the invention is to provide a ventilation element for use in a shaft bottom of a shaft assembly of a shoe, with an air-permeable spacer structure which has a three-dimensional structure permitting air passage in at least the horizontal direction.

The ventilation element according to the invention is used in shoes according to the invention which are such that the openings are located in the lower shaft area, below the level of the sole of the foot. In this case, the ventilation element is arranged in a sole-side lower region of the shaft arrangement. The upper upper material has at least one air passage opening in a sole-side lower peripheral region, by means of which a connection can be established between the ventilation element and the outer environment of the shoe such that an exchange of air between the outer environment and the ventilation element Lage can take place. In this way, heat and water vapor can be removed from the region of the shaft arrangement located above the ventilation element, for example by means of convective air exchange through the ventilation element.

Since, in the solution according to the invention, the at least one air passage opening, which in conjunction with the ventilation element enables the efficient removal of perspiration moisture, is not formed in the outsole, where it does not from the standpoint of outsole stability and especially in the case of a shoe with a rather thin outsole for aesthetic reasons can be particularly large, but in a sole-side lower peripheral region of the upper shaft material, where you can easily make the air passage opening comparatively large, one achieves thereby already a better air exchange and thus higher Wasserdampfabführmöglichkeit than a shoe whose at least one air passage opening is formed in the outsole.

The shaft arrangement with the ventilation element also has the further advantage that the ventilation element, which is positioned between the at least one air passage opening and the shoe interior, can extend directly to the inside of the shaft upper material and is not limited to the interior space between the twine impact edge of the upper shaft material. For example, in the case of gusseted shoes, the ventilation element is located above the adhered lasting sting and can therefore provide a greater exchange surface for water vapor and heat of the sole of the foot. Therefore, in the solution according to the invention, the ventilation element can have a significantly larger surface area than in the known solutions, with accordingly larger exchange surface and thus Wasserdampfabführkapazität.

This shoe construction and the high Wasserdurchampfdurchlass- and Luftaustauschwirkung achieved with it is advantageous both for shoes that do not have to be waterproof, because they are used only in dry areas, such as work shoes in an assembly hall, as well as shoes that are worn outdoors and therefore may be exposed to moisture.

The ventilation element may be formed as an air-permeable spacer structure, which is designed so that the ventilation element, even under load by the foot of the user of the shoe maintains such a distance between the above and below her layers that the air permeability of the ventilation element is maintained.

In one embodiment of the invention, the spacer structure is formed with a sheet which includes a plurality of spaced apart from the sheet perpendicular and / or at an angle between 0 ° and 90 ° extending spacer elements.

In this case, define the ends of the spacer elements remote from the fabric together a surface, by means of which a remote from the fabric second support surface can be formed. The spacer elements may be rod-shaped or thread-like individual elements or sections of a more complex structure, for example a truss or latticework.

By selecting the material of the spacer elements and / or by selecting the angle of inclination of the spacer elements and / or by selecting the proportion of the contact points to which adjacent spacer elements are fixed to each other and / or the shape of the tray or lattice used rigidity and thus dimensional stability Adjust the spacing structure under load to the respective requirements. The spacers may be fibers.

As a ventilation element, for example, is a distance structure, as it is in itself DE 102 40 802 A2 is known, but there in connection with an infrared-reflective material for clothing.

The ventilation element can be, for example, a molded structure made of polymers, a 3D spacer structure or a textile structure solidified with polymer resins. The ventilation element may also be manufactured by an injection molding process, in one embodiment it may have a channel or tubular configuration or be formed of polymer or metal foams.

Shaped structures of polymers are based on polymer monofilaments, fabrics, nonwovens or scrims which are formed by means of deformation and fixation of the materials to a ribbed, knobbed or zigzag structure. The structure may also be a 3-dimensional structure, for example of polypropylene, in the form of a z. B. wavy or brought by other form to a 3D structure Filamentgeleges. The deformation and fixation can be carried out, for example, via a heated structural roller or as a thermoforming process. The formed structures may additionally be laminated with a fabric or nonwoven to improve dimensional stability. One possible method for producing such shaped structures is, for example, in the patent application WO 2006/056398 A1 described.

The ventilation element can also be formed from a 3D spacer structure. Such spacers are usually made of polyester multi or monofilaments. Spacers may be spacer, spacer, spacer, or spacer. The active technology makes it possible to vary both the top and bottom of the fabric surfaces as well as the spacer thread (pile thread) independently of each other. Thus, the surfaces and the hardness including the spring characteristic can be adjusted depending on the type of individual application. Spacers are characterized by a very high air circulation in all directions, even under load.

A spacer structure, for example in the form of a spacer knit, can also be produced by impregnating fabrics which are impregnated with synthetic resin before or after deformation into a 3-dimensional structure to obtain the desired rigidity. As fiber material for the spacer structure also inorganic fibers such as glass fibers or carbon fibers can be selected.

The ventilation element may be partially or completely elastically yielding.

Since at least in gezwickten shoes, in which a sole-side Zwickeinschlag the upper shaft material is glued or pinched on a peripheral edge of the underside of a mounting sole or insole (also known under the name AGO), a considerable pressure on the ventilation element is exercised. It is therefore possible that a very open and / or flexible ventilation element yielding or can be deformed. As a result, the Zwickvorgang is made more difficult as such. If the ventilation segment later Developed back to its original thickness, this can negatively affect the fit and comfort of the shoe. In addition, such ventilation elements can be expensive.

In a further embodiment of the invention, a non-compressible or slightly compressible material is therefore used in a part of the ventilation element.

The material can replace at least part of the spacer structure. Alternatively, the material may also be injected into at least a portion of the spacer structure. Ventilation element and material can also be arranged overlapping. The material may be sharpened and under or over the spacer to avoid a sharp edge between the two areas, which could lead to material wear or an uncomfortable wearing sensation.

In general, the material may be located in the toe and / or heels and / or ball of the foot and / or peripheral area of the spacer structure. In the ball of foot, the material can contribute to cushioning. If the material is in the peripheral area of the spacer structure and is impermeable to air, it may be provided with recesses which allow air passage.

The material can, for. Example of ethyl vinyl acetate (EVA), polyurethane (PU) or felt. The use of such materials is cheaper to use than conventional spacers. It may be permeable to air and / or water vapor or air or water vapor impermeable.

In an additional embodiment of the invention, the ventilation element has a channel structure.

The channel structure may represent the entire ventilation element or only a part thereof. The ventilation element may consist of a spacer structure in at least one partial region and of a channel structure in at least one partial region. In this case, a little compressible, air-permeable material can be used for the ventilation element in at least a portion.

In a further embodiment of the invention is located in the shaft bottom region, a waterproof and water vapor permeable functional layer, for example in the form of a functional layer laminate, wherein the ventilation element is located directly below the functional layer or the functional layer laminate. In connection with this embodiment, an advantage of the invention lies in the fact that an air exchange and thus a removal of sweat moisture and heat is made possible by the at least one air passage opening in cooperation with the air-permeable layer. The diffusion-limiting diffusion path, which the water vapor initially has to cover from the underside of the foot to the air-permeable layer, is minimized by the choice of the thinnest possible layer structure of the functional layer and maximizes heat transfer. If the steam has reached the ventilation element, it is additionally removed convectively via the air flow, whereby the water vapor partial pressure difference between the two sides of the functional layer is permanently maintained at a high level. There are no more layers to overcome. The water vapor partial pressure difference between the two sides of the functional layer is a driving force for efficient removal of perspiration moisture. In addition to the steam, heat is also dissipated by the convection. Since, in the case of a sheathed shaft, the ventilation element is arranged above the lasting end of the shaft upper material, approximately the entire sole surface is available for the steam exchange.

In one embodiment of the invention having a shaft functional layer and a shaft bottom functional layer, these are part of a sock-like functional layer bootie in which a shaft region is formed by the shaft functional layer and a sole region by the shaft bottom functional layer.

In another embodiment of the invention with the shank functional layer and the shank bottom functional layer, the shank functional layer and the shank bottom functional layer in the lower shank region are connected to each other and sealed watertight at their common boundary.

In one embodiment of the invention, the functional layer of the shaft functional layer and / or the shaft bottom functional layer is part of a multilayer laminate which has at least one textile layer in addition to the functional layer. Frequently used laminates are two-, three- or four-ply with a textile layer on one side or one textile layer on each side of the functional layer.

In one embodiment of the invention, a shaft bottom functional layer laminate and / or a shaft functional layer laminate are constructed with the laminate.

In one embodiment of the invention, the functional layer has a water vapor-permeable membrane. Preferably, the membrane is waterproof and permeable to water vapor. In a preferred embodiment, the functional layer has a membrane constructed with expanded microporous polytetrafluoroethylene (ePTFE).

In one embodiment of the invention, the ventilation element is located below the shaft bottom functional layer.

The invention will now be further explained by means of embodiments. In the attached drawing figures show:

1 an embodiment of a ventilation element according to the invention;

2 a second embodiment of a ventilation element according to the invention;

3 a third embodiment of a ventilation element according to the invention;

4 A fourth embodiment of a ventilation element according to the invention;

5 A fifth embodiment of a ventilation element according to the invention;

6 a sixth embodiment of a ventilation element according to the invention;

7 a seventh embodiment of a ventilation element according to the invention;

8th an eighth embodiment of a ventilation element according to the invention;

9 ; A ninth embodiment of a ventilation element according to the invention;

10 a tenth embodiment of a ventilation element according to the invention;

11 an eleventh embodiment of a ventilation element according to the invention;

12 a twelfth embodiment of a ventilation element according to the invention;

13 A thirteenth embodiment of a ventilation element according to the invention;

14 a fourteenth embodiment of a ventilation element according to the invention and;

15 a schematic view of a cross section through a part of the forefoot of a shoe according to the invention.

In the 1 to 12 different embodiments of the invention Venilatationselements are shown.

So will in 1 an embodiment of a spacer structure 60 shown, which is suitable for the ventilation element according to the invention 40 suitable. The spacer structure forms two mutually spaced support surfaces, wherein the spacer structure rests with the lower support surface on the respective support and whose upper support surface serves as a support surface for the located above the spacer structure layer, which is in particular the bottom portion of the Funktionsschichtbooties. The two bearing surfaces are either either each formed by a sheet, which are held by means of intermediate spacer elements at a distance from each other and of which at least the upper is air-permeable. Or only the lower support surface is formed by a fabric, stand up from the spacer elements whose free ends form support points, which together have the function of the upper support surface. Or there is neither a lower nor an upper sheet but a single sheet formed in a wave or zigzag form with lower and upper crests or serrations that define the lower and upper surfaces, respectively. 1 shows an embodiment of a ventilation element 40 suitable distance structure 60 its upper and lower bearing surface by two mutually parallel air-permeable sheet 62 and 64 are formed, for example, from the group of polyolefins, polyamides or polyesters in, wherein the fabrics 62 and 64 by supporting fibers 66 permeable to each other and spaced at the same time. At least part of the fibers 66 as a spacer is at least approximately perpendicular between the sheets 62 and 64 arranged. The fibers 66 consist of a flexible, deformable material such as polyester or polypropylene. The air can pass through the fabric 62 and 64 and between the fibers 66 flow through. In the fabrics 62 and 64 it is open-pored woven, knitted or knitted textile materials.

The 2 to 7 show exemplary embodiments of a ventilation element 40 in which in a part of the ventilation element 40 a non or little compressible, air impermeable material 100 is used instead of the distance structure 60 , The material can, for. Example of ethyl vinyl acetate (EVA), polyurethane (PU) or felt. The material can replace at least part of the spacer structure. Alternatively, the material may also be injected into at least a portion of the spacer structure. In general, the material in the toe 105 and / or heels 110 and or footpads 115 and / or peripheral area 120 of the spacers. In the ball of the foot 115 The material can contribute to the damping. If the material is in the peripheral area 120 of the ventilation element 40 It can be located with recesses or openings 125 be provided, which allow an air passage.

So shows 2 an embodiment in which the material 100 only in toe 105 and heel area 110 located. The use of this material 100 should a yielding or deformation of the ventilation element 40 z. B. when tackling the Zwickeinschlages 16a of the upper upper material 16 a z. B. as an embodiment in 13 Shoe shown 10 on a peripheral edge of the underside of a mounting sole or insole 30 prevent, where a significant pressure on the ventilation element 40 exercised, which significantly complicates the Zwickvorgang. In addition, the use of such a material prevents 100 that the ventilation element 40 later regressed to its original thickness, which can negatively impact the fit and comfort of the shoe.

In the embodiment, in 3 is shown, is the material 100 both in the heel 105 , as well as toe 110 , as well as in the forefoot area 115 available. Also in the latter area 115 is a back deformation after the Zwickprozess problematic. In addition, over time, by wearing the shoe and the load on the foot and its rolling motion, the ventilation element 40 , especially in the forefoot area 115 , be heavily compressed. The material 100 can counteract this process by its compression resistance.

In 4 The material is located in the forefoot area 115 as well as in the extended heel area 110 , where also a great pressure on the ventilation element 40 takes place, due to the body weight of the shoe wearer and its movements. The forefoot or ball area 115 and the heel area 105 are critical areas where the greatest stress and bending occurs.

The embodiment according to 5 shows a different kind of material 100 as in 4 shown with an inner circumference of the material adapted to the foot circumference 100 ,

In the embodiment according to 6 is the material 100 in addition to the toe 105 and heel area 110 also in the peripheral area 120 of the ventilation element 40 that is on the lateral edges, which is the toe area 105 and the heel area 110 connect with each other. This is particularly advantageous in the production of the shoe when the distance structure 60 is very easily compressible or relatively unstable, as well as shoes that are exposed to high voltages / pressures, eg. B. running shoes. In order to achieve additional damping in this case, is located in 7 the material 100 also in the foot ball area 115 , In both embodiments are recesses or openings 125 in the material 100 in the lateral peripheral area 120 of the ventilation element 40 ,

The 8th to 10 show embodiments of the ventilation element 40 that have a channel structure 160 . 165 . 188 exhibit.

8th shows a plan view of a ventilation element 40 with a channel structure 188 , The upper surface of the ventilation element 40 is with the reference numeral 606 designated. The channel structure 188 contains a number of cross channels 181 , Some of the cross channels 181 have widened lateral ends and thus form air and moisture-repellent openings 182 , The depth of the cross channels 181 in the air and moisture dissipating openings 182 can also be compared with the depth of the middle part of the transverse channels 181 to be taller.

8th also shows dashed the lateral openings 610 through the side wall of the ventilation element 40 , These lateral openings 610 connect the air and moisture dissipating openings 182 with the outside environment ventilation element 40 , In the embodiment of the 8th have the lateral openings 610 a width / diameter substantially equal to the width of the transverse channels 181 equivalent. Their width can also be smaller than the width of the transverse channels 181 be.

Some of the cross channels do not end in openings. Their ends are not with lateral openings 610 in the side wall of the ventilation element 40 connected.

Adjacent transverse channels are spaced apart and the transverse channels cover almost the entire upper part of the ventilation element 40 from his toe area to his heel area.

The channel structure 188 also contains two circumferential channels 189 . 190 , where the peripheral channels 189 . 190 the cross channels 181 essentially connects in the longitudinal direction. A first circumferential channel 189 extends from a toe area to a region of the ventilation element 40 in front of the heel area. In particular, the first circumferential channel runs 189 from a central region of the first transverse channel 181 to a middle section of the 19th cross channel 181 in a zigzag line, with its outermost points next to the air and moisture-dissipating openings 182 the cross channels 181 that in the third, the 6th, the 10th, the 13th and the 16th cross channel 181 are shaped. The innermost points of the first circumferential channel 189 are located on the first, the 5th, the 9th, the 12th, the 15th and the 19th cross channel 181 ,

A second circumferential channel 190 runs from a middle section of the 20th cross channel 181 to a middle section of the 24th cross channel 181 , with its outermost points next to the air and moisture-dissipating openings 182 the 22nd cross channel 181 are arranged.

In a further embodiment, not shown, but also only one circumferential channel may be provided, extending from a central region of the foremost (the toe area) transverse channel 181 in a zigzag line to a central region of the rearmost (heel region) transverse channel 181 extends.

Through the circumferential channels 189 . 190 becomes the number of channels that ultimately lead to the air and moisture dissipating opening 182 lead, increases, whereby the amount of air and moisture is increased, which can be transported to the outside environment of the shoe. The circumferential channels 189 . 190 cuts the cross channels 181 in different angles. So cuts the circumferential channels 189 . 190 the second cross channel 181 at an angle of 45 degrees. Accordingly, the 6th channel is cut at an angle of 58 degrees, the 16th channel at an angle of 48 degrees and the 21st at an angle of 72 degrees. Instead of two dissipative openings 182 with a straight circumferential channels 189 . 190 to connect, to the circumference of the body 177 follows, the circumferential channel zigzags, as already described. The zigzag structure has better absorption and transport of moisture than a structure with straight connecting channels between the discharging openings.

The channel structure 188 also contains a number of longitudinal channels 184 showing some of the cross channels 181 in the middle of the front and the middle region of the ventilation element 40 to cut. These longitudinal channels 184 are not apertured, but could be in other embodiments of the invention.

The cross channel width can be adjusted in the forefoot / bale 115 and toe area 105 and in the heel area 110 slightly smaller than the transverse channel width in the other areas of the ventilation element 40 be. An exemplary cross channel width in the ball area 115 and in the heel area 110 is 2.5 mm, while the width of the transverse channel in the other areas as well as the width of the longitudinal and / or circumferential channel can be 3 mm.

In addition, to maximize the pumping action in the gait cycle of the gait cycle, the cross channels may be used 181 in the forefoot / ball area 115 more to the top of the ball area 115 be postponed. Thus, the 7th, 8th, and 9th cross channels are moved closer to the 6th channel, thereby providing a maximized pumping action by placing the bale of the human foot. In other words, the distances between adjacent cross-ventilation channels 181 in the forefoot area then smaller than in the heel area to increase the effect of pumping water vapor into the outside environment.

The 9 and 10 also show ventilation elements 40 with canal structures 200 . 205 are provided, extending from the ventilation element 40 of the 8th distinguished by their arrangement and shape, but have the same function.

Both 11 to 14 Embodiments are shown which are hybrid structures that are both a spacer 60 as well as a channel structure 210 . 215 . 220 . 225 exhibit. The distance structure 60 is located mainly in the midfoot area, but with extensions in the other foot areas. In other embodiments, not shown, the distance structure may also be primarily in the toe 105 , Forefoot 115 and / or heel area 110 Depending on where more ventilation is needed or more compression resistance or stability.

Both the distance structure 60 as well as the channel structure 210 . 215 . 220 . 225 can be arbitrarily formed and shaped.

13 shows an embodiment of a shoe 10 , which is a shaft arrangement 12 and one at the lower end portion of the shaft assembly 12 attached sole 14 which is an outsole in the case of this embodiment. In the lower end of the shaft assembly 12 are two air vents 20 to see. The air openings are opposite. This can form an air flow through the ventilation element, which is conducive to the removal of water vapor and heat from the shoe by means of convection. The air vents 20 are with an air-permeable protective cover 22 provided to prevent the ingress of coarse particles such as stones. The protective cover 22 can cover the air passage opening from outside and / or from inside. It can each have a protective cover 22 every single air outlet 20 be assigned or an entire protective cover 22 extends over all air vents. The protective cover 22 may be formed for example by a net or mesh of metal or plastic or by a textile material with high air permeability and thus high water vapor permeability.

The shaft arrangement 12 has a shaft upper 16 on whose inside there is a lining, which is a functional layer 39 having. In the area of the shaft bottom 15 there is a shaft bottom functional layer. The functional layer on the inside of the upper 16 and the functional layer on top of the ventilation element 40 Both are part of a sock-like bootie 39 which the entire shaft assembly 12 on the inside of which, with the exception of Fußeinschlüpföffnung in this embodiment. Such a bootie is usually sewn together from several functional layer parts, wherein the seams are pasted over with waterproof seam sealing tape and made waterproof in this way. The bootie could also be made of one piece of material, which would no longer require the need to sew and seal it. The functional layers are each part of a three-layer functional layer laminate, with a functional layer 34 that exist between two fabrics 25 and 26 is embedded. In the fabrics in 25 and 26 it can usually be a textile layer.

Alternatively, a wrapped sole side under end portion of the shaft functional layer laminate by means of a Strobelnaht on the mounting base 30 sewn firmly. The shaft bottom functional layer laminate may be below the mounting sole 30 and extend to below the crimped end portion of the sheath functional layer laminate and be watertightly bonded to the end portion via a sealing material (not shown), such as a sealant, such that the shoe interior is formed by the cooperation of the mutually sealed functional layers except the foot weft opening and lacing portion of the shoe 10 is completely waterproof, as when using a functional layer bootie.

The shaft arrangement 12 is thus waterproof and using a sole 14 is a waterproof shoe. The ventilation element 40 is in the shaft bottom area immediately below the functional layer laminate 24 of the bootie 39 arranged. In this case, the ventilation element extends 40 Over the entire shaft floor area and is thus the entire sole of the foot for the steam and heat exchange available. Below the ventilation element 40 is the mounting sole 30 on the underside of the lasting impact 16a the sole side lower end portion is fixed by means of Zwickklebstoff (not shown). Instead of using a separate mounting sole, it is also possible in certain embodiments, the underside or lower bearing surface of the ventilation element 40 To make accordingly stable, so that on this underside of the Zwickeinschlag can be attached. In such an embodiment, the ventilation element additionally assumes the function of a mounting sole. Alternatively, the sole side lower end portion of the upper upper material 16 by means of z. B. a Strobelnaht with the mounting base 30 get connected.

The upper 16 is constructed with a water vapor permeable material. Also with water vapor permeable material are those above the shaft bottom functional layer laminate 28 arranged mounting sole 30 and, if present, the feeding situation.

The sole 14 may be constructed with waterproof material which is rubber or a rubber-like elastic plastic such as an elastomer. The sole 14 but can also be made of water vapor permeable material such. B. leather. At the sole 14 It may be a prefabricated sole, which is connected to the shaft assembly 12 is glued, or one to the shaft assembly 12 molded sole act. One at the bottom of the sole 14 running surface of this sole is provided in the usual way with a groove pattern to form profile projections, which the slip resistance of such a sole 14 provided shoe 10 improve.

Summary

• 1. ventilation element ( 40 ) for use in a shaft bottom of a shaft assembly ( 12 ) of a shoe, with an air-permeable spacer structure ( 60 ) which has a three-dimensional structure permitting air passage in at least horizontal direction. Shoe ( 10 ), with a shaft arrangement ( 12 ) and a sole ( 14 ). The shaft arrangement ( 12 ) has a shaft upper ( 16 ) and one in a shaft bottom ( 15 ) arranged ventilation element ( 40 ) on. The ventilation element ( 40 ) is in a sole side lower portion of the shaft assembly ( 12 ) arranged. The upper material ( 16 ) has in a sole side lower peripheral region at least one air passage opening ( 20 ), which the ventilation element ( 40 ) in such a way with the external environment that air between the outside environment and the ventilation element ( 40 ) can be exchanged.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10240802 A2 [0015]
• WO 2006/056398 A1 [0017]

Claims (11)

Ventilation element ( 40 ) for use in a shaft bottom of a shaft assembly ( 12 ) of a shoe, with an air-permeable spacer structure ( 60 ) which has a three-dimensional structure permitting air passage in at least horizontal direction. The ventilation element ( 40 ) according to claim 1, wherein the spacer structure ( 60 ) with a sheet ( 62 ) is formed, which a plurality of the fabric ( 62 ) perpendicular and / or at an angle between 0 ° and 90 ° away extending spacer elements ( 66 ) includes. The ventilation element ( 40 ) according to claim 1 or 2, wherein in a part of the ventilation element ( 40 ) a non-compressible or slightly compressible material ( 100 ) is used. The ventilation element ( 40 ) according to claim 3, wherein the material ( 100 ) at least a part of the spacer structure ( 60 ) replaced. The ventilation element ( 40 ) according to claim 3, wherein the material ( 100 ) in at least a part of the spacer structure ( 60 ) is injected. The ventilation element ( 40 ) according to one of claims 3 to 5, wherein the material ( 100 ) in toe ( 105 ) and / or heel ( 110 ) and / or foot pads ( 115 ) and / or peripheral area ( 120 ) of the ventilation element ( 40 ) is located. The ventilation element ( 40 ) according to claim 6, wherein the material ( 100 ) in the peripheral area ( 120 ), the ventilation element ( 40 ) Recesses ( 125 ) Has. The ventilation element ( 40 ) according to claim 1, having a channel structure ( 188 . 200 . 205 . 210 . 215 . 220 . 225 ). The ventilation element ( 40 ) according to claim 2 and 8, with a spacing structure ( 60 ) and a channel structure ( 188 . 200 . 205 . 210 . 215 . 220 . 225 ). Shoe ( 10 ), comprising a) a shaft arrangement ( 12 ) and a sole ( 14 ), wherein: b) the shaft arrangement ( 12 ) b.1) a shaft upper ( 16 ) and b.2) in a shaft bottom ( 15 ) arranged ventilation element ( 40 ) according to at least one of claims 1-9; where c) the ventilation element ( 40 ) in a sole side lower portion of the shaft assembly ( 12 ) is arranged; and d) the upper ( 16 ) in a sole-side lower peripheral region at least one air passage opening ( 20 ), which the ventilation element ( 40 ) in such a way with the external environment that air between the outside environment and the ventilation element ( 40 ) can be exchanged. Shoe ( 10 ) according to claim 9, which at least in one to the sole ( 14 ) pointing lower portion of the shaft assembly ( 12 ) a waterproof, water vapor permeable functional layer ( 34 . 38 ), wherein the ventilation element ( 40 ) below the functional layer ( 34 . 38 ) is arranged.

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